EP3506999A1 - Open-pore membrane having an inner space-spanning polymeric structural network for electrophoretic material-selective separation and methods for producing and using same - Google Patents

Abstract

The invention relates to an open-pore membrane having nano-cavity polymer structures in solid separating media for separating fatty acids and/or carboxylic acids from principally aqueous mixtures, and to a method for producing said membrane.

Description

 Open-pore membrane with internal space-spanning polymer structure network for electrophoretically selective separation

 The present invention relates to an open-pore membrane having nanocavity polymer structures in solid separation media for separating off fatty and / or carboxylic acids from aqueous mixtures and to a process for their preparation.

description

Carboxylic or fatty acids are amphiphilic molecules that hardly dissolve in water and are therefore present in water only in small amounts in volatile form. The most common form in which fatty acids occur in water is therefore in the form of micelles and emulsions which cause phase separation. The amphiphilia causes them to precipitate on surfaces that are hydrophobic or lipophilic. If they are dissolved with detergents, they are present in an aqueous medium as micellar particles. Most organic compounds adsorb carboxylic acids to some extent via electrostatic binding forces. Therefore, carboxylic acids are present in aqueous organic solutions for the most part in a bound form or as micelles with other organic compounds. Due to the small size of such micelles, a filtration of these structures is virtually impossible or there is an occupancy of the filter surfaces, which causes a closure of the filter surface (fouling).

Therefore, classical extraction methods, such as filtration or dialysis, are practically not used for the separation of carboxylic acids.

In principle, classical extraction methods can be used for the removal of carboxylic acids.

These include

 the solid-liquid extraction processes which involve adsorption of the molecules to be separated on surfaces, e.g. in chromatography, - the liquid-liquid extraction in which the molecule to be separated in a liquid extractant, e.g. an alcohol or a nonpolar solvent from a liquid mixture enriches,

 the liquid-gas extraction, in which the molecule to be separated off is separated and separated from a liquid mixture by a compressed gas, e.g. in the form of supercritical CO2 extraction,

 - The distillation in which the molecule to be separated is evaporated from a liquid mixture and is again condensed in a cooling column, and

Analytical methods, such as gas chromatography, which is a combination of the above-mentioned methods. The listed extraction methods are used in analytical chemistry (here in particular chromatography) as well as in the pharmaceutical and chemical industries (in particular chromatography and liquid-liquid extraction) and petrochemistry (in particular distillation). The methods which enable a high transport of substances are associated with a considerable input of energy and thus a cost. Separating membranes for the separation of carboxylic acids dissolved in an aqueous medium and membrane-based separation processes for carboxylic acids dissolved in an aqueous medium are nonexistent.

Detailed description

 Carboxylic acids can only be separated discontinuously from an aqueous medium by the abovementioned processes. In the deprotonated state, carboxylic acids have a negative charge and can thus be moved in an electric field of tension. Therefore, in principle, an electrophoretic separation of carboxylic acids is possible. In the passage of carboxylic acids through an open-pore separation medium, such as e.g. a filter membrane, the surfaces are occupied by adhering carboxylic acids, it is irrelevant whether the surface properties of such membranes are hydrophobic or hydrophilic. Furthermore, compounds which are also present in the aqueous medium and which themselves have a negative charge and / or are loaded with deprotonated carboxylic acids, are transported along in an electrophoretic separation through a membrane. Therefore, a selective separation of carboxylic acids from aqueous organic mixtures by an open-cell membrane and methods of the prior art is not possible.

Membrane-based processes for material separation at the molecular level are carried out according to the state of the art with closed membranes, which allow a diffusive mass transfer of the molecular structures to be separated, and summarized under the term nanofiltration. The disadvantage here is that the quantities of material that can be transported per membrane surface unit are only small and that a high energy requirement (eg for a pneumatic pressure build-up of 20-80 bar) is required for the separation (A comprehensive review of nanofiltration membranes: treatment, pretreatment, modeling, and atomic force microscopy, N. Hilal, H. Al-Zoubi, NA Darwish, AW Mohammad, M. Abu Arabi, Desalination 2004, 170: 281-308). Therefore, separation processes with closed membranes are not suitable if large amounts of substance to be separated. For the separation of substance classes, the use of open-pore membranes with nano-scaled channel diameters has recently been proposed, which theoretically allows a much higher mass transport than with closed Membranes (Molecular Sieving Using Nanofilters: Past, Present and Future, Jongyoon Han, Jianping Fu, Reto B. Schoch., Lab Chip., 2008, 8 (1): 23-33). More recently, micro- and nanofluidic processes for the selective separation of mixtures have been presented. It could be shown that hydrophilic and hydrophobic compounds, which are present together in an aqueous medium, can be selectively separated by diffusion through membranes, which have highly ordered nanoscale channels and were provided with a hydrophilic or hydrophobic surface coating (solvent extraction and Langmuir Adsorption-Based Transport in Chemically Functionalized Nanopore Membranes, Damian J. Odom, Lane A. Baker, and Charles R. Martin, J. Phys. Chem. B 2005, 109, 20887-20894). The selectivity for the compounds to be separated is achieved by a surface coating of the channel walls. As a result, a selectivity index of up to five for a diffusive mass transfer could be documented for the separation of apolar compounds. It has now been found that the properties attainable with sole surface coating of nanoscale channels are not suitable for ensuring sufficient selectivity for the separation of carboxylic acids from other organic compounds similar to carboxylic acids in a diffusive separation process. Further, in such membranes, there is no selectivity for the separation of different organic compounds when an electrical gradient is applied to the separation membrane. Thus, from a solution containing albumin and dissolved fatty acids, fatty acids could be separated by diffusion through a membrane having channels of 100nm and their surfaces coated with alcylsilanes into an acceptor medium, with minimal transport of albumin takes place through the membrane. If the same experiment was carried out with the application of a transmembrane electrical gradient, albumin and fatty acids passed through such a membrane, which occurred to the same extent, but no selectivity of the mass transfer then existed. Thus, by a surface coating such. B. by a hydrophobization of the filter membrane surfaces, alone do not produce a selective electrophoretic mass transport for amphiphilic carboxylic acids. For electrophoretic separations of organic compounds with membranes it is known that there are strong fouling processes, in particular on anion-selective membranes (Fouling of electrodialysis membranes by organic substances, Lindstrand, V; Sundstrom, G and Jönsson, Ann-Sofi LU (2000), in Desalination 128 (1), p.102-91.) Furthermore, the development of electro-osmotic flow phenomena in a strain on membranes with micro- and nanofluidic channels is described. Accordingly, it is not apparent from the prior art how substance-group-specific release properties for carboxylic acids could be implemented in an open-pore separation apparatus. It is therefore an object of the present invention to provide an open-pore separation membrane and a process for the separation of carboxylic acids and / or fatty acids from a solution or an emulsion through a membrane. It is a further object of the invention to provide processes for preparing such separation membranes and processes for the separation of carboxylic acids and / or fatty acids using such separation membranes.

This object is achieved by the technical teaching of the independent claims. Further advantageous embodiments of the invention will become apparent from the dependent claims, the description, the figures and the examples.

One aspect of the present invention relates to an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm, and

 II) a space-spanning polymeric structural network in the pores of the support membrane.

In other words, the present invention relates to an open-pored membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm, and

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the space-spanning polymeric structural network spans the pores of the open cell membrane and is not a pure surface coating of the pores of the open cell membrane.

Stated another way, the present invention relates to an open-cell membrane for the selective electrophoretic separation of carboxylic acids from a mixture of substances in aqueous solution, comprising or consisting of: I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm, and

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the space-spanning polymeric structural network spans the pores of the open cell membrane.

The present invention further relates to an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm, and

 II) a space-spanning polymeric structural network in the

Pores of the support membrane,

wherein for the separation of the carboxylic acids, a concentration gradient and / or electrical gradient is established at the membrane. In other words, the underlying invention further relates to an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm, and

 II) a space-spanning polymeric structural network in the pores of the support membrane, and

 III) means for generating a concentration gradient and / or an electrical gradient at the membrane.

A further aspect of the present invention relates to a process for producing an open-pored membrane according to the invention for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a), c) polymerization of the polymerizable monomers or oligomers in the pores of the open-pore carrier membrane to form a space-spanning polymeric structure network in the pores of the open-pore carrier membrane.

Starting from solutions with reactive amino acid monomers, formation of compact but open-celled masses resulted after formation of a nucleophilic polymerization reaction, which exhibited a high capacity for absorbing fatty acids and were not wettable by water due to the hydrophobicity. However, such polymer structures are brittle and fragile, since there does not appear to be sufficient cross-linking between the polymer chains during self-assembly. It has therefore been attempted to establish such self-assembly in given nano-scaled channels by first contacting the channel surfaces with a reaction-initiating coating, such as e.g. Aminosilanes, were coated over the entire surface. A static or dynamic loading of the membrane channels with a monomer solution gave different results. In some cases, the polymerization resulted in complete closure of the channels and in part only in superficial coverage of the channels with a polymer layer. While membranes with fully buried channels could not be traversed by carboxylic acids, membranes that had a surface channel coating that could be quantified by scanning electron microscopy showed amplification of electroosmotic flow when an electrical voltage was applied in an electrodialysis cell.

Electro-osmotic flow is accomplished by occupying surfaces, e.g. in a membrane, with ions being moved in an electric field. The superficially mobile ion layer is transported in the electric field, whereby the water sheath bound to the ions is transported and thus a water volume transport is created. It is known from the literature that electrodialysis with membranes having microfluidic channels leads to the formation of an electroosmotic flow (EOF). With a negatively charged surface of the channel walls, the direction of the EOF is opposite to the electrokinetic direction of transport of anions.

In electrodialysis of dissolved fatty acids with membranes whose nanochannels had been coated with hydrophobic compounds, an EOF was also formed. This phenomenon can be explained by an adsorption of fatty acids on the channel wall surfaces, which results from hydrophobic interaction forces, resulting in a negative charge on the channel wall surfaces through deprotonated carboxyl groups. For electrodialysis examinations, which were carried out with such membranes to separate carboxylic acids, which were dissolved in an aqueous medium from this into another aqueous medium, it was found that the EOF, the electro-kinetic transport of carboxylic acids is considerably limited. Upon establishing a pneumatic pressure in the donor chamber that matched the pressure buildup achieved by the EOF, the amount of electro-kinetically transported carboxylic acids increased. The establishment of a pressure build-up in such a device which results in the elimination of an electro-osmotic flow is difficult, since the strength of the electro-osmotic flow depends on many factors, such as the acceptor and donor medium ion concentration, and the applied voltage and others Factors (eg the surface charge of the membrane channels).

Since an EOF affects the effectiveness of a separation of carboxylic acids, which can be achieved with an electrodialysis, it is also the object of the invention to provide a membrane in which no or only a small electro - osmotic flow arises, so that the establishment of a pneumatic Counterpressure is not required.

Surprisingly, it has been found that no electro-osmotic flow is produced in open-cell membranes according to the invention or produced according to the invention. Therefore, an embodiment of the invention is an open-pore membrane or an open-pore membrane available or obtained by a method according to the invention, wherein the open-cell membrane prevents an electro-osmotic flow through the open-cell membrane. An embodiment of the underlying invention therefore relates to an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the open cell membrane prevents electro-osmotic flow through the open cell membranes.

Preference is given to the preparation of self-assembled nanocavity polymer structures for the reduction / elimination of an electro-osmotic flow. Based on the results of a surface coating of nanochannels with hydrophobic polymers, a change in the reaction parameters (including time duration, reaction temperature, concentration of the monomers) resulted in a higher full-area polymeric layer structure in the nanochannels, resulting in a further reduction of the free channel lightings. However, this resulted in an increase in EOF and a reduction in the separation efficiency of carboxylic acids.

 A surprising result has been the use of compounds in the solutions containing reactive mono- / oligomers which can promote or cause a polymerization reaction of the reactive mono- / oligomers. In such formulations, polymers formed on planar surfaces exhibited irregular electron-microscopic structures which had fabric-like textures but were fragile as an independent layer or mass. They were porous and could rapidly pick up liquid carboxylic acids in the three-dimensional network that had formed. They were not wettable with water. Such layers / masses were easily removed mechanically from the contact surface and disintegrated into the smallest particles. When porous materials were filled with reactive mono- / oligomer solutions and a polymerization reaction was initiated by a reaction activation, e.g. by solvent or physical measures, similar fabric-like structures formed in the porous materials that filled the entire volume of the channels / columns, but remained open-pored, as the fabric-like polymer structures formed nano-scaled gaps. The reaction activation of the polymerizable monomers and / or oligomers is preferably carried out starting from the solvent phase. This means that by solvent, activators or physical means the polymerization reaction is initiated by components in the solvent phase and preferably not by an activator on the surface of the support membrane. However, this does not mean that an interaction or reaction with the surface of the support membrane may take place during or after polymerization.

Such treated membranes also received liquid carboxylic acids and did not allow uptake of water. Electron microscopy showed that in such membranes polymer structures were formed, which have textures that can be strand-like and form a three-dimensional network but can also be made of flat tissue structures that are parallel or in an irregular arrangement to each other and in which the polymeric tissue structures the entire Space that through the space-limiting internal structures of the support membrane was predetermined, filled. The resulting polymer structures were altered by physical measures that are not changed in their structure or properties by a pressure rinse with water or organic solvents, as well as by an ultrasonic bath. Porosimetry and electron microscopy revealed that the three-dimensional space-filling but non-space-occlusive polymer structures confined irregularly configured cleavage spaces, which were openly interconnected and ensured communication between both outer surfaces of the treated membranes. Such membranes were thus not closed. In the case of membranes which were lined with room-filling or space-spanning polymer structures, surprisingly, electrodialysis of aqueous media with fatty acids dissolved therein produced virtually no EOF, with a simultaneously high transport rate for fatty acids.

Therefore, another aspect of the present invention is directed to an open cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture obtainable or obtained by a process according to the invention.

Thus, another aspect of the present invention is an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture obtainable or obtained by a process comprising the steps of: a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 b) introducing a solution of polymerizable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a), c) polymerizing the polymerizable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymeric structural network in the pores of the open-pore carrier membrane.

The inventor could further show that, by appropriate choice of polymerization conditions, three-dimensional fabric-like polymer structures which give rise to nanocavitary fissures are formed by self-assembly within the open-celled host membrane which is open-pored and permeable to carboxylic acids and gases and prevents electroosmotic flow. Not according to the invention, however, is the filling of the space-filling open-pore carrier membrane with a polymer which is polymerized was generated, so that thereby the pores, channels or slots are closed by the polymer formed. Likewise not according to the invention are membranes whose interior spaces or pores are filled with a polymer which has been produced by a polymerization in such a way that the interior spaces or pores are closed. Likewise, the surface coating of the pores, channels or slots of the space-giving open-pore carrier membrane with a polymer is not according to the invention. Accordingly, an open-pore membrane, the interior spaces, pores, channels or slots of the space-giving open-pore carrier membrane are superficially coated, just as little according to the invention. The space-filling or space-spanning open-pore polymer structures according to the invention are preferably achieved by "self-assembly" of mono- / oligomers into polymeric textures and are preferably covalently and / or electrostatically bonded to the surfaces of the open-pore carrier membrane in the pores of the porous support membrane, wherein the open-pore polymer structures are preferably nanocavity polymer structures.

Furthermore, the polymeric structural network is preferably the result of a "self-assembly" of monomers and / or oligomers, and the polymer structures or the polymeric structural network are preferably covalently bonded to the inner surfaces of the open-celled support membrane. the polymeric structural network is covalently cross-linked in three dimensions.

Surprisingly, it has been shown that a selective separation of carboxylic acids from an aqueous mixture of substances by membranes with a space-spanning polymeric structural network, which was obtained by a self-assembly, is made possible.

One embodiment of the present invention thus relates to an open-pore membrane described herein for the electrophoretic separation of carboxylic acids from a liquid mixture, wherein the space-spanning polymeric structural network is nanocavitary.

Thus, an embodiment of the invention is an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of: I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a room-spanning polymeric structural network in the pores of the support membrane;

wherein the space-spanning polymeric structure network is nanocavitary.

The underlying invention is directed to a process for the preparation of an open cell membrane according to the invention for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

Providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 Introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 Forming a nanocavity room-spanning polymeric structural network within said open-celled support membrane by reaction activation of

Polymerization reaction of the polymerizable monomers or oligomers in the pores of the open-celled support membrane.

In other words, the underlying invention relates to a process for producing an open-pored membrane according to the invention for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

c) forming a nanocavity room-spanning polymeric structural network within said open-celled support membrane by polymerizing the polymerisable monomers or oligomers in the pores of the open-celled support membrane to obtain the open porosity of the membrane. The open-pore membranes of the invention described herein are characterized in particular by the fact that they are suitable for the selective electrophoretic separation of carboxylic acids from a liquid mixture. One embodiment of the present invention relates to an open-cell membrane for the selective electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm, and

 II) a space-spanning polymeric structural network in the pores of the support membrane.

One embodiment of the present invention therefore relates to an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm, and

 II) a space-spanning polymeric structural network in the

Pores of the support membrane,

wherein the open cell membrane is selective towards carboxylic acids.

Furthermore, an embodiment of the present invention is directed to a process for producing an open-pored membrane according to the invention for the selective electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerizable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a), c) polymerizing the polymerizable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymeric structural network in the pores of the open-pore carrier membrane.

Therefore, another embodiment of the present invention is directed to a process for producing an open cell membrane of the invention Electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a), c) polymerizing the polymerisable monomers or oligomers in the pores of the open-pore carrier membrane to form a space-spanning polymeric structural network in the pores of the open-pore carrier membrane,

wherein the open cell membrane is selective towards carboxylic acids.

Preferred is an open-pore membrane described herein for the separation of carboxylic acids from a liquid mixture, wherein the open-cell membrane has a selectivity index for carboxylic acids over the corresponding alcohols of> 4. The corresponding alcohol to hexanoic acid is e.g. Hexane-1-ol. Preference is furthermore given to a process according to the invention for the production of open-pore membranes which permit selective transport of carbonic acids with a selectivity index of> 4 relative to the corresponding alcohol. Consequently, the open-cell membranes or open-pore membranes according to the invention are obtainable or obtained by a process according to the invention for the continuous separation of carboxylic acids, preferably of fatty acids, from liquid mixtures containing the carboxylic acids and preferably the fatty acids, this mixture being on one side of a membrane according to the invention with continuous pores, channels or slits and the carboxylic acids and preferably the fatty acids these continuous pores, channels or slits are transported to the other side of the membrane, with a selectivity index> 4 relative to that derived from the carboxylic acid by reduction ltlichen alcohol.

Therefore, an embodiment of the present invention is an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture consisting of: I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the open-pore membrane has a selectivity index for carboxylic acids over the corresponding alcohols of> 4.

A high concentration of the monomers in the reaction solution was found to be advantageous for the formation of space-filling or space-spanning polymer structures. However, this requires a high viscosity of the reaction solution, which makes incorporation into nano- or microchannels virtually impossible. It has been shown that reaction solutions with a high content of monomers can be introduced into various separation media which have channel and / or slot structures in the micrometer to millimeter range and that radical or nucleophilic polymerization can be initiated by various starting reactions which lead to Formation of nanocavity polymer structures leads, preferably it is a multifocal radical or nucleophilic polymerization. Following a polymerization according to the invention, space-filling or more precisely space-spanning structural structures / textures are present in such membranes. These structural structures preferably form nanoscale cavities which are connected to one another.

 Such membranes are porous, since a gas flow could pass through such membranes.

Electron microscopically, the polymer structures thus produced differ from those initiated by a start reaction due to contact with a coated surface, in the sense of a "grafting from" polymerization process and obtained by a self-sustained polymerization, characterized in that the polymer layer is not a closed mass, open-pore, with the formation of filamentous to membranous structures, which formed space-filling or space-spanning irregularly-restricted cleavage sites, thus initiating a radical or nucleophilic polymerization reaction in a monomer and / or oligomer solution by addition of a chemical initiator and / or physical reaction initiation Process for accelerating a polymerization reaction of a solution with reactive mono- / oligomers Particularly preferred embodiments for the preparation of the membranes of the invention. In a further preferred embodiment of the underlying invention, the process for producing an open-pore membrane according to the invention for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the polymerization reaction in step c) is initiated by the addition or application of a chemical and / or physical initiator of a radical or nucleophilic polymerization. In a further preferred embodiment of the underlying invention, the process for producing an open-pore membrane according to the invention for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps:

 a) providing an open-porous carrier membrane with pores having a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein in step c) the solution of the polymerisable monomers and / or oligomers is heated and / or the solution contains a solvent which initiates a polymerization.

Accordingly, another preferred embodiment of the invention is an open-cell membrane for the electrophoretic separation of carboxylic acids a liquid mixture or obtained by a process comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the polymerization reaction in step c) is initiated by the addition or application of a chemical and / or physical initiator of a radical or nucleophilic polymerization.

Therefore, a further preferred embodiment of the invention is an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture obtainable or obtained by a process comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein in step c) the solution of the polymerisable monomers and / or oligomers is heated and / or the solution contains a solvent which initiates a polymerization.

In a preferred method, in one of the methods described herein, a reactive monomer solution is fully incorporated into a microporous and / or macroporous support membrane and the polymerization initiated by the solvent phase, ie, the polymerization in step c) is characterized by a solution contained in the solution Solvent initiated. Therefore, a further preferred embodiment of the present invention is a process for producing an open-pore membrane for the electrophoretic separation of carboxylic acids from liquid mixtures comprising the steps: a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter from 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein in step c) the solution contains a solvent which initiates the polymerization.

Surprisingly, there is no or minimal EOF during electrodialysis of carboxylic acids in the use of open-cell membranes with space-filling or space-spanning nanocavity polymer structures.

Preference is therefore given to a process for the preparation of open-cell membranes comprising a self-assembled nanocavity room-spanning polymeric structural network for the reduction / elimination of an electro-osmotic flow.

Further preferably, an open-pored membrane is obtainable or obtained by a process for the production of open-pore membranes comprising a self-assembled nanocavity room-spanning polymeric structural network for the reduction / elimination of an electro-osmotic flow.

Thus, an open-celled membrane described herein is preferred which has a self-assembled nanocavity spanning polymeric structural network for reducing / eliminating electro-osmotic flow.

In another particularly preferred embodiment, the membrane of the invention and / or a separate membrane is / is coated with a polycation. Suitable polycations are described in more detail in the section "Post-polymerization Functionalization." The coating can be used in Form of adsorption and / or covalent bonding or physiosorptive and / or chemisorptive carried to the surface of the support material. In this case, the coating can be applied on the surface, preferably on the side facing the acceptor medium. However, the coating can also be introduced into the cleavage spaces of the membrane, which in turn can take place in the form of an adsorption and / or a covalent bond or physiosorptive and / or chemisorptive. Methods for this are known in the art. In a particularly preferred embodiment, a free-bearing layer consisting of polycationic compounds is used by bringing them together with a membrane according to the invention. This bringing together means a close spatial contact, the z. B. is achieved by the membranes are pressed together by a suitable holding device to each other, whereby a gap formation between the two membranes is prevented. Such an arrangement also occurs when using a separate membrane which has been coated with a polycation.

Preference is given to a process in which an elimination of an electro-osmotic flow is effected by at least one polycationic compounds being applied in the optional step d2) in a physiosorptive and / or chemosorptive manner onto the surfaces of the polymer matrix network spanning the space. Accordingly, an open-pore membrane according to the invention is obtainable or obtained by a process in which a suppression of an electro-osmotic flow takes place by at least one polycationic compound being applied in the optional step d2) to the surfaces of the space-spanning polymer structure network in a physiosorptive and / or chemosorptive manner.

 A preferred embodiment of the present invention is directed to an open cell membrane or obtained by a process comprising the steps of:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane, d2) Physiosorptive and / or chemosorptive application of at least one polycationic compound to the surfaces of the polymer structures of the space-spanning polymeric structural network.

Furthermore, an open-pored membrane according to the invention is furthermore preferably also comprising a functionalization of the surfaces of the space-spanning polymeric structural network.

 Therefore, in an embodiment according to the invention, the open-pore membrane comprises or consists for the electrophoretic separation of carboxylic acids from a liquid mixture of substances:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structural network in the

Pores of the support membrane,

wherein the surfaces of the space-spanning polymeric structural network is functionalized with at least one polycationic compound. Furthermore, an open-pored membrane according to the invention is furthermore preferably further comprising a functionalization of the surfaces of the nanocavity-spanning polymeric structural network.

 Therefore, in an embodiment according to the invention, the open-pore membrane comprises or consists for the electrophoretic separation of carboxylic acids from a liquid mixture of substances:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the surfaces of the space-spanning polymeric structural network is functionalized with at least one polycationic compound.

Particularly preferred are open-pore membranes, wherein the surface of the space-spanning polymeric structural network is functionalized with at least one hydrophobic polycationic compound. Hydrophobic herein means that the polycationic compound preferably has a K _ow of> 0.3, more preferably of 0.4, more preferably of 0.4, more preferably of 0.5, even more preferably of 0.6, even more preferably from 0.7, more preferably from> 0.8 and most preferably> 1. Hydrophobic does not mean that the compounds can not be dissolved in one part in an aqueous medium. Therefore, in a preferred embodiment, the open-pored membrane for electrophoretic separation of carboxylic acids from a liquid mixture of substances comprises or consists of:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the surfaces of the space-spanning polymeric structural network is functionalized with at least one hydrophobic polycationic compound.

Also preferred is a membrane according to the invention described herein, further comprising a coating on the surfaces of the space-spanning polymeric structural network comprising at least one compound selected from the group consisting of or consisting of amphiphilic and / or cationic and / or polycationic compound.

Therefore, a preferred embodiment of the present invention is an open cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the surfaces of the space-spanning polymeric structural network comprises a coating comprising at least one compound selected from the group consisting of or consisting of amphiphilic and / or cationic and / or polycationic compounds. Preference is given to open-pore membranes for the electrophoretic separation of carboxylic acids in which polycationic compounds are applied to the nanocavitamin polymer structures in a physiosorptive and / or chemosorptive manner and bring about an inhibition of an electro-osmotic flow. Preference is given to open-pore membranes for the selective removal of carboxylic acids, in which a further membrane, which has been adsorptively and / or chemosorptively coated with a polycationic compound (s), is brought into close spatial contact with the separation membrane in order to obtain an electrochemical to reduce osmotic flow.

Another aspect of the present invention relates to a method for suppressing the electro-osmotic flow, which is achieved by the separation membrane and / or another membrane is adsorptively and / or chemosorptively coated with a polycationic compound (s) In the case of a separate membrane, this is brought into close spatial contact with the separation membrane.

 Preference is given to open-cell membranes according to the invention described herein for the electrophoretic separation of carboxylic acids, wherein furthermore the surfaces of the room-spanning polymeric structural network are ionically and / or chemosorptively functionalized with ionic and / or ionizable compounds.

A preferred embodiment of the invention therefore relates to a process for producing an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, preferably a mixture of substances in aqueous solution, comprising the steps:

 Providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerization of the polymerizable monomers or oligomers in the pores of the open-pore carrier membrane to form a space-spanning polymeric structural network in the pores of the open-pore carrier membrane, wherein the surfaces of the space-spanning, polymeric structural network are functionalized with ionic and / or ionizable compounds.

Preferred is a method in which inhibition of the electro-osmotic flow is produced by bringing a free-bearing membrane composed of polycationic compounds or in which polycationic compounds are integrated into close spatial contact with the separation membrane. Another aspect of the invention relates to the surface charge of the space-spanning polymeric structural network in the membranes produced according to the invention. The surface charge can be determined by a transmembrane determination of the zeta potential. The zeta potential of the membrane according to the invention is preferably 0 mV. In further preferred embodiments, the membranes according to the invention have a zeta potential which is not equal to 0 mV and lies in a range between + 40 mV and -80 mV. Depending on the composition and the properties (eg pH) of the aqueous media from which carboxylic acids are to be separated by a membrane according to the invention, it may be necessary to provide positive and / or negative charge groups on the surfaces of the nanocavity polymer structures. This can be achieved by incorporating ionic or ionizable compounds into the polymer structures. Since positive or negative charge groups can interfere with the polymerization reaction of stage c) of the preparation process according to the invention, in one embodiment the ionic or ionizable compounds are provided with a protective group and added to the reaction mixture in stage b). In another embodiment, these protecting groups are cleaved in optional step d1) by appropriate reagents or physical means and subsequently removed from the membrane. In another embodiment, ionic and / or ionizable compounds in the optional process step d2) are attached to the surfaces of the nanocavitamin polymer structures in a physio- and / or chemosorptive manner. For this it may be necessary to first prepare reactive groups on the polymer structures. Methods for this are known in the art. After a subsequent physio- and / or chemosorptive addition of ionic or ionizable compounds and after the removal of protective groups such membranes are carefully cleaned of unreacted or eliminated compounds. Scalable surface charges of the membranes of the present invention can be made in these optional process steps, preferably in the range of + 0.1mV to + 40mV, as long as a positive zeta potential is desired and in the range of -0.1mV to -80mV if a negative zeta potential is required.

Preference is given to a process in which protective groups of the mono- / oligomers reacted in stage c) in stage d1) are removed by suitable reagents or physical measures and subsequently removed from the membrane.

A preferred embodiment of the present invention is a process for producing an open-pored membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps: a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

 d1) cleavage of the protective groups,

wherein the introduced mono and / or oligomer solution contains protected monomers and / or protected oligomers and the monomers and / or oligomers are ionic and / or ionizable.

Preference is given to open-cell membranes for the electrophoretic separation of carboxylic acids from liquid mixtures in which ionic and / or ionizable compounds are attached physiologically and / or chemosorptively to the surfaces of the room-spanning polymeric structural network.

A preferred embodiment of the present invention is a process for producing an open-pored membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a), wherein the introduced mono- and / or oligomer solution contains protected monomers and / or protected oligomers,

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

d2) binding of an ionic and / or ionizable compound to the deprotected, open-pore, space-spanning polymeric structural network. Preference is given to a process in which ionic and / or ionizable compounds in a process step d2) are attached physiologically and / or chemosorptively to the surfaces of the structurally spanning structural network.

In a further preferred embodiment of the present invention, the process for producing an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerizable monomers and / or

Oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

 d2) binding of an ionic and / or ionizable compound to the open-pore nanocavity room-spanning polymer

Structure network.

Another aspect of the invention relates to the physical properties of the membranes of the invention. Such membranes are on the one hand hydrophobic and on the other hand lipophilic. In a preferred embodiment, the nanocavity polymer structures according to the invention are prepared by a polymerization process which is started in situ by nucleophilic reaction initiation of a monomer solution. This initiation is referred to herein as "reaction activation" or "reaction initiation." This includes nucleophilic and free-radical reactions involving covalent bonding between one or more mono- / oligomers, or covalent bonding with other compounds (eg, organic compounds on surfaces of the bulk support membrane). In a particularly preferred embodiment, the reaction products additionally promote the formation of the nanocavitaminic polymer structures.The term reaction initiation also means suitable measures for a multifocal start of the polymerization so that nanocavitary spatial structures within the space-giving open-pore open pores are formed In other words, reaction initiation prevents / prevents a uniform layer buildup or the formation of compact dressings of the forming polymers by a multifocal polymer growth. Suitable reaction activation means include adding initiators of polymerization reactions, raising the temperature, lowering the temperature, adding a solvent, irradiating, increasing or decreasing the pressure, as well as known methods of the prior art. The reaction activation prevents the formation of a compact layer of the polymer on the surfaces of the supporting fabric and a closure of the pores of a porous membrane. A preferred embodiment of the invention thus relates to a process for producing an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the formation of the space-spanning, polymeric structural network in step c) takes place via a multifocal polymer growth.

Decisive for the present invention, and therefore preferred, is that the monomers and / or oligomers used are room-polymerizable.

 In a preferred embodiment of the present invention, the process for producing an open-pored membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a), c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the introduced into the pores of the support membrane monomers and / or oligomers are room spanning polymerizable.

Preferably, the mono- or oligomers are in the form of a solution or suspension in a suitable solvent. Preferred solvents are, acetonitrile, THF, 1, 4-dioxane, Ν, Ν-dimethylformamide (DMF) dichloromethane, chloroform, methyl tert-butyl ether or similar solvents, such as. N, N-dimethylacetamide (DMA) and N-methylpyrrolidone (NMP), DMSO, water, methanol, toluene, xylene, anisole and other organic solvents and combinations thereof or hereby.

The choice of monomer / oligomer concentration will depend on the resulting physical properties and solubility. Preferably, the concentration is to be selected from a range between 1 mmol / l and 3 mol / l, more preferably between 10 mmol / l and 1 mol / l and more preferably between 100 mmol / l and 0.5 mol / l.

 In a further preferred embodiment of the present invention, the process for producing an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps:

 a) providing an open-porous carrier membrane with pores having a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the monomer and / or oligomer concentration of said mono and / or oligomer solution is between 1 mmol / l and 3 mol / l.

A further preferred embodiment of the present invention is an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture obtainable or obtained by a process comprising the steps: Providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the monomer and / or oligomer concentration of said mono and / or oligomer solution is between 1 mmol / l and 3 mol / l.

In a preferred embodiment, the preparation of nanocavitären polymer structures by a suitable and prepared structure and space-giving membrane is filled to saturation with the reactive mono- / oligomer solution. The filling can be carried out by impregnation, pouring, loading with / in the monomer / oligomer solution or by a continuous or discontinuous volume flow of the mono- / oligomer solution through the membrane. It may be necessary to lower or raise the temperature. Preferably, the introduction of the mono- / oligomer solution in the structuring membrane at a temperature of -10 to 100 ° C, more preferably between 0 ° C and 80 ° C and more preferably between 10 ° C and 40 ° C.

In a further preferred embodiment, the nanocavity polymer structures according to the invention are prepared by a polymerization process which is started in situ by a free-radical or nucleophilic reaction initiation of a monomer and / or oligomer solution.

 In a further preferred embodiment of the present invention, the process for producing an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps:

 Providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

c) polymerization of the polymerizable monomers or oligomers in the pores of the open-pore carrier membrane to form a space-spanning polymer structure network in the pores of the open-pore carrier membrane,

wherein the reaction activation takes place radically or nucleophilic in situ. Initiators of a reaction of the mono- / oligomers are substances that can initiate a ring-opening or free-radical polymerization, as known from the prior art. These include solvents such as water, DMF, NMP, DMSO, tetramethylurea. Nucleophiles, such as amines, amides, alcoholates, hydroxide ions, thiolates, triethylamine, ammonia, pyridines, such as 4-dimethylaminopyridine, phosphines, carbenes, such as imidazol-2-ylidenes and imidazolin-2-ylidenes or thiazol-2-ylidenes. Cationic catalysts, such as trifluoromethanesulfonic acid and methyltrifluoromethanesulfonate, bifunctional organocatalysts, such as [1- (3,5-bis (trifluoromethyl) phenyl) -3- (2-dimethylamino-cyclohexyl) thiourea] or [1, 5,7-triazabicyclo ( 4.4.0) dec-5-ene (TBD). Catalysts such as Grubb's catalyst, metal ions such as copper, tin, for example as tin octanoate (Sn (Oct) ₂ ), aluminum alkoxides Al (OR) 3, titanium alkoxides (Ti (OR) ₄ ), cobalt or nickel, acids such as ascorbic acid, sulfuric acid or phosphoric acid, furthermore azo compounds, such as AIBN or peroxides, such as benzoyl peroxide.

 In a preferred embodiment, the substances / compounds which initiate a starting reaction are added to a carrier structure of the mono- / oligomer solution immediately before the introduction of the monomer / oligomer solution and / or have been previously applied to the surfaces of the carrier structure. The ring-opening polymerization is preferably carried out with a nucleophile-induced polymerization, preferably previously amines are applied to the surfaces of the carrier structures. In one embodiment, the initiator of a free-radical or nucleophilic polymerization is added to the mono- / oligomer solution immediately prior to introduction into the supporting tissue.

Particularly preferred is the use of solvents which can initiate a nucleophilic reaction, such as DMF, DMA or NMP. Further preferred is the use of solvent combinations. In a preferred embodiment, a mono- or oligomer solution present in a solvent which does not initiate a nucleophilic reaction, a solvent which effects a nucleophilic reaction, is added immediately prior to introduction of the solution into the open-celled support membrane. For example, a ring-opening polymerization of amino acid monomers dissolved in THF can be initiated by the addition of 10% by volume DMF.

Preferably, the initiation of the free-radical or ring-opening reaction in the solvent phase is by physical means. This includes one Heating the substrate, preferably heating to 40 to 160 ° C, more preferably to 60 ° to 120 ° C and more preferably to 80 ° to 1 10 ° C. In a preferred embodiment, the polymerization reaction takes place at an overpressure or at a reduced pressure. Preference is given to the application of a pressure between 1, 1 bar and 10bar. Further preferred is the installation of a negative pressure between 10 and 900 mbar. Further preferred is the application of a pressure curve. Thus, in one embodiment initially an increased pressure can be applied and in the course of this is lowered continuously or stepwise. In a particularly preferred embodiment, the solvent-induced polymerization initiation takes place in a container with a controllable inlet / outlet valve. In a further particularly preferred embodiment, the temperature of the membrane filled with the reaction solution takes place according to a two-stage or multistage or continuous flow pattern with different temperatures. Preferred is a duration of a temperature increase between 10 minutes and 72 hours, more preferably between 30 minutes and 48 hours and more preferably between 2 and 24 hours.

In a further preferred type of process, the reaction initiation of the mono- / polymer solution takes place in a space-providing supporting fabric by a polycondensation in the form of a melt. Preferably, temperatures are chosen here which are around or above the individual melting point of the monomers used. Preference is given to heating to 40 to 200 ° C, more preferably to 80 ° to 140 ° C and more preferably to 90 ° to 140 ° C. Another preferred method for initiating polymerization is exposure of the open-celled membrane impregnated with a mono- / oligomer solution to long or short wave radiation. Particularly preferred is the application of microwaves. In a preferred embodiment of the process, the reactive mono- / oligomers are concentrated in the internal spatial structures of the porous support membrane prior to reaction activation. In one embodiment, this can be done by introducing the solution with the reactive mono- / oligomers into the support membrane and then evaporating the solvent by appropriate means, preferably without causing a reaction activation. This can be achieved, for example, by performing the evaporation at a reduced temperature and an applied vacuum. This process can be repeated in the required number. It is preferred to carry out thereafter a melt or irradiation of the accumulated reactive mono- / oligomers. It has been shown that the nano-cavitation spaces formed during the polymerization can be influenced by additionally adding to the solution with mono- and / or oligomers compounds which do not participate in a polymerization reaction. These additional connections are inert to the reaction conditions. These compounds, which may also be referred to as release agents, are preferably hydrophobic and low molecular weight compounds. In this connection, a low-molecular compound preferably means a compound having a molecular mass of at most 1000 g / mol. Hydrophobic here means that the compound preferably has a K _ow of> 0.3, more preferably of 0.4, more preferably of 0.4, more preferably of 0.5, even more preferably of 0.6, even more preferably of 0.7, more preferably> 0.8 and most preferably> 1. Hydrophobic does not mean that the compounds can not be dissolved in one part in an aqueous medium. Furthermore, they are preferably oleophilic and can be completely removed again after the multifocal polymerization according to the invention by means of a suitable solvent from the membrane with a space-spanning polymer structure network. Mixtures of release agents may also be used. Preferred compounds which can be used as release agents in a multifocal polymerization, in particular aliphatic or aromatic hydrocarbons, such as alkanes, alkenes, alkynes, cycloalkanes, cycloalkenes, cycloalkynes, isoprenes, terpenes, alcohols, phenols, carboxylic acids or their salts, carboxylic acid alkyl esters , Fatty alcohols or their salts, carbonic acid dialkyl esters, ethers, alkylsulfonic acids or their salts, alkylsulfuric esters, dialkylsulfoxides, dialkylsulfones, amides, carbamates and organic phosphorus compounds.

 The molar ratio between the release agent and the monomer or oligomer is preferably in the range of 1: 100-1: 1, preferably 1: 100-1: 2, more preferably between 1: 80-1: 3, more preferably between 1: 60-1: 4, more preferably between 1: 40-1: 5 and even more preferably between 1: 30-1: 6 and even more preferably between 1:20 -1:10.

In this context, the term "alkyl" also means aryl or alkylaryl compounds Preferably, an "alkyl" radical comprises 1 to 30 carbon atoms (C 1 -C 30 -alkyl), more preferably 4 to 22 carbon atoms and even more preferably 6 - 22 carbon atoms. Preferably, an "aryl" radical comprises from 6 to 14 carbon atoms of (Ce-Ci ₄ -aryl) Preferably, an "alkylaryl" radical comprises from 7 to 15 carbon atoms (C ₇ -C 15 -alkylaryl).

Thus, in a preferred embodiment, the process of making an open cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps of: a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the solution in step b) further contains a release agent.

Particularly preferred is a ring-opening polymerization, which takes place while heating the substrate.

Preferred is a method described herein, wherein in step c) the formation of a space-spanning polymeric structural network by ring-opening polymerization takes place, wherein the solution of the polymerizable monomers and / or oligomers is heated and / or the solution contains a solvent which is a ring-opening or free-radical polymerization initiated. Therefore, open-cell membranes are also available or obtained by the method just described.

 In a further preferred embodiment of the present invention, the process for producing an open-pore membrane for the electrophoretic separation of carboxylic acids from liquid mixtures therefore comprises the steps of: a) providing an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μm and a maximum diameter from 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein in step c) the formation of a space-spanning polymeric structural network is carried out by ring-opening polymerization, wherein the solution of polymerizable monomers and / or oligomers is heated and / or the Solution contains a solvent that initiates a ring-opening or radical polymerization.

 Preferred is a process for ring-opening polymerization in which the substrate is heated with the mono- / oligomer solution.

 Preference is given to a process in which the space-spanning polymeric structural network is effected by a polycondensation of a thermal melt of the polymerizable monomers and / oligomers. Therefore, open-cell membranes are also available or obtained by the method just described.

In a preferred embodiment of the present invention, the process for producing an open-pored membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps:

 a) providing an open-porous carrier membrane with pores having a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein in step c) a polycondensation of a thermal melt of the polymerizable monomers and / or oligomers takes place.

In one embodiment, the polymerization is initiated by a start reaction initiated from the surface of the support materials. Preference is given to surfaces which have a functionalization with a starter for a free-radical or ring-opening polymerization. Further preferred are polymerizations which are carried out by means of a "grafting through" process In the grafting through process, two or more polymer compounds are bonded together, one of the compounds forming a longer-chain backbone and the other compounds being used in the reaction with this backbone In a further embodiment, a polymerization takes place in the form of a "grafting to" process. Initially, polymers are produced in suitable reaction mixtures. Preferably, the resulting polymers are subsequently purified and obtained in a specified form or with a defined molar mass by suitable separation techniques. These polymers are then with Surfaces or other polymers brought into contact and connected to these by means of a condensation, addition or substitution reaction.

Polymerization processes with which the nanocavity polymer structures according to the invention can be prepared include processes from the prior art, such as atom transfer radical polymerization (ATRP), ring-opening metathesis polymerization (ROMP), anionic or cationic polymerization, as well as free living radical polymerization, but also the radiation-induced polymerization, the ring-opening olefin metathesis polymerization, the reversible addition-fragmentation chain transfer polymerization, the nitroxide-mediated polymerization, polycondensation reactions and an inferior-induced polymerization.

 The reaction conditions required in the various processes for the preparation of nanocavity space-filling or space-spanning polymer structures can be very different. Preferred is a reaction time between 1 minute and 10 days, more preferably between 10 minutes and 3 days and more preferably between 15 minutes and 24 hours. Preferred is a reaction temperature between 0 ° and 270 ° C, more preferably between 10 ° and 180 ° C and more preferably between 20 ° and 130 ° C.

 Preference is given to a process in which, in step b), a solution containing reactive monooligomers is introduced into a spatially open porous carrier membrane and polymerization initiation in step c) results in the formation of polymer structures which form nanocavityy cleavage spaces. Preferably, an open-pore membrane is also available or obtained according to the method of the invention just described.

Preference is given to a process in which step c) takes place chemically, physico-chemically or physically by polymerization initiation. Preference is also given to obtaining an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid substance mixture or obtained by the process according to the invention which has just been described.

Preference is given to a process in which the polymerization is initiated in step c) by increasing the temperature. Preference is also given to obtaining an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid substance mixture or obtained by the process according to the invention which has just been described.

The room-spanning polymeric structural network may comprise at least one polymer such as polyvinylidene chloride, polyvinyl butyral, polyvinylpyridine, polycarbonates, polyamides, polyimides, polybenzimidazoles, polyethers, polystyrene, polydivinylbenzene, polyvinyltoluene, polyvinylbenzyl chloride, Polymethylmethacrylate, polyethylene, polypropylene, polyvinylacetate, polyacrylonitrile, polyacrolein, polybutadiene, polychlorobutadiene, polyisoprene, polyvinylchloride, polyvinylalcohol, polyacrylonitrile. Polyvinyl pyrrolidone, glycerin, polyhydroxyethyl methacrylates, polyethylene glycol, polypropylene glycol, polyvinyl alcohol polydioxanone, polycaprolactone, polygluconate, polylactic acid-polyethylene oxide copolymer, modified cellulose, poly (hydroxybutyrate), polyamino acids, poly-α-amino acids, poly-β-amino acids, homopoly-a Amino acids, homopoly-β-amino acids, polyphosphate esters, polyvalerolactones, poly-s-decalactones, polylactic acid, polyglycolic acid polylactides, preferably poly-L-lactide, poly D, L lactide, and copolymers and blends such as poly (L-lactide-co-poly) glycolide), poly (D, L-lactide-co-glycolide), poly (L-lactide-co-D, L-lactide), poly (L-lactide-co-trimethylene carbonate)], polyglycolides, copolymers of polylactides and Polyglycolides, poly-s-caprolactone, polyhydroxybutyric acid, polyhydroxybutyrates, polyhydroxyvalerates,

Polyhydroxybutyrate co-valerates, poly (1,4-dioxane-2,3-diones), poly (1,3-dioxan-2-ones), poly-para-dioxanones, polyanhydrides, polymaleic anhydrides,

Polyhydroxymethacrylates, fibrin, polycyanoacrylates,

Polycaprolactone dimethyl acrylates, poly-b-maleic acid polycaprolactone butyl acrylates, multiblock polymers of oligocaprolactone diols and oligodioxanonediols, polyetherester multiblock polymers of PEG and polybutylene terephthalate, polypivotolactones, polyglycolic acid trimethylcarbonates, polycaprolactone glycolides, poly (g-ethylglutamate), poly (DTH-lminocarbonate), poly (DTE-co-DT-carbonate) , Poly (bisphenol A-iminocarbonate), polyorthoesters, polyglycolic acid trimethylcarbonates, polytrimethylcarbonates, polyiminocarbonates, poly (N-vinyl) -pyrrolidone,

Polyvinyl alcohols, polyester amides, glycolated polyesters, polyphosphoesters, polyphosphazenes, poly [p-carboxyphenoxy) propane], polyhydroxypentanoic acid, polyanhydrides, polyethylene oxide-propylene oxide, polyether esters such as polyethylene oxide, polyalkene oxalates, polyorthoesters and their copolymers, lipids, waxes, oils, polyunsaturated fatty acids, eicosapentaenoic acid, Timnodonic acid, docosahexaenoic acid, arachidonic acid, linoleic acid, α-linolenic acid, γ-linolenic acid, carrageenans, fibrinogen, agar-agar, starch, collagen, protein-based polymers, polyamino acids, synthetic polyamino acids, zein, polyhydroxyalkanoates, pectinic acid, actinic acid, carboxymethylsulfate, albumin, hyaluronic acid, Chitosan and its derivatives, heparan sulfates and its derivatives, heparins, chondroitin sulfate, dextran, β-cyclodextrins, copolymers with PEG and polypropylene glycol, gum arabic, guar, gelatin, collagen, collagen N-hydroxysuccinimide, lipids, phospholipids, polyacrylic acid, polyacrylates, polyme methyl methacrylate, polybutyl methacrylate, polyacrylamide, polyacrylonitriles, polyamides, polyetheramides, polyethyleneamine, polyimides, polycarbonates, polycarbourethanes, polyvinyl ketones, polyvinyl halides, polyvinylidene halides, Polyvinyl ethers, polyisobutylenes, polyvinylaromatics, polyvinyl esters, polyvinylpyrollidones, polyoxymethylenes, polytetramethylene oxide, polyethylene, polypropylene, polytetrafluoroethylene, polyurethanes, polyetherurethanes, silicone-polyetherurethanes, silicone-polyurethanes, silicone-polycarbonate-urethanes, polyolefin elastomers, polyisobutylenes, fluorosilicones, carboxymethylchitosans, polyaryletheretherketones, Polyetheretherketones, polyethylene terephthalate, polyvalerates, carboxymethylcellulose, cellulose, rayon, rayontriacetates, cellulose nitrates, cellulose acetates, hydroxyethylcellulose, cellulose butyrates, cellulose acetate butyrates, ethylvinylacetate copolymers, polysulphones, epoxy resins, ABS resins, EPDM rubbers, silicones such as polysiloxanes, polydimethylsiloxanes, polyvinylhalogens, cellulose ethers, Cellulosetriacetate, shellac, poly-para-xylylenes (parylene) such as Parylene N, Parylene C and / or Parylene D, and copolymers of the aforementioned polymers. Particularly preferred are lipophilic polymers. Particularly preferred are lipophilic polymers having amide bonds, such as polyamino acids and preferably polyamino acids of the same amino acid monomer, such as polyisoleucine, polyphenylalanine, polyvaline.

The space-spanning polymeric structural network of the open-pore membranes according to the invention described hereinbefore preferably comprises or comprises the electrophoretic separation of carboxylic acids from a liquid mixture of polyvinyl polymers or polyamino acids.

A preferred embodiment of the invention is directed to an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the space-spanning polymeric structural network consists of vinyl polymers or polyamino acids, preferably lipophilic polyamino acids.

The space-spanning polymeric structural network of the open-pore membranes according to the invention described hereinbefore preferably comprises or comprises the electrophoretic separation of carboxylic acids from homopolyamino acids. A particularly preferred embodiment according to the invention is therefore directed to an open-pored membrane for the electrophoretic separation of carboxylic acids from a liquid mixture of substances comprising or consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the space-spanning polymeric structural network consists of homopoly-a-amino acids, preferably lipophilic homopoly-a-amino acids.

The term homopoly-a-amino acids refers to polymers of the same a-amino acid as e.g. Polyphenylalanine. The space-spanning polymeric structural network of the present invention open-celled membranes for the electrophoretic separation of carboxylic acids from a liquid mixture preferably comprises or consists of vinyl polymers selected from the group consisting of or consisting of polyvinyl chloride, polyvinylidene chloride, polyacrylic acid, polyacrylamide, polyvinyl butyral, polyvinylpyridine, polyvinylamine, polyvinyl ethers, polystyrene , Polydivinylbenzene, polyvinyltoluene, polyvinylbenzylchloride, polymethylmethacrylate, polyethylene, polypropylene, polyvinylacetate, polyacrylonitrile, polyacrolein, polybutadiene, polychlorobutadiene, polyisoprene, polyvinylalcohol, alkylated or acylated polyvinylalcohol.

A preferred embodiment of the invention is directed to an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the space-spanning polymeric structural network consists of vinyl polymers and the vinyl polymers are selected from the group consisting of or consisting of polyvinyl chloride, polyvinylidene chloride, polyacrylic acid, polyacrylamide, polyvinyl butyral, polyvinyl pyridine, polyvinylamines, polyvinyl ethers, polystyrene, polydivinylbenzene, polyvinyltoluene, polyvinylbenzylchloride, polymethylmethacrylate, polyethylene, polypropylene , Polyvinyl acetate, polyacrylonitrile, polyacrolein, Polybutadiene, polychlorobutadiene, polyisoprene, polyvinyl alcohol, alkylated or acylated polyvinyl alcohol.

In principle, all organic compound units known from the prior art, with which organic polymers can be prepared, can be used for the production of the open-pore nanocavitic space-filling or space-spanning polymer structures according to the invention. Examples of such organic compound units are ethylene, propylene, vinyl chloride, caprolactam, isoprene, 1,3-butadiene, 4-vinylbenzyl chloride (VBC) or ammonium salts thereof, carbonates, arylates, caprolactone, tetrafluoroethylene, oxazolines, imidazoles, carboxylic acid esters or ethers, 1 -thio-2,3-dihydroxypropyl thioether, 1-diglycerol ether, 1, 2 dihydroxy 3-thiopropyl-1-ether, 1-glycerol ether, 1-glycerol ether having a substituent at position 3, such as. B. 1, 3 glycerol.

 Furthermore, imides, aramids and aromatic amides (for example m- or p-phenyleneisophthalamide), paraphenylenes, terephthalamides, paraphenylenes / 3,4'-diphenyl ethers, terephthalamide and metaphenylene-isophthalamide, aminoalcohol, isocyanates, cyclocarbonate, triazines, melamine, vinyl alcohol , Vinyl acetate, vinyl butyral, acrylate with free hydroxyl groups, polyester, preferably PET, PBT, PTT, p-hydroxybenzoic acid, 2,6-hydroxynaphthoic acid, 2,5-Hydroxynahpthoesäure, 2,6-dihydroxynaphthalene, 2,6-naphthalenedicarboxylic acid, biphenol, bisphenol A, terephthalic acid, isophthalic acid and hydroquinones.

 Furthermore, aromatic polyamides, such as vinylpyrrolidone or mixed esters thereof, urethane, urea or biologically produced or degradable mono- or polymers, preferably from lactic acid, hydroxyalkanoate, hydroxybutyrate, hydroxyvalerate, cellulose or mixtures thereof or copolymers thereof.

 Various polymerization mechanisms can be selected for the preparation of the nanocavity polymer structures according to the invention. For this purpose, monomers containing free-radical, cationic or anionic centers to produce. Techniques for making reactive mono- / oligomers are known in the art. Halogens and halides, such as bromine or chloride, cyclic olefins, such as norbornenes and cyclopentenes, negatively charged vinyl groups, isocyanates, amines, aldehydes, ketones, carboxylic acids, epoxides, electron-rich aromatics, such as phenols, hydroxy compounds, such as phenols, are particularly useful as reactive centers or alcohols, Michael systems such as α, β-unsaturated esters, amides, nitriles, nitroolefins, carbonic acids and derivatives.

Particularly preferred is the use of monomers that are physiologically occurring and / or biodegradable. Particularly suitable amino acids and derivatives thereof are suitable for this purpose. These may be carbamic acid, alpha-, beta- or gamma-amino acids as well as L- or D-forms as well Mixtures of these. In particular, these are alanine, arginine, asparagine, aspartic acid, cysteine, glutamine, glutamic acid, glycine, histidine, isoleucine, leucine, lysine, methionine, phenylalanine, proline, serine, threonine, tryptophan, tyrosine, valine, and thyroxine, dopamine , 5-hydroxytryptophan, histamine. Further amino acid derivatives, such as. As tyrosine, cinnamic acid or 3- (4-hydroxyphenyl) propionic acid. Particularly preferred are phenylalanine, arginine and lysine. If monomers have reactive sites / side groups which may cause an undesirable reaction during the polymerization, these reactive groups should be passivated with protecting groups. Techniques for this are known from the prior art.

 In a further preferred procedure, protected amino acids are used, i. Reactive major or pendant groups are protected from reaction turnover by reversible saturation with a non-reactive compound. As protecting group for the functionality to be protected it is preferred to use fluorenylmethoxycarbonyl (Fmoc), tert-butyloxycarbonyl (Boc), benzyloxycarbonyl (Cbz, Z) or acetyl groups, more preferred are triphenylmethyl (Trt), benzyloxymethyl (Born), benzyl -, phenyl, dinitrophenyl (Dnp), toluenesulfony-1 (Tos), mesitylenesulfonyl (Mts), acetamidomethyl (Acm), tert-Butylmercaptogruppen (tBum) used. Methods are known in the prior art with which the protective groups can be removed again following polymerization.

It is therefore further particularly preferred if the space-spanning polymeric structural network of the open-cell membranes of the invention described herein comprise or comprise electrophoretic separation of carboxylic acids from polyamino acids, and wherein the polyamino acids consist of amino acid monomer units selected from the group consisting of or consisting of proteinogens Amino acids and their derivatives, in particular their lipophilic derivatives such as alkylated or acylated derivatives or derivatives with lipophilic protective groups.

 A particularly preferred embodiment of the invention is thus directed to an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

II) a space-spanning polymeric structure network in the pores of the support membrane, wherein the space-spanning polymeric structural network consists of or comprises polyamino acids, and wherein the polyamino acids consist of amino acid monomer units selected from the group consisting of or consisting of proteinogenic amino acids and their derivatives. Preferably selected from proteinogenic amino acids or as derivatives alkylated proteinogen amino acids, acylated proteinogenic amino acids or proteinogenic amino acids with protective groups, in particular lipophilic protective groups.

Proteinogenic amino acids include alanine, arginine, asparagine, aspartic acid, cysteine, glutamine, glutamic acid, glycine, histidine, isoleucine, leucine, lysine, methionine, phenylalanine, proline, serine, threonine, thryptophan, tyrosine and valine. The functional group of the respective proteinogenic amino acid, which is present in addition to the α-aminocarboxylic acid unit, is preferably functionalized by a further lipophilic group. The α-amino unit can also be monoalkylated. There is also the possibility that the proteinogenic amino acid in the carbon chain or the carbon ring carries additional functionalities.

The open-pore membranes according to the invention for the electrophoretic separation of carboxylic acids from a liquid mixture whose space-spanning polymeric structural network consists of poly-a-amino acids and preferably homopoly-a-amino acids described herein are the monomer units of poly-a-amino acids selected from the group comprising or consisting of alanine, phenylalanine, valine, isoleucine, leucine, proline, Νω-functionalized arginine, O-functionalized serine, asparagine functionalized on the ß-amide moiety, aspartic acid functionalized on the ß-carbonyl moiety, glutamic acid functionalized on the γ-carbonyl moiety, glutamine functionalized functionalized on the γ-carbonyl moiety, histidine functionalized on the imidazole moiety, O-functionalized threonine, thryptophan functionalized on the indole moiety, S-functionalized cysteine, or ε-Ν-functionalized lysine. More preferably, the monomer units of the polyamino acids are selected from the group consisting of or consisting of alanine, phenylalanine, valine, isoleucine, leucine, proline, Νω, Ν'ω-dialkyl-arginine, Νω, Νω-dialkyl-arginine, Νω-alkyl-arginine , Νω-carbamate-functionalized-arginine, Νω-carbamate-functionalized, Ν'ω-alkyl-arginine, Νω-acyl-arginine, Νω-alkyl, Ν'-acyl-arginine, Νω-alkylsulfonyl-arginine, Νω-alkylsulfonyl , Ω-alkyl-arginine, β-amide-alkylated asparagine, aspartic acid-β-alkylester, -glutamic acid-y-alkylester, γ-amide-alkylated glutamine, imidazole-alkylated histidine, O-alkyl-serine, O-acyl-serine, O-alkyl-threonine, O-acyl-threonine, indole-alkylated thryptophan, O-alkyl-tyrosine, S-alkyl-cysteine, ε-Alkyl-alkyl-lysine, ε-Ν, Ν-dialkyl-lysine, ε-Ν Acyl-lysine, ε-Ν-alkyl, ε-Ac-acyl-lysine, ε-Ν-carbamoyl-lysine, ε-Ν-carbamoyl, ε-Ν-alkyl-lysine, ε-Ν-carbamoyl-lysine, ε-Ν-carbamate-functionalized lysine, sN-alkyl, sN-carbanate-functionalized lysine, ε-Alkyl-alkylsulfonyl-lysine, ε-Alkyl-alkylsulfonyl, ε-Ν-alkyl-lysine. In this context, the term "alkyl" or alkylated also means aryl or alkylaryl compounds, Preferably an "alkyl" radical comprises 1 to 10 carbon atoms (C 1 -C 10 -alkyl). Preferably, an "acyl" group comprises 1 to 10 carbon atoms (Ci-Cio-acyl). Preferably, an "aryl" group comprises from 6 to 14 carbon atoms (C6-Ci ₄ aryl). Preferably, an "alkylaryl" radical comprises 7 to 15 carbon atoms (C ₇ -C ₅ -alkylaryl). The simplest alkylaryl radical is benzyl (-CH ₂ Ph).

Thus, the following radicals are preferred: alanine, phenylalanine, valine, isoleucine, leucine, proline, Νω, Ν'ω-di-Ci-Cio-alkyl-arginine, Νω, Νω-di-Ci-Cio-alkyl-arginine, Νω- Ci-Cio-alkyl-arginine, Νω-carbamate-functionalized-arginine, Νω-carbamate-functionalized, Ν'ω-Ci-Cio-alkyl-arginine, Νω-Ci-Cio-acyl-arginine, Νω-Ci-Cio Alkyl, Ν'ω-Ci-Cio-acyl-arginine, Νω-Ci-Cio-alkylsulfonyl-arginine, Νω-Ci-Cio-alkylsulfonyl, N ^* -Ci-Cio-alkyl-arginine, ß-amide-Ci-Cio -alkylated asparagine, aspartic acid-β-Ci-Cio-alkyl ester, glutamic acid-y-Ci-Cio-alkyl ester, v-amide-Ci-Cio-alkylated glutamine, imidazol-Ci-Cio-alkylated histidine, O-Ci-Cio Alkyl-serine, O-Ci-Cio-acyl-serine, O-Ci-Cio-alkyl-threonine, O-Ci-Cio-acyl-threonine, indol-Ci-Cio-alkylated Thryptophan, O-Ci-Cio-alkyl -Hyrosine, S-Ci-Cio-alkyl-cysteine, ε-Ν-Ci-Cio-alkyl-lysine, ε-Ν, Ν-di-Ci-Cio-alkyl-lysine, ε-Ν-Ci-Cio-acyl -Lysine, ε-Ν-Ci-Cio-alkyl, ε-Ν-Ci-Cio-acyl-lysine, ε-Ν-carbamoyl-lysine, ε-Ν-carbamoyl, -Ν-Ci-Cio-alkyl-lysine, ε-Ν-carbamoyl-lysine, ε-Ν-carbamate-functionalized lysine, ε-N-C1-C1o-alkyl, ε-N-carbamate-functionalized lysine, ε-Ν -Ci-Cio-alkylsulfonyl-lysine, ε-Ν-Ci-Cio-alkylsulfonyl, ε-Ν-Ci-Cio-alkyl-lysine.

Even more preferably, the amino acids are selected from the group consisting of or consisting of phenylalanine, valine, isoleucine, leucine, proline, ω, ω'-dialkyl-arginine, ω, ω-dialkyl-arginine, ω-alkyl-arginine, ω-carbamate - functionalized-arginine, N-carbamate-functionalized, N'-alkyl-arginine, Νω-acyl-arginine, Νω-alkyl, Ν'ω-acyl-arginine, Νω-alkylsulfonyl-arginine, Νω-alkylsulfonyl, N ^* -alkyl -Arginine, y-alkyl glutamate, ε-Ν-alkyl-lysine, ε-Ν, Ν-dialkyl-lysine, ε-Ν-acyl-lysine, ε-Ν-Α ^ Ι-ε-Ν-ΑΰγΙ-γγείη , ε-Ν-carbamoyl-lysine, ε-Ν-θΒ, ηηογΙ-ε-Ν-ΑΑΙ-γγείη, ε-N-carbamoyl-ε-N-acyl-lysine, ε-Ν-carbamate-functionalized lysine, ε-N-alkyl, ε-N-carbamate-functionalized lysine, ε-Ν-alkylsulfonyl-lysine, ε-Ν-Α ^ ΙευΙίοηγΙ, ε-Ν-Α ^ Ι-ε-Ν-Α ^ ΙευΙίοηγΙ-γγείη. Most preferably, the amino acids are selected from the group comprising or consisting of phenylalanine, Νω-Boc-arginine, Νω-Cbz-arginine, Νω-Fmoc-arginine glutamic acid-Y-benzyl ester.

Therefore, another particularly preferred embodiment of the underlying invention is an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the space-spanning polymeric structural network consists of or comprises polyamino acids, and wherein the polyamino acids consist of amino acid monomer units, alanine, phenylalanine, valine, isoleucine, leucine, proline, ω-functionalized arginine, O-functionalized serine, asparagine functionalized on the β-amide moiety , Aspartic acid functionalizes at the β-carbonyl moiety, glutamic acid functionalizes at the γ-carbonyl unit, glutamine functionalizes at the γ-carbonyl unit, histidine functionalizes at the imidazole unit, O-functionalized threonine, thryptophan functionalizes at the indole unit, S-functionalized cysteine or ε-Ν -functionalized lysine. More preferably, the monomer units of the polyamino acids are selected from the group consisting of or consisting of alanine, phenylalanine, valine, isoleucine, leucine, proline, Νω, Ν'ω-dialkyl-arginine, Νω, Νω-dialkyl-arginine, Νω-alkyl-arginine , Νω-carbamate-functionalized-arginine, N-carbamate-functionalized, N'-alkyl-arginine, Νω-acyl-arginine, Νω-alkyl, Ν'-acyl-arginine, Νω-alkylsulfonyl-arginine, Νω-alkylsulfonyl, Ω-alkyl-arginine, β-amide-alkylated asparagine, aspartic acid-β-alkyl ester, glutamic acid-Y-alkyl ester, γ-amide-alkylated glutamine, imidazole-alkylated histidine, O-alkyl-serine, O-acyl-serine, O -Alkyl-threonine, O-acyl-threonine, indole-alkylated thryptophan, O-alkyl-tyrosine, S-alkyl-cysteine, ε-Ν-alkyl-lysine, ε-Ν, Ν-dialkyl-lysine, ε-Ν- Acyl-lysine, ε-Ν-alkyl, ε-Ac-acyl-lysine, ε-Ν-carbamoyl-lysine, ε-Ν-carbamoyl, ε-N-alkyl-lysine, ε-Ν-carbamoyl-lysine, ε- Ν-carbamate-functionalized lysine, ε-Ν-alkyne-N-carbamate functionality lyzed lysine, ε-Ν-alkylsulfonyl-lysine, ε-Ν-alkylsulfonyl and ε-Ν-alkyl-lysine.

Therefore, a particular preferred embodiment of the present invention is a process for the preparation of an open-celled membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps: a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerizable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerization of the polymerizable monomers or oligomers in the pores of the open-pore carrier membrane to form a space-spanning polymeric structural network in the pores of the open-pore carrier membrane,

wherein the polymerizable monomers or the units of the polymerizable oligomers are selected from the group consisting of or consisting of alanine, phenylalanine, valine, isoleucine, leucine, proline, Νω-functionalized arginine, O-functionalized serine, asparagine functionalized on the β-amide unit, Aspartic acid functionalized on the β-carbonyl moiety, glutamic acid functionalized on the γ-carbonyl unit, glutamine functionalized on the γ-carbonyl unit, histidine functionalized on the imidazole moiety, O-functionalized threonine, thryptophan functionalized on the indole moiety, S-functionalized cysteine or ε-Ν- functionalized lysine. More preferably, the monomer units of the polyamino acids are selected from the group consisting of or consisting of phenylalanine, valine, isoleucine, leucine, proline, Νω, Ν'-dialkyl-arginine, Νω, Νω-dialkyl-arginine, Νω-alkyl-arginine, Νω Carbamate-functionalized arginine, N-carbamate-functionalized, N'-alkyl-arginine, Νω-acyl-arginine, Νω-alkyl, Ν'ω-acyl-arginine, Νω-alkylsulfonyl-arginine, Νω-alkylsulfonyl, ΝΡω- Alkyl arginine, β-amide alkylated asparagine, aspartic acid β-alkyl ester, γ-alkyl glutamate, γ-amide-alkylated glutamine, imidazole-alkylated histidine, O-alkyl-serine, O-acyl-serine, O-alkyl -Threonin, O-acyl-threonine, indole-alkylated thryptophan, O-alkyl-tyrosine, S-alkyl-cysteine, ε-Ν-alkyl-lysine, ε-Ν, Ν-dialkyl-lysine, ε-Ν-acyl- Lysine, ε-Ν-alkyl, ε-Ac-acyl-lysine, ε-Ν-carbamoyl-lysine, ε-Ν-carbamoyl, ε-Ν-alkyl-lysine, ε-N-carbamoyl-lysine, ε-Ν- Carbamate-functionalized lysine, ε-Ν-Α ^ νΙ, ε-Ν-03 ^) 3ηη3ί- fu functionalized lysine, ε-Ν-alkylsulfonyl-lysine, ε-Ν-alkylsulfonyl, ε-Ν-alkyl-lysine and derivatives thereof. Likewise particularly preferably, an open-pored membrane is obtainable or obtained by the process just mentioned. Particularly preferred are monomers of α-amino acid N-carboxyanhydrides. Particularly preferred is phenylalanine NCA as a reactive monomer. Further preferred are di-, tri- or polypeptides having at least one reactive group which allows polymerization. Also referred to herein as "reactive monomers" are di-, tri- or oligomers, as well as copolymers or block polymers which have one or more reactive groups which enable or permit polymerization with other reactive monomers Copolymers, such as styrene.

The polymerization reactions of the invention can be prepared with reactive monomers or alone or together from / with reactive oligomers. By oligomer is meant herein a molecule consisting of 2, 3 or more like or similar molecular moieties covalently bonded together. The oligomers of the invention preferably have up to 500 subunits, more preferably up to 250, and more preferably up to 100 subunits. The molecular subunits of the oligomers of the invention preferably consist of the same compounds as the reactive monomers described herein. Especially preferred are polypeptides consisting of 2, 3 or more identical or different amino acids linearly linked in the form of a chain or in cyclic formation and also falling within the term oligomer as used herein. The reactive oligomers have one or more reactive centers which allow a nucleophilic or free-radical reaction, preferably these consist of one or more of the compounds listed herein. As such, the reactive oligomers can be polymerized by the same methods as the reactive monomers.

Surprisingly, there was no reduction in the transport of carboxylic acids in electrodialysis, even when the application time was longer (> 200 h), when proteins or phospholipids were present in the donor medium. Therefore, the membranes according to the invention are also resistant to fouling by compounds which, due to their physico-chemical properties and their dimensions, can enter and prove the membranes according to the invention.

 Preference is given to a process for producing membranes, by which fouling of the membranes by organic compounds is prevented. Therefore, an open cell membrane for electrophoretic separation of carboxylic acids which prevents fouling of the membranes by organic compounds is preferred.

Another very advantageous effect, which is accomplished with the membranes according to the invention, is a very good biocompatibility. Thus, it could be shown that contact with biological fluids only leads to a small to barely measurable adhesion of biomolecules. In particular, no attachment of living cells was observed. This also leads to an inhibition of otherwise common fouling processes that in separation membranes that are used in biological fluids occur. The anti-fouling effect is assisted by separating the carboxylic acids without pressurizing the donor medium.

The surfaces of the membranes of the invention also have a very good biocompatibility and hemocompatibility. In particular, for membranes prepared according to the invention with solutions containing polyphenylalanine monomers by any of the methods disclosed herein, there was no adhesion of blood proteins or blood cells over 6 hours. Therefore, the membranes of the invention are also bio- or hemocompatible. Preference is given to an open-pore membrane having a spatially stretching polymeric structural network or its preparation, wherein the subunits of the raumduchspannenden polymeric structural network preferably to> 25% by weight, more preferably> 50% by weight, more preferably> 75% by weight and particularly preferably> 90% by weight Biomono- / oligomers are constructed. Preference is given to an open-pore membrane having a spatially tension-spanning polymeric structural network or its preparation, the subunits preferably being> 25% by weight, more preferably> 50% by weight, more preferably> 75% by weight and particularly preferably> 90% by weight of phenylalanine and / or phenylalanine derivatives are constructed.

Preferred is a process for the production of bio- and hemocompatible membranes.

 In a further preferred embodiment of the present invention, the process for producing an open-pore biocompatible and hemocompatible membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerization of the polymerizable monomers or oligomers in the pores of the open-pore carrier membrane to form a space-spanning polymeric structure network in the pores of the open-pore carrier membrane.

Therefore, an open cell membrane for electrophoretic separation of carboxylic acids, which are bio- and hemocompatible, is preferred. Another preferred embodiment of the present invention is an open-pore biocompatible and hemocompatible membrane for the electrophoretic separation of carboxylic acids from a liquid mixture consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structural network in the pores of the support membrane. In a further preferred embodiment of the present invention, the process for producing an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprises the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the mono- and / or oligomer solution contains biomonomers and / or biooligomers.

A particularly advantageous effect, which results in particular from the coating according to the invention of a support membrane with amino acid polymers, is their resistance to organic solvents. Thus, membranes which were polymerized with polyphenylalanine or benzylglutamate monomers by a process of the present invention had no structural changes by electron microscopy when placed in THF or hexane for 3 weeks.

 Preferred is a process for the preparation of solvent resistant membranes.

In a process embodiment, the mono- and / or oligomeric compounds used to make the nanocavity polymer structures may have pendant functional groups. The functional side groups may be polar or apolar and / or reactive and / or ionic compounds contain. Examples of apolar groups are aliphatic or cyclic hydrocarbons. Examples of polar side groups are alcohols or carboxylic acids. Examples of reactive side groups are amines, thiols, olefins, alkynes, aldehydes. Preferably, these pendant functional groups are protected by protecting groups known in the art during the polymerization reaction. Preferably, the protecting groups are cleaved off after the polymerization reaction and removed from the membrane by suitable means.

 Following polymerization, the membranes are liberated from residual residues of monomers and / or catalysts and / or by-products by flushing the membranes with a suitable sequence of solvents.

 Preference is given to a process in which residues of monomers and / or catalysts and / or by-products present in stage d) are removed from the membrane.

In a very particularly preferred embodiment, the polymers according to the invention which form nanocavity polymer networks are biopolymers. These include physiological compounds such as amino acids, carboxylic acids, polysaccharides, nucleic acids, polyphenols, phenylpropane derivatives, saccharides, and their derivatives. Particularly preferred are phenylalanine, lysine, arginine and benzylglutamate. Preferred carboxylic acids are stearic acid, oleic acid, linoleic acid and linolenic acid.

 Preference is given to a process for the preparation of nanocavity polymer structures by means of biopolymers.

 Preferred is a process for the preparation of nanocavitären polymer structures of polyphenylalanine.

A preferred embodiment of the present invention relates to methods for surface functionalization of the nanocavity polymer structures with compounds that are bifunctional lipophilic and cationic. This means that the coating consists of amphiphilic molecules having a positively charged group and having a lipophilic moiety, such as a longer alkyl moiety. Suitable molecules for surface functionalization are therefore in particular tetraalkylammonium compounds or alkylated imidazole compounds having at least one alkyl radical or a longer carbon chain, which may also contain aromatics or double bonds or heteroatoms, and the positively charged nitrogen atom, so that lipophilic and cationic properties are present in one molecule. Preferred compounds are Tetradecyltrimethylammonium oxalate, Denatoniumbenzoat or tetramethyl-2-methylene-1 H-imidazole. An alternative is to use two different molecules, one having the cationic properties and the other the lipophilic properties, such as ammonium polyols or a trimethylpropylammonium group having cationic properties and a dodecyl moiety having the lipophilic properties.

Preference is given to a process in which the surface functionalization of the polymer structures, obtainable from stage c), with amphiphilic compounds takes place in stage d2).

Process for the preparation of an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-porous carrier membrane with pores having a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

 d2) functionalizing the surface of the space-spanning polymeric structural network from step c) with at least one amphiphilic one

Connection.

In a particularly preferred embodiment, the polymerization of mono- / oligomers takes place in a space-providing supporting fabric. The supporting tissue is preferably an open-pored carrier membrane. "Spontaneous" in this context means that the open-pore carrier membrane is porous and open-pored and that the pores, channels or slots have a diameter between 10nm to 500 μιτι, preferably between 20nm to 500μηη, more preferably between 30nm to 500 μιτι, more preferably between 50nm up to 500 μm, more preferably between 10 nm to 300 μm, more preferably between 30 to 300 μm, more preferably between 40 nm to 300 μm, more preferably between 50 nm to 300 μm, more preferably between 100 nm and 10 μm and most preferably between 200 nm and 5μηη have. Consequently, the space-giving open-pore carrier membrane has a large specific surface or large inner surface, the space limiting and shaping is for the nanocavitären polymer structures, which abut the inner surfaces, or with which they are connected. Ie. the space-giving open-pore carrier membrane has open cavities in the form of open, continuous pores, channels or slots and is therefore not only able to absorb substances and molecules into its open cavities, but also viscous solutions with a solids concentration of 1 mmol / L to 3 mol / L. The open-pore carrier membrane is also characterized by the fact that it has a high mechanical stability. The open cavities remain stable in external pressure effects in shape and in particular do not coincide. Particularly suitable for this are free-carrying membranes, fabrics or textures and porous materials that are present in a composite structure. Suitable open cell backing fabrics for coating can be any durable membranes, fabrics or materials having a preferred open porosity of> 15%, more preferably> 25%, more preferably> 50%, even more preferably> 70% and most preferably> 80%. Suitable materials are both organic and inorganic materials, provided they are resistant to the solvent used for the solution of monomers and aqueous media with which they are brought into contact in an application. Suitable organic materials include natural and synthetic polymers, in particular cellulose and cellulose derivatives, for example cellulose acetates, melamines, polyethylene, polypropylene, PMMA, polycarbonate, polyurethane, Nafion, polyethylene, terephthalate (PET) or polysulfones.

Polymeric materials may be in the form of fibers, fabrics or foams, and may form a structural network in any arrangement. Particularly preferred are hollow chamber fibers. Furthermore, polymer membranes are suitable, which were first prepared as a closed film and then perforated mechanically or chemically. Insofar, "nuclear track membranes" are also suitable in which, after an electron bombardment, channels which pass through the membrane are produced by chemical etching along the polymer dressing dissolved by the electron bombardment Furthermore, films of polymers which are porous by means of multidimensional warping are suitable Particularly suitable for this purpose is PTFE and also suitable are films made of block copolymers in which polymer components are dissolved by physical or chemical methods after production, whereby the films become porous which may also already contain chemical bonding groups, so that a surface functionalization for the inventive production of space-filling or space-spanning polymers is no longer required. In one embodiment, the nanoscale polymer structures are prepared by applying films or strips to the monomer solution and stacking them in multiple layers. The films serve as support framework, the composite can be sliced after the polymerization. In this case, the transport of carboxylic acids is not carried out by the carrier film, but along this through the space-filling or space-spanning polymer structures. With such a composite of stacked films, which enclose nanocavity polymer layers, different geometries of a separation medium can be produced. So rings or tubes can be made by cutting. On the other hand, strips can be produced which are superimposed and joined together to form a solid composite. In another embodiment, it may be advantageous to apply a carrier material on one or both sides with the monomer solution and after preparation of a polymer layer with nanoscale polymer structures with similarly prepared carriers in layers or cut them and cut into spatial formations such. As a disc, merge. In a particularly preferred embodiment, the carrier material consists of carbon fibers. These have the advantage of a high chemical and thermal resistance and a very good mechanical strength. Carbon fibers can be made in thin strips or fibers and can be z. B. process into tissues.

 Suitable inorganic materials preferably include ceramic or metallic materials such as, for example, alumina, aluminum, titanium oxide, titanium, tantalum, zirconium, zirconium oxide, zeolites or glass. Suitable ceramic membranes can be produced from a pressing or sintering of particles, which are then thermally treated, whereby a stable composite is formed. It may be necessary to use organic or inorganic additives which are physically or chemically wholly or partly discharged or degraded after or during the production of the membrane. Ceramic membranes can also be obtained by a melt of particles. This method is particularly suitable for silicon compounds. On the other hand, fiber textures can also be produced from inorganic materials. These can be put together to fabric associations, z. B. as a glass fiber fabric.

The voids of suitable porous materials may have any configuration as long as they are interconnected in plurality and allow the passage of a liquid medium through the material. The gap dimensions are preferably for minimum diameters between 10nm to Ι ΟΟμηη, more preferably between 100nm and 10μηη and more preferably between 200nm and 1 μηη. Preferably, maximum diameters of the gaps are between 1 μm and 3 mm, more preferably between 10 μm and 1 mm in diameter, and more preferably between 10 μm and μm. The length of the connections between the two outer sides is preferably between 5μηη and 10mm, more preferably between 50μηη and 3mm and more preferably between Ι ΟΟμιτι and 1 mm. The structure or structure of the space-giving supporting tissue, resp. the open-pore carrier membrane, is arbitrary. It may be a layered structure of fibers or fabrics or consist of a sintered material or of a cast or compressed continuously or discontinuously related material.

 The thickness of the carrier material, resp. the open-pore carrier membrane is preferably between 5μηη and 10mm, more preferably between 50μηη and 3mm and more preferably between Ι ΟΟμιτι and 1 mm. The outer shape of the space-giving support structure can have any desired geometry, preferably a flat design and a tubular shape. In a particularly preferred embodiment, the space-giving open-pore carrier membrane is a hollow fiber capillary.

 Preferred is a method in which the space-giving open-pore carrier membrane of step a) consists of a porous, free-carrying membrane, fabrics or textures and porous materials which are present in a composite structure. Preferred is a method in which the space-giving open-pore carrier membrane of stage a) consists of inorganic and / or organic compounds.

Preference is given to a method in which the space-giving open-pore carrier membrane of stage a) has the form of planar membranes, tubes or hollow-chamber capillaries.

Open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the open-celled support membrane consists of a porous, free-carrying membrane, a woven fabric or textures, or porous materials that are in a composite structure.

In order to obtain an extremely advantageous substance separation by the membrane production according to the invention, it is preferred that the nanocavitates Polymer structures are space-filling or space-spanning as well as a full-surface composite with the inner surfaces of the spatial structure fabric is achieved. Therefore, it is advantageous to achieve a full-surface occupancy / binding of the inner space-defining boundary surfaces of the open-pore carrier membrane with the polymer structures according to the invention. Unless reaction-forming groups are already present on the spatial support structure, these can be applied to the inner surfaces of the support material using techniques known in the art. Suitable compounds which should be available on the surface for high-density reaction formation have functional groups, such as. As amines, epoxides, thiols, alkyl halides or carboxyl groups. Further, other reactive groups can be used, such as cyanates, thiocyanates, alkenes, azides or activated carboxylic acids. For coating, the surfaces of the open-pore carrier membrane are to be prepared with suitable measures from the prior art. The binding can be chemosorptive or physiosorptive. Preferred compounds with which a full-surface covering of the surfaces of the open-pore carrier membrane can be effected by means of a covalent bond are, for example, aminosilanes, such as (3-aminopropyl) triethoxysilane (APTS) or and (3-trimethoxysilylpropyl) diethylenetriamine (TAPTES). Examples of compounds with which a physiosorptive coating of the surfaces is possible, for example, dopamine, polyethyleneimine, polyvinylamine, polyvinylimidazole, polyvinylpyridine, polyvinylpyrrolidone, polylysine or polyacrylic acid.

 In a particularly advantageous embodiment of the process takes place in the optional stage a1), a pretreatment of the surfaces of the space-defining open-pore carrier membrane with a full-surface coating with compounds that allows or requires a reaction with the monomer solution in step b). Preference is given to a process in which the space-giving open-pore carrier membrane of stage a) is subjected to a surface treatment in stage a1).

Preference is given to a process in which the surface treatment in step a1) is carried out with a starter for free-radical or nucleophilic polymerization.

After the formation of the nanocavityer polymer structure, residues of solvent and / or by-products of the reaction may remain in the open-celled membrane produced according to the invention. These residues can be removed from the membrane in a separate cleaning step, eg by rinsing or washing. It may be necessary to clean the membranes with various solvents and in a sequential sequence, preferred are methanol, H2O2 or THF. Furthermore, it may be necessary residues of Solvents, including, for example, the insertion in a vacuum drying cabinet or heating are suitable methods.

Thus, in a preferred embodiment of the present invention, the process for preparing an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

 d) purifying the membrane from step c) of solvents and / or reaction by-products.

The membranes according to the invention are distinguished in particular by different physical properties. These include, in particular, that they are permeable to gases and carboxylic acids.

 The membranes according to the invention are further characterized by measurable surface properties, such as, for example, a lipophilicity, or a hydrophobicity, or a charge carrier density, which are indicated by the determination of the contact angles for water or a carboxylic acid. The measurement method aims at the wettability of surfaces, measuring the angle between a drop of liquid on a surface and the solid surface.

The membranes according to the invention exhibited water contact angles of preferably> 70 °, more preferably of> 100 ° and more preferably of> 120 °, both on the outer surfaces and on the surfaces of breaklines. The membranes of the invention further preferably had contact angles for oleic acid on outer and inner surfaces, which are preferably <30 °, more preferably <20 ° and more preferably <10 °. Further preferred is a method according to the invention described herein, wherein the functionalized or coated surfaces of the pores, channels or slots have a contact angle for water of> 70 °, preferably> 100 °, particularly preferably> 120 ° and a contact angle for the carboxylic acid to be separated of <30 ° have. Likewise preferred is an open-cell membrane according to the invention for the electrophoretic separation of carboxylic acids from a liquid mixture described herein, characterized in that the contact angle for water on the surface of the inner pores, channels or slits of the open-pore membrane is> 70 °.

A preferred embodiment of the invention therefore relates to an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

characterized in that the contact angle for water on the surface of the inner pores, channels or slots of the open-pore membrane is> 70 °.

Preference is furthermore given to an open-pored membrane according to the invention for the electrophoretic separation of carboxylic acids from a liquid mixture, the membrane being lipophilic and / or the space-spanning polymeric structural network being lipophilic.

A preferred embodiment of the invention therefore relates to an open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture comprising or consisting of:

 I) an open-pore carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm,

 II) a space-spanning polymeric structure network in the pores of the support membrane,

wherein the membrane is lipophilic and / or the space-spanning polymeric structural network is lipophilic.

In one embodiment, the membranes of the invention are characterized in that they absorb carboxylic acids against a hydrostatic gradient. This gradient is preferably> 10 mm H ₂ O, more preferably> 30 mm H ₂ O and more preferably> 60 mm H ₂ O. This can be determined by adding to closed and completely filled with a carboxylic acid container with a membrane lying therein, a corresponding negative pressure is applied.

In a particularly preferred embodiment, the membranes of the invention are resistant to most organic solvents. Preference is given to a resistance to toluene, ethanol, methanol, xylene, acetonitrile, THF, dimethylformamide, acetone, methyl ester, ethyl ester, propylene carbonate, NMP, DMSO, dichloromethane, chloroform, dichloroethane, perchlorethylene, trichlorethylene, carbon tetrachloride, chlorobenzene, benzyl alcohol, glycols, glycol ethers , Isopropyl acetate, butanone, methyl isobutyl ketone, methoxypropyl acetate, butyl acetate, tetrahydrofuran, diethyl ether, diisopropyl ether, MTBE, butanol, isopropanol, trifluoroethanol, hexafluoroisopropanol. Resistant means that they do not decompose in the solvents.

 Preferred is a process for the preparation of membranes with nanocavity polymer structures that are resistant to organic solvents.

In a further particularly preferred embodiment, the membrane according to the invention has a high biocompatibility. High compatibility is ensured in particular by a low activation of the coagulation and complement system occurs upon contact with the membrane of the invention. Another aspect of high biocompatibility is due to low adsorption of proteins and living cells.

 Preferred is a process for the preparation of membranes with nanocavity polymer structures that are biocompatible.

Methods for the continuous separation of deprotonated carboxylic acids present in aqueous media are not known. With the membranes according to the invention such a continuous separation of carboxylic acids is possible. In this case, a selectivity for the separation of dissolved in aqueous emulsions carboxylic acids over similar organic compounds that have no carboxyl group can be achieved.

 So z. For example, it can be shown that a selectivity for fatty acids to fatty alcohols or fatty sulfates having an equal number of carbon atoms, with a selectivity index CIOH based on fatty alcohols of 400-800 and a selectivity index αι based on fatty sulfates of 160, when using an aqueous Medium (Example 3).

With the membranes of the invention also a selectivity to other organic compounds having negative charge groups is found. Proteins usually have one under physiological conditions negative surface charge and can be transported electrophoretically. With uncoated porous membranes, the achievable transport amount of carboxylic acids and proteins through the membrane is proportional to each other. In diffusion and electrodialysis, which were carried out with the membranes of the invention, there was virtually no transport of proteins through the membrane, whereas compared to uncoated membranes, the transport rate for carboxylic acids was increased (Example 3). But also small anionic compounds were retained, such as chloride and sulfate ions. Thus, the membranes according to the invention ensure a high selectivity for the separation of carboxylic acids from aqueous media or aqueous mixtures of substances.

 Preference is given to a process for producing membranes with nanocavitären polymer structures, with which a mass transfer of anionic hydrophilic compounds is prevented. In a further embodiment of the present invention, it has proved to be particularly advantageous that a solubilization of carboxylic acids is carried out prior to the separation of the carboxylic and / or fatty acids. Effective solubilization techniques of carboxylic and / or fatty acids are described in the literature. Particularly suitable for their solution in aqueous media are alkali formers, such as NaOH, cationic water-soluble compounds, such as guadinine or amidine-bearing compounds or quaternary ammonium compounds.

Examples of solutions or emulsions containing carboxylic acids which can be separated include industrial oils, vegetable oils, dairy products, phospholipid and glycolipid purification fluids, fuel purification, biodiesel production, biomass separation, biotechnological process fluids, blood, blood plasma, process fluids, effluents , pharmaceutical synthesis mixtures and liquids of chemical analysis and wastewater. Since the separation membranes according to the invention are not based on the principle of a molecular size selection and the effective channel diameters are usually much larger than the molecules of the substance mixture to be scavenged, it is preferable to apply no or only a small transmembrane pressure gradient. To achieve this, it may be necessary to monitor the pressure at the donor and acceptor side and to provide pressure equalization. A preferred embodiment of the membranes of the invention relates to a separation process in which no elevated pressure is applied to the liquid mixture containing at least one carboxylic acid for the passage of the at least one carboxylic acid through the membrane. In one embodiment, a hydrostatic pressure is applied to the donor chamber. This is particularly advantageous to counteract any existing EOF.

 The transport of carboxylic acids through the membranes according to the invention is carried out by a diffusion due to a concentration gradient or a thermal gradient and / or electro-kinetically by an electrical gradient. An electrical gradient is preferably produced by the application of a DC voltage between the donor and acceptor sides. In this case, a voltage of between 1 μV and 500V, more preferably between 100mV and 100V, and more preferably between 1V and 50V is preferred. A current strength between 0.01 mA and 5 A, more preferably between 0.1 mA and 0, is preferred. 5A and more preferably between 1 mA and 0.5A.

 A preferred method for carrying out the diffusion dialysis are cross-flow methods, using a suitable acceptor medium, in which a recording of the carboxylic acids to be separated can take place.

 A particularly preferred embodiment relates to a method according to the invention, wherein an electrochemical gradient is applied from the inlet side to the outlet side of the membrane for separating the at least one carboxylic acid.

The invention therefore also relates to a process for the continuous separation of carboxylic acids from liquid mixtures, comprising the steps:

 (i) providing a liquid mixture containing at least one carboxylic acid,

 (ii) contacting the liquid mixture containing at least one carboxylic acid with an open-pore membrane having space-filling or space-spanning nanocavitating polymer structures,

 (ii) separating the at least one carboxylic acid from the liquid mixture by selective passage of the at least one carboxylic acid through the open-cell membrane with space-filling or space-spanning nanocavity polymer structures,

 wherein the separation has a selectivity index of> 4 over the alcohol obtainable by reduction of the corresponding carboxylic acid.

Another aspect of the invention relates to methods that can be optionally used to counteract the generation of an electro-osmotic flow that can occur at high electrical voltages. Surprisingly, it has been found that the presence of dissolved polycationic compounds in the acceptor medium, in which the transported carboxylic acids are taken up, makes this possible. This can lead to the formation of viscous layers come from the membrane surface, which contain carboxylic acids derived from the donor medium. These layers are permeable to carboxylic acids. Preference is given to high molecular weight polycationic compounds, such as polyethyleneimine, polyvinylamine, polyvinylimidazole, polyvinylpyridine, polyvinylpyrrolidone, polylysine, polyarginine.

 Polycationic compounds are described in greater detail using the example of polyethyleneimine in the section Post-polymerization functionalization.

The concentration of the polycationic compounds in the acceptor medium is preferably between 0.1 μηηοΙ / Ι to 2mol / l, more preferably between 1 μηηοΙ / Ι and 0.1 mol / l and more preferably between 10μηηοΙ / Ι and 50 mmol / l.

Preference is given to a method in which an inhibition of the electro-osmotic flow during electrodialysis is achieved by the use of polycationic compounds in the acceptor medium.

Carboxylic acids are a very common class of compounds extracted from organic substrates in many industrial sectors. The carboxyl groups essentially cause the chemical but also the physicochemical properties of the carboxylic acids. Lipophilic carbon compounds are thereby given amphiphilic properties. As a result, the solubility in aqueous or organic mixtures is decisively changed compared to a same molecular structure without a carboxyl group. As a rule, this also results in a reduced extractability of these molecules from a mixture of substances, especially if they are present in emulsions. Many carboxylic acids are important building and building materials in various industries, which they often have to be present in a high degree of purity. The extraction takes place by digestion of organic organic products and fossil materials or by a substance synthesis. Separation techniques for carboxylic acids according to the prior art are usually expensive or are not suitable for the continuous separation of large amounts of material. With steadily increasing demand for carboxylic acids, it is desirable to produce a cost-effective process technology which allows continuous removal of carboxylic acids in large quantities. This is now made possible to a great extent by the membranes according to the invention. It is particularly advantageous that other organic and inorganic compounds are retained without having to change the pH or adding an extractant to the substance mixture. It is also particularly advantageous that large amounts of material per unit area can be transported by the open porosity of the membranes. Furthermore, it is advantageous that the energy required for this purpose in comparison to thermal separation process is minimal. It is extremely advantageous that there is no fouling of the membrane by organic compounds which close the nano-scaled gaps, resulting in a longevity of the membranes according to the invention. The membranes of the invention are also bio- and hemocompatible, so that they can be used in biological solutions or in blood and blood products. It is particularly advantageous that the membranes of the invention can be prepared with different support materials that are available from the prior art. Thus, different designs are easy to implement and the different requirements for different applications can be guaranteed.

Definitions The term "open pore" as used herein refers to continuous pores extending from one side of the membrane to the other side. This means that there is an association of individual pores, which communicate with one another via at least one pore entrance and at least one pore outlet and the combination also has at least one pore entrance on one side of the membrane and at least one pore exit on the other side of the membrane. They thus establish a connection from one side of the membrane to the other and allow a mass transport through the membrane. In other words, one side of the membrane may be in fluid communication with the other side of the membrane. Open pore therefore does not mean that a pore has only one opening on one side of the membrane. Open pore therefore does not mean that a pore has only one opening (dead end pore) or two or more openings on only one side of the membrane. Open pores include pores, channels, slots and any other forms of continuous connections between the two membrane sides.

Open-poredness also means porosity.

The total porosity of a substance is made up of the sum of the voids that are related to each other and to the environment (open porosity, useful porosity) and the unconnected voids (closed or dead-end porosity). The porosity here means only the open porosity, ie the Nutzporosität, which can be used for mass transfer. The closed porosity is unimportant to the present invention. The open-pore membrane is therefore preferably ideally open-pored, ie preferably has only useful porosity. High open porosity refers to open-pore material or, ideally, a honeycomb structure, while pure closed-pore character is referred to as foam.

Therefore, the open-pore membrane as well as the space-spanning polymeric structural network is not made of foam or a foam-like structure.

Open-pore carrier membrane

 The term "open-pored carrier membrane" as used herein means space and structural porous support webs or solids having continuous open connections between both (or more) outsides, ie, no foam or foamy formation The geometries of the inner slits or cavities of the support membrane, which are to be filled by room-spanning polymer structures or nanocavitären space-spanning polymer structures.The term structuring refers to the outer shape and geometry of the open-pore carrier membrane.The open connections can be plane-parallel to completely irregular The contours may have any dimensions, preferably, minimum diameters of the internal cavities (pores) are between 10 nm and 500 μm, more preferably wall contours or progression shapes of the inner boundary surfaces which bound the cavities (pores) preferably between 10nm to 400μηη, more preferably between 10nm to 300μηη, more preferably between 10nm to 200μηη, more preferably between 10nm to ΟΟ ΟΟμηη, more preferably between 20nm to Ι ΟΟμηη, more preferably between 30nm to Ι ΟΟμηη, more preferably between 50nm to 80 μιτι, more preferably between 70nm to 50μηη, more preferably between 90nm and 30μηη, more preferably between 100nm and 10μηη and more preferably between 200nm and 1 μηη. Preferably, the spatial structures of the open-pore carrier membrane are not nanocavitary. Preferably, the maximum diameter of the inner cavities of the support membrane between 1 and 3mm μηη, more preferably between 10μηη diameter and 1 mm and more preferably between 10μηη and Ι ΟΟμιτι. The term "minimum diameter" of the internal cavities (pores) refers to the minimum distance that the plane-parallel or completely irregular wall contours or progress forms of the inner boundary surfaces of the support membrane, which delimit the cavities (pores) "Maximum diameter" is the largest distance between the plano-parallel or completely irregular wall contours or progress forms of the inner boundary surface.

The thickness of the support membrane and / or the length of the open connections between the outer sides is preferably between 5μηη and 10mm, more preferably between 50μηη and 3mm and more preferably between Ι ΟΟμιτι and 1 mm. The structure or structure of the space-giving open-pore carrier membrane are arbitrary. It may be a layered structure of fibers or fabrics or consist of a sintered or cast or pressed, continuous or discontinuous contiguous material. The material of the space-giving open-pored carrier membrane can have any external or internal surface finish (eg smooth or rough) and consist of substances or compounds including, among others, natural polymers such as cellulose, synthetic polymers such as polyethylene glycol, and inorganic compounds such as alumina or silica.

Polymer structural network

 The term "polymeric structural network" refers to the entirety of the polymer structures in the pores of the support membrane.

polymer structures

 The polymer structures may be in various configurations and categorized, preferably as filament, ribbon, mesh, sheet or nodular, but other geometries and combinations thereof are possible. The polymer structures are connected to each other covalently and / or electrostatically and are preferably connected physiologically and / or chemosorptively to the interfaces of the open-pore carrier membrane.

Nanocavity polymer structures

The term "nanocavity polymer structures" is understood to mean polymer structures which form nipples in the nanometer range of 0.01 to 1000 nm or enclose and limit such. The nano-cavitation spaces (nano-spaces) are also referred to herein as "nanocavity spatial structures" because they may have different geometric shapes, being round, polygonal or slot-shaped. "Nanocavitary" means the minimum distance between two nanometer-scale polymeric interfaces between 0 , 01 to 1000 nm, preferably between 0.01 and 100 nm, more preferably between 0.1 and 50 nm and more preferably between 1 and 10 nm The maximum distance between two polymeric boundary surfaces is preferably between 1 and 500 nm, more preferably between 5 and 10 nm 200nm and more preferably between 10 and 100nm Preferably, the nanocavity spatial structures are interconnected and can be traversed by a gas or carboxylic acids Nanocavitären the polymer structures form nanocavitary gap spaces, which interconnected and open are. Thus, there is still an open connection between the outer boundary surfaces of the membrane. The support membrane remains open-pore with ideally only useful porosity, because the space-spanning polymeric structure network (definition see below) is also porous and does not adversely affect the useful porosity of the support membrane. The pores in the carrier membrane remain open and are not closed by the space-spanning polymeric structure network. Preferably, the length of a transmembrane path through the interconnected or not directly interconnected nanocavity spatial structures between 1 μηη and 30mm, more preferably between 5μηη and 3mm and more preferably between 50 μιτι and 1 mm.

Process for the preparation of an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the open-pore space-spanning polymeric structure network is nanocavitary and the continuous compounds have a maximum diameter between 1 nm and 500 nm.

The term "space-spanning" is to be understood as meaning that the polymer structures, which are, for example, in a thread-like, band-shaped or net-like configuration, extend, for example through the cavity of the pores of the carrier membrane, from one boundary surface of one cavity toward another boundary surface. As the term "room-spanning" suggests, the polymeric structure network extends into the space of the pores in a naturally random and arbitrary manner. However, the polymer structures and the polymeric structural network do not close the pores. In addition, the polymer structures and the polymeric structural network do not provide a coating on the surfaces of the pores in the support membrane which would ultimately only lead to a reduction in the maximum and minimum pore diameters. The Polymer structures and the polymeric structural network are therefore not a surface modification of the pore surfaces, but are three-dimensional structures that use the interior of the pores, ie extend in the interior of the pores and partially abut the surfaces of the pores, these touch or are bound to them.

 The space-spanning polymeric structure network expands in the pores of the support membrane in a three-dimensional direction. It is open-pored. It is preferably nanocavitary. It is preferably produced by multifocal

Polymer growth. It may partially cover, adhere to or touch the surfaces of the pores, but is not a pure surface coating. It preferably expands in the available space of the pores.

The "polymeric structure network" is composed of the entirety of the polymer structures already defined above, which extend in the cavities of the support membrane, and thus occupy the space within the space-giving, open-pore support membrane in three dimensions.The "polymeric structure network" of polymers is built up. The structure network should have a high open porosity and ideally have only useful porosity. The term "room-spanning polymer structure network" therefore refers to the entirety of the polymer structures that are located in the pores of the support membrane and thus occupy the space within the space-giving, open-pore support membrane in three dimensions ) produced by the polymer structures allow fluid communication of the outer interfaces of the membrane through the open, interconnected nanocavity fractures.

The polymeric structural network is not a pure surface layer coating wherein the space-spanning polymeric structural network may cover and / or adhere to the surfaces of the support membrane pores. Nor is it to be understood as meaning a polymer layer on the surface of the carrier membrane pores. The term is also not to be understood as meaning a layer structure which extends from the surfaces of the pores into the interior of the pores. Thus Raumdurchspannend does not mean that only a coating of polymers is present, which occupies the cavity of the pores partially or completely. In other words, a coating of surfaces, for example by a polymer, is not a space-spanning polymeric structural network. Accordingly, the room-spanning polymers produced according to the invention are Structural network not to surface coatings, although they cover the surface of the space-giving open-pore carrier membrane, in contact with it or may be directly or indirectly physiologically and / or chemosorptively bound to it. The polymer structures limit the gap or cavities within the open-pore carrier membrane and form the space-spanning polymeric structure network.

Self-assembly

 The term "self-assembly" as used herein refers to the formation of three-dimensional molecular contiguous structures that result from a polymerization reaction. The polymerization can be carried out starting from monomers or oligomers. The polymer growth is multifocal. The term "multifocal polymer growth" is understood to mean that the space-spanning polymeric structural network is formed by polymerization in the pores of the support membrane at a plurality of locations within the support membrane and the resulting polymer structures grow together, intertwine and / or bond together , The space-spanning polymer structure network according to the invention is preferably produced on the basis of a multifocal polymer growth which self-assembles during formation from various structure formations.

selectivity index

The selectivity index a, as defined herein, refers to the amount of substance of a carboxylic or fatty acid as compared to an organic compound (ref) of comparable molecular weight (± 30%), which is not a carboxylic or fatty acid, through a membrane of the invention is transported per unit time by applying an electrical gradient or a concentration gradient.

where v is the transport speed in mol / s, n is the transported amount of substance and t is the time.

At the same initial concentration (n ₀ , cooH = n ₀ , _re f) of carboxylic acid and organic compound and the same time (tcooH = t _re f), the selectivity index of the relative transported amount of substance n / n ₀ can be determined. The equation is as follows:

Preference is given to membranes according to the invention which have a selectivity index α of> 4, preferably of> 6, more preferably of> 8 and most preferably of> 10.

Preferably, the selectivity index aoH between a carboxylic acid and the corresponding alcohol is determined: Preference is given to membranes according to the invention which have a selectivity index CIOH of> 4, preferably of> 6, more preferably of> 8 and most preferably of> 10.

The selectivity index characterizes the transport of carboxylic or fatty acids through a separating membrane according to the invention in comparison with a hydrophilic molecule (Kow <1) with a comparable molecular weight (+/- 30%).

The selectivity index αι characterizes the transport of carboxylic or fatty acids through a separating membrane according to the invention in comparison to a hydrophobic molecule (K ₀ w> 1) with a comparable molecular weight (+/- 30%), which carries no carboxyl group. _Kow refers to the distribution quotient of a compound in a mixture of octanol and water.

 ^ COOH /

 ~ _ ^ COOH _ / ^ COOH

Preference is given to membranes according to the invention which have a selectivity index of> 8, more preferably of> 12 and most preferably of> 20.

Preference is given to membranes according to the invention which have a selectivity index αι of> 8, more preferably of> 10 and most preferably of> 15. carboxylic acids

The term "carboxylic acids" includes organic molecules having as a common feature one or more carboxyl group (s) (-COOH). The most common forms of carboxylic acids include compounds of the general formula R-COOH where R is an aliphatic radical CH ₃ - (CH ₂ ) n-. However, equally well branched and substituted alkyl, alkenyl or alkynyl radicals as well as cyclic or heterocyclic carbon radicals may carry a carboxyl group. Further, the term includes compounds having multiple carboxyl groups.

Fatty acids are carboxylic acids having at least 4 carbon atoms. Saturated fatty acids usually have a straight chain and an even number of carbon atoms (n = 4 - 30). They are subject to the general formula CH ₃ (CH ₂ ) _n COOH. They include butyric acid, caproic acid, caprylic acid, capric acid, lauric acid, myristic acid, palmitic acid, margaric acid, stearic acid, arachidic acid, safflower acid and lignoceric acid.

Monoolefinic fatty acids are monounsaturated fatty acids and have the general structure CH ₃ (CH ₂ ) x CH = CH (CH ₂ ) y COOH. You can have the only double bond in a number of different positions. Some important monoolefinic acids are myristoleic acid, palmitoleic acid, petroselinic acid, oleic acid, vaccenic acid, gadoleic acid, gondoic acid, erucic acid and nervonic acid. Polyolefin fatty acids are also called polyunsaturated fatty acids (PUFA). These fatty acids have two or more double bonds, most often separated by a single methylene group (methylene-separated polyolefins). Linoleic acid is a typical member of this group. Some other polyunsaturated fatty acids exhibit a shift in one of their double bonds, which are not separated again by a methylene group and are known as conjugated fatty acids. Some unusual fatty acids do not have the regular structure with one methylene group between two double bonds, but are polyolefins separated by several methylene groups.

The most important polyene fatty acids can be divided into 2 groups with a common structural feature: CH ₃ (CH ₂ ) _X CH = CH- where x = 4 for the (n-6) group and x = 1 for the (n-3) Group. Representatives of this group are linoleic acid, linolenic acid, arachidonic acid, stearidonic acid, EPA, DPA, DHA and meadsäure. The most common polyolefinic acids are octadecatrienoic acids.

Of the unsaturated fatty acids separated by several methylene groups, which occur in the plant kingdom, those with a cis-5 ethylene bond are found in various localities. The three most common fatty acids with this structure are taxoleinic acid (all-cis-5,9-18: 2), pinoleic acid (all-cis-5,9,12-18: 3) and sciadic acid (all-cis-5,1 1, 14-20: 3). Some isoprenoid fatty acids are known, for. B. the retinoic acid. Further examples of branched fatty acids are pristansäure and Phytansäure. Some fatty acids contain either a cyclopropane ring or a cyclopropene ring in the chain or a cyclopentene ring or a heterocyclic ring such as lipoic acid at the end of the chain.

 Other carboxylic acids include, for. B. the cyclopropanoic acids, such as. As the lactobacillic acid (1 1, 12-methylene-octadecanoic), also cyclopropanoic acids, epoxy acids, eg. B. 9,10-Epoxystearin- and 9,10-epoxy-octadec-12-en- (coronaric) acid. Also, acetylene fatty acids, also known as ethic acids, such as tartric acid (6-octadecic acid). Furthermore, hydroxy fatty acids, wherein the hydroxyl group may occur at various positions in the carbon chain, which may be saturated or monounsaturated. Examples are ricinoleic acid (12-hydroxy-9-octadecenoic acid), and lesquerolic acid, the C20 homolog of ricinoleic acid (14-hydroxy-1-1-eicosenoic acid). Likewise di- or tricarboxylic acids, examples of which are adipic acid, pimelic acid, suberic acid, azelaic acid, sebacic acid, brassylic acid and thapsic acid.

 Preferably, the fatty acids are carboxylic acids having at least 6 carbon atoms, i. Fatty acids having a carbon chain length of 6 to 30, more preferably having a carbon chain length of 6 to 28, even more preferably having a carbon chain length of 6 to 26, even more preferably having a carbon chain length of 6 to 24, even more preferably having a carbon chain length of 8; 22 and most preferably having a carbon chain length of 10 - 22. A liquid composition

"Liquid mixture" means a mixture of at least one solvent and at least one carboxylic acid, preferably at least one fatty acid and at least one other substance which is not a carboxylic acid, wherein the solvent may be at least one organic solvent or water or mixtures of organic solvents or in a mixture of at least one organic solvent and water, therefore, in the embodiments described herein, the liquid mixture preferably comprises at least one organic solvent or water or a mixture of solvents, more preferably water or water having a volume of up to 20 vol % of organic solvents which are preferably miscible with water, such as acetone, THF or ethanol The liquid mixture may be either a solution or an emulsion. Alternatively, therefore, the term "liquid mixture" in all embodiments disclosed herein may be replaced by the term "aqueous solution of a mixture of substances" wherein the mixture of substances consists of at least one carboxylic acid, preferably at least one fatty acid and at least one further substance , which is not a carboxylic acid.

The further substance can be selected from the group comprising or consisting of alcohols such as octadecanol, alkyl sulfates such as octadecyl sulfate, possibly alkylsulfonic acids asulfonates such as octadecanesulfonate, proteins such as albumin, .beta.-thromboglobuhn, glycoproteins such as fibrinogen, fibronectin, lipoproteins, enzymes such as LDH, phospholipids, Glycolipids, dyes, platelets, leukocytes, surfactants, inorganic salts or ions such as sulfates, and thrombin-antithrombin complex. The further substances preferably comprise all substances occurring in the blood or in the blood plasma.

Particular preference is given to liquid mixtures of substances comprising or consisting of at least one fatty acid, arginine and at least one solvent.

Particularly preferred are liquid mixtures in the form of a nanoemulsion comprising or consisting of at least one fatty acid and arginine.

Another preferred liquid mixture is whole blood or blood plasma.

The viscosity of the liquid mixture should be below 1 10 mPa * s, preferably below 100 mPa * s, more preferably below 90 mPa * s, more preferably below 80 mPa * s, more preferably below 70 mPa * s, more preferably below 60 mPa * s, more preferably below 50 mPa * s, more preferably below 40 mPa * s, more preferably below 30 mPa * s, more preferably below 20 mPa * s, more preferably below 10 mPa * s, even more preferably below 5 mPa * s and most preferably less than 2 mPa * s.

methods

 surface functionalization

The term surface functionalization for the present invention, the change in the surface properties by introducing chemical radicals, preferably with functional groups, on the surface of the space-limiting structures of the open-pore carrier membrane, both on its outer surface as well as on the surface of the space-giving structures understood. The introduction of chemical residues can be physio- or chemosorptive as well as a combination of both. Hereby, mono- to multilayers of molecules can be applied to the surfaces of a support structure.

 1. physisorption

 Here, the connection of a compound to a substrate surface by electrostatic exchange forces. Physiosorptive application is advantageous since the coating technique can be applied over the entire surface by simple wetting with the substance in solution (for example by dip-coating). It is possible to produce layer thicknesses from a few nanometers down to the millimeter range. Typical compounds for physiosorptive attachments are e.g. Polymers with many different charge groups and amphiphilic molecules, e.g. Phospholipids or carboxylic acids and hydrophilic compounds, such as electrolytes or polyelectrolytes.

 2. Chemisorption

This is understood to mean a covalent attachment of a compound to the substrate surface. A covalent attachment of organic molecules may, for. B. by a SAM on various substrates (eg gold, oxides of aluminum, zirconium, titanium or silicon) via reactive groups on the molecules to be bound HS-R (thiols), R-SS-R '(disulfides), RSR (dialkyl sulfides) , S ₂ CO-R (alkylxanthates), R (4-n) -Si- (R ¹ ) _n , R ¹ : -OMe, -OEt, -Cl, -H, -NH ₂ (n = 1 -3) , Carboxylic acids (R-COOH), phosphonic acids (RP (O) (OH) ₂ ) take place.

 3. vapor deposition process

 Among the methods of depositing and reacting the molecules to be deposited from a gas phase are Atomic Layer Deposition (ALD), Chemical Vapor Deposition (CVD), Plasma-Enhanced Chemical Vapor Deposition (PECVD), Chemical Vapor Infiltration (CVI).

 Gas separation processes are particularly suitable for applying monolayers of the gas phase compound, but multiple layers and polymerization processes can be achieved. Also known are coatings with silanes and organic molecules. a) Surface pretreatment / activation methods

Different membrane materials must be chemically modified before coating with functional molecules. to be activated. So it is z. As in the metals aluminum, titanium, tantalum or zirconium, but also in silicon, it is necessary to oxidize the superficial layers in order to obtain a sufficient number of reactive groups (OH) for attachment of the coating molecules. The appropriate methods are known and are therefore presented only briefly. A commonly used method is the combination of an acid (eg, sulfuric acid) and an oxidizing agent (eg, H2O2), which, due to the high oxidation potential and extremely low pH, both cleans the surface and oxidize the substrate surface. Furthermore, this can also be achieved with a strong base (eg NH ₃ ) and an oxidizing agent.

 Another method of cleaning and activating the substrate surfaces is the application of radiant energy, for example in the UV range.

 Furthermore, plasma processes can be used both for cleaning surfaces and for activating them. Plasma is a complex gas state of matter consisting of free radicals, electrons, ions, photons, etc. Plasma can be formed by continuous electrical discharge in either an inert gas or a reactive gas. For use with a membrane, plasma can improve the properties of both the porous substance and a polymer film for gas separation. Porous membranes can be subjected to a plasma treatment to achieve the following effects:

 (i) cross-linking the topmost layer and reducing the pore size;

 (ii) introduction of functional groups on the surface or

 (iii) deposition and deposition of a thin selective layer on the porous substrate.

 For a plasma treatment inert gases, such as argon or helium are suitable.

 A second application is the introduction of functional groups.

Plasma treatment with air, oxygen, or water vapor introduces oxygen-containing functional groups on the surface. Nitrogen, ammonia and alkylamine plasma introduce nitrogen-containing functional groups. Ammonia plasma was used to measure the flow and selectivity of UF

Polysulfone membranes improve. Nitrogen and oxygen plasma was used to improve the hydrophilicity of polyvinylchloride membranes.

Hydrophilization can also be achieved by plasma-induced deposition polymerization including hydrophilic monomers. The plasma is then formed by gaseous organic molecules that polymerize and on the

Crosslink membrane surface.

 In a preferred embodiment, plasma is used to remove polymer structures on one or both outer sides of the membranes produced according to the invention.

polymerization

In a preferred embodiment, the production of nanocavityer polymer structures is carried out by in situ polymerization within the spatial structures open-pore carrier membranes. For this purpose, it is usually necessary to subject the surfaces of the spatial structures within the open-pore carrier membrane, a pretreatment. The manner of introducing a solution / suspension with reactive mono- / oligomers into the spatial structures of the open-pore carrier membrane depends inter alia on their viscosity, the dimensions of the spatial structures and the reaction conditions and can therefore vary considerably. The type of introduction of the monomer / oligomer solution can be carried out by impregnation, pouring, inserting the open-pore carrier membrane or by a continuous or discontinuous volume flow of the mono- / oligomer solution, which is passed through the membrane. It is advantageous to completely fill all the space structures of the open-pore carrier membrane with the mono- / oligomer solution. The filling can also be done several times in succession. This is particularly necessary if, due to the viscosity of the solution, a low concentration of the mono- / oligomers must be selected. The polymerization process can be carried out under static conditions in a suitable vessel or under dynamic conditions (flow) in a flow-through apparatus. It is preferred if the formation of the space-spanning polymer structure network takes place under static conditions. Therefore, a preferred embodiment of the present invention is directed to a process for preparing an open cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-porous carrier membrane with pores having a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the formation of the space-spanning polymeric structural network takes place under static conditions.

Furthermore, it is particularly advantageous if, during the polymerization to form the space-spanning polymer structure network, the solution of the polymerizable monomers and / or oligomers immediately after addition a starter for multifocal polymerization is introduced into the open-pore carrier membrane and the polymerization takes place under static conditions, ie the solution is not agitated. Therefore, a particularly preferred embodiment of the present invention is directed to a process for the preparation of an open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-porous carrier membrane with pores having a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein, during the formation of the space-spanning polymeric structural network, the solution of polymerizable monomers and / or oligomers is introduced into the open-celled support membrane immediately after adding a multifocal polymerization initiator and the polymerization is carried out under static conditions. Preferably, the feed of the open-pore membrane with the solution and the polymerization under inert gas conditions. The introduction of the mono- / oligomer solutions is preferably carried out at a temperature of -10 to 100 ° C, more preferably this is between 0 ° C and 80 ° C and more preferably between 10 ° C and 40 ° C.

The polymerization is carried out by a radical or nucleophilic reaction of reactive monomer and / or oligomers. The polymerization process is preferably initiated immediately before, during and / or after the introduction of the mono- / oligomer solution into the open-pore carrier membrane. The polymerization to nanocavitären polymer structures then takes place in situ. It is initiated and / or maintained by a chemical reaction involving compounds located on the surfaces of the open cell support membrane and / or contained in the mono- / oligomer solution. Such compounds include nucleophiles such as amines, amides, alcoholates, hydroxide ions, thiolates, triethylamine, ammonia, pyridines such as 4-dimethylaminopyridine, phosphines, carbenes, such as imidazole 2-ylidenes and imidazolin-2-ylidenes or thiazol-2-ylidenes. Cationic catalysts, such as trifluoromethanesulfonic acid and methyl fluoromethanesulfonate, bifunctional organocatalysts, such as [1- (3,5-bis (trifluoromethyl) phenyl) -3- (2-dimethylannino-cyclohexyl) thiourea] or [1, 5,7-triazabicyclo (4.4 .0) dec-5-ene (TBD). Catalysts, such as Grubb's catalyst, metal ions, such as copper, tin, such as tin octanoate (Sn (Oct) 2), aluminum alkoxide AI (OR) 3, titanium alkoxides (Ti (OR) 4), cobalt or nickel, acids, such as ascorbic acid, sulfuric acid or Phosphoric acid, furthermore azo compounds, such as AIBN or peroxides, such as benzoyl peroxide. Initiators of a polymerization reaction are also solvents such as water, DMF, NMP, DMA, NMP, DMSO, tetramethylurea.

 Polymerization processes that can be used to obtain nanocavity polymer structures include process steps known by the terms "grafting from", "grafting through", or "grafting to".

Particular preference is given to polymerization processes based on nucleophilic reaction initiation, such as atom transfer radical polymerization (ATRP), ring-opening metathesis polymerization (ROMP), anionic or cationic polymerization, and free living radical polymerization, but also radiation induced polymerization, ring-opening olefin metathesis polymerization, reversible addition-fragmentation chain transfer polymerization, nitroxide-mediated polymerization, polycondensation reactions, and iniferter-induced polymerization.

 Preferred reactive mono- / oligomers are benzyl-L-glutamate-NCA, phenylalanine-NCA, H-Lys (Z) -NCA, alanine-NCA, valine-NCA, or combinations thereof.

The reactive mono- / oligomers are introduced into the open-pore carrier membranes in the form of solutions or suspensions having a preferred concentration of between 1 mmol / l and 3 mol / l.

 The initiation / catalysis of the polymerization reaction leading to nanocavity polymer structures can also be accomplished by or in combination with physical (n) reaction conditions. This includes in particular the heating of the substrate (open-pore carrier membrane containing the mono- / oligomer solution), preferably heating to 40 to 160 ° C, more preferably 60 ° to 120 ° C and more preferably 80 ° to 1 10 ° C. , The polymerization reaction can be carried out at different ambient pressures. An overpressure can be used, for example, with a temperature increase of the substrate. Preference is given to the application of a pressure between 1, 1 bar and 10bar. Further preferred is the installation of a negative pressure between 10 and 900 mbar.

The temperature and the ambient pressure of the substrate can be varied during the course of the polymerization. Thus, in one embodiment, the substrate initially be subjected to an increased pressure and in the course of this is lowered continuously or stepwise. The duration of a pressure which is changed with respect to the ambient temperature and the environment is preferably over 10 minutes to 72 hours, more preferably over 30 minutes and 48 hours and more preferably over 2 and 24 hours.

 The production according to the invention of nanocavitary polymer structures can also be achieved by a polycondensation of the mono- / oligomers, in the form of a melt, introduced into the spatial structures of the open-pore carrier membrane. Preference is given here to temperatures which are above or above the individual melting point of the monomers used, preferably heating to 40 to 200 ° C., more preferably 80 ° to 140 ° C. and more preferably 90 ° to 140 ° C. Another preferred method for polymerization initiation is exposure of the mono- / oligomer solution impregnated membrane to long or short wavelength radiation. Particularly preferred is the application of microwaves.

 In a preferred embodiment, compounds of reactive mono and / or oligomers are added to the solution which preferably do not react with the mono and / or oligomers and / or influence the polymerization reaction. They serve to stabilize the space of the nanocavitational space structures forming in the course of the multifocal polymerization, in which they are located after polymerization. These preferred apolar and low molecular weight compounds can be rinsed out of the nanocavity pore system after polymerization with suitable solvents. Suitable compounds are i.a. linear or cyclic hydrocarbon compounds or aromatic hydrocarbons, such as alcohols, fatty alcohols, fatty acid methyl esters, alkanes, isoprenes, terpenes, alkenes, alkynes, cycloalkanes, cycloalkenes, cycloalkynes, phenols, carboxylic acids or their salts, alkyl carboxylates, fatty alcohols, fatty acids or their salts, Carbonic acid dialkyl esters, ethers, alkylsulfonic acids or their salts, alkyl sulfates, dialkylsulfoxides, dialkylsulfones, amides, carbamates and organic phosphorus compounds. The terms "release agent" and "compounds used for space stabilization" are used synonymously herein.

The purification of the membranes after polymerization is carried out by placing in preferably THF, DMF or DCM. The successful polymerization is achieved by analytical methods, such as contact angle measurement,

Scanning electron microscopy or infrared spectroscopy. Preferred is a method according to the invention described herein, wherein the solution of the polymerisable monomers and / or oligomers is at least one amino acid and / or at least one oligopeptide in a solvent.

Therefore, a particular preferred embodiment of the present invention is a process for the preparation of an open-celled membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the solution of the polymerisable monomers and / or oligomers is at least one amino acid and / or at least one oligopeptide in a solvent.

Particular preference is given to a method according to the invention described herein, wherein the solution of the polymerisable monomers and / or oligomers is at least one amino acid and / or at least one oligopeptide in an organic solvent.

Therefore, a particularly particular preferred embodiment of the present invention is a process for the preparation of an open-celled membrane for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-pore carrier membrane with pores having a minimum diameter of 50 nm to 500 μm and a maximum diameter of 1 μm to 3 mm,

b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a), c) polymerisation of the polymerisable monomers or oligomers in the pores of the open-pored carrier membrane to form a space-spanning polymer structure network in the pores of the open-pored carrier membrane,

wherein the solution of the polymerisable monomers and / or oligomers is at least one amino acid and / or at least one oligopeptide in an organic solvent.

Post-Polymerisationsfunktionalisierunq

 After preparation of the nanocavity polymer structures according to the invention, in further preferred embodiments functional groups A / compounds can be applied to the polymer structures and / or introduced into the cavities and / or brought to / on one or both outer surfaces of the membranes. In a further preferred embodiment, the preferred compounds are covalently bonded to the nanocavity polymer structures. Preferred compounds which allow cationic or polycationic surface properties by physisorption or chemisorption are amines. These include u.a. aliphatic and cycloaliphatic amines, preferably methylamine, ethylamine, propylamine, butylamine, pentylamine, hexylamine, heptylamine, octylamine, nonylamine, decylamine, undecylamine, dodecylamine, tridecylamine, stearylamine, palmitylamine, 2-ethylhexylamine, isononylamine, hexamethyleneimine, dimethylamine, diethylamine, dipropylamine, Dibutylamine, dihexylamine, ditridecylamine, N-methylbutylamine, N-ethylbutylamine; alicyclic amines, preferably cyclopentylamine, cyclohexylamine, N-methylcyclohexylamine, N-ethylcyclohexylamine, dicyclohexylamine; Diamines, triamines and tetraamines, preferably ethylenediamine, propylenediamine, butylenediamine, neopentyldiamine, hexamethylenediamine, octamethylenediamine, imidazole, 5-aminoimidazole, 3-trimethylcyclohexylmethylamine, diethylenetriamine, dipropylenetriamine, tripropyltetraamine, 4,4'-methylenebiscyclohexylamine, 4,7-dioxadecyl-1, 10-diamine, 4,9-dioxadodecyl-1,12-diamine, 4,7,10-trioxatridecyl-1,13-diamine, 2- (ethylamino) ethylamine, 3- (methylamino) propylamine, 3- (cyclohexylamino) - propylamine, 3- (2-aminoethyl) aminopropylamine, 2- (diethylamino) ethylamine, 3- (dimethylamino) propylamine, dimethyldipropylenetriamine, 4-aminomethyloctane-1, 8-diamine, 3- (diethylamino) propylamine, N, N-diethyl 1, 4-pentanediamine, diethylenetriamine, dipropylenetriamine, bis (hexamethylene) triamine, aminoethylpiperazine,

Aminopropyl piperazine, N, N-bis (aminopropyl) methylamine, N, N-bis (aminopropyl) ethylamine, N, N-bis (aminopropyl) hexylamine, N, N-bis (aminopropyl) octylamine, N, N-dimethyldipropylenetriamine, N, N-bis (3-dimethylaminopropyl) amine, N, N'-1, 2-ethanediylbis (1, 3-propanediamine), N- (aminoethyl) piperazine, N- (2-imidazole) piperazine, N- Ethyl piperazine, N- (hydroxyethyl) piperazine, N- (aminoethyl) piperazine, N- (aminopropyl) piperazine, N- (aminoethyl) n-morpholine, N- (aminopropyl) morpholine, N- (aminoethyl) -imidazole, N- (aminopropyl) -imidazole , N- (aminoethyl) hexane-ethylenediannine, N- (aminopropyl) hexane-ethylene-diaminine, N- (aminopropyl) -ethylenediannine, N- (aminoethyl) -butylenediannin, N- (aminopropyl) -butylenediannin, bis (aminoethyl) -piperazine, bis (aminopropyl) -piperazine, bis ( aminoethyl) hexanethylenediannin, bis (aminopropyl) hexanethylenediannine, bis (aminoethyl) ethylenediannine. Bis (aminopropyl) ethylenediannine, bis (aminoethyl) butylenediannin, bis (aminopropyl) butylenediannin, aliphatic amino alcohols, diethanolamine, bis (hydroxyethyl) aminoethylannin, bis (hydroxypropyl) aminoethylannin and other amino group containing compounds such as melamine, urea, guanidine, polyguanides, amidines , Piperidine, morpholine, 2,6-dimethylmorpholine and tryptamine. Preferred amines are selected from hexamethylenediamine, octylamine, monoethanolamine, octamethylenediamine, diaminododecane, decylamine, dodecylamine, betaines such as polycarboxybetaines, arginine and mixtures thereof. Polycationic in this context means that a functionalization with a plurality of cationic charge carriers, wherein a single compound or single compound unit may contain a singular cationic charge group. Particularly preferred is a post-functionalization with hydrophobized polycationic electrolytes. Positive charge groups are provided predominantly by quaternized nitrogen compounds. However, other charge carriers are also suitable, for example amines, amides, ammonium, imines, azanes, triazines, tetrazanes or nitrones. The nitrogen-based cationic charge groups may be, for example, guanidine or amidine or imidazole groups. DE10124387A1 discloses methods with which hydrophilic cationic polyelectrolytes can be hydrophobically functionalized.

 It is preferred if the cationic charge group consists of a quaternized nitrogen compound.

Preference is given to quaternized nitrogen atoms or compounds having quaternized nitrogen atoms as cationic charge group carriers.

 For hydrophobing, it is preferred that the hydrogen atoms of primary and secondary amino groups are partially substituted by linear or branched alkyl, alkenyl, hydroxyalkyl or alkylcarboxy radicals having 10 to 22 C atoms, preferably 14 to 18 C atoms in the alkyl radical, the further substituents, as carboxyl groups, can carry replace.

Suitable quaternizing agents are alkylating agents such as dimethyl sulfate, diethyl sulfate, methyl chloride, methyl iodide, ethyl chloride or benzyl chloride. Also preferred are hydrophobic Polyethyleninnine. These may be homopolymers of ethyleneimine (aziridine) or its higher homologs, as well as the graft polymers of polyamidoamines or polyvinylamines with ethyleneimine or its higher homologs. The polyethyleneimines can be uncrosslinked or crosslinked, quaternized and / or modified by reaction with alkylene oxides, dialkyl or alkylene carbonates or C 1 - to C 6 -carboxylic acids.

Grafted polyamidoamines are known, for example, from US Pat. No. 4,144,123 or DE-B-2,434,816.

 Furthermore, in the prior art further hydrophobization methods are known, for. For example, for polyenthyleneimine in WO 2004/087226 or polyvinylamine in WO 97/42229 and WO 03/099880.

 Hydrophobic polyethyleneimines can also consist of polymers which have been prepared from ethyleneimine units and polyamidoamines by grafting. Particularly preferred are hydrophobic compounds of polyamidoamine (PAMAM), polyethylenimine (PEI) and polypropylenimine (PPI).

 For a chemosorptive attachment of polycations to compounds, e.g. Aminosilanes (aminopropyl) triethoxysilane (APTS), amino-functionalized polymers (polylysine, polyvinylamine), polycarboxylic acids (polyacrylic acid, polyglutamic acid), polyamides and polyacrylic acid esters, are preferred to carry out further functionalizations and corresponding couplings. This is preferably done by converting the amino functionalities with cyclic acid anhydride (e.g., glutaric anhydride) to the carboxylic acid. The carboxyl groups require activation by various reagents, e.g. Pentafluorophenol, N-hydroxysuccinimide, thionyl chloride, 1-ethyl-3- (3-dimethylaminopropyl) carbodiimide. Alternatively, attachment directly to functional silanes (such as (3-glycidoxypropyl) trimethoxysilane, (3-iodopropyl) trimethoxysilane, (3-

Triethoxysilyl) succinimidanydride).

Uses of the membranes

The membranes of the invention are preferably used in conjunction with a diffusive or electro-kinetic separation process. For this purpose, techniques and devices are known from the prior art. The methods can be summarized under the terms diffusion, electrodialysis and electroosmosis. Diffusion dialysis (DD) is based on the principle of spontaneous concentration compensation of dissolved compounds due to their own motion. When using a diffusion-open membrane, a concentration balance of a compound from a solution with an increased concentration in a solution with a lower concentration of this compound takes place. Electrodialysis (ED) is an electrochemically driven membrane process in which ion-selective membranes in combination with an electrical potential difference can be used to remove ionic species from uncharged compounds from a solution. The starting solution is in a chamber (donor chamber), which preferably has the largest possible contact surface of the volume of space with the at least two sides limiting membranes filled. The separation membranes preferably have a selectivity that is selective to anions on the anode-facing side and cationic on the cathode-facing side. These membranes are preferably aligned parallel to each other and allow a preferably straight-line flow of electrons between an anode and a cathode and are not directly electrically connected to each other. In the spaces filled with a liquid, which adjoin the anode-permeable membrane on the anode side and adjoin the cation-permeable membrane on the cathode side, an accumulation of the anions or cations passing through the ion-selective membranes takes place, therefore the medium becomes concentrate or Acceptance medium and the cell space in which this takes place, called acceptor cell. If depletion of cations and anions is desired, an ED unit may consist of repeating units of a cation acceptor chamber, a donor chamber, and an anion acceptor chamber which may be arranged in a serial sequence between a DC voltage generator. The separation of the ions from the starting solution is carried out by applying a DC voltage to an anode and a cathode. The process can be carried out in a continuous flow mode or under static conditions.

In a particularly preferred method application of the membranes according to the invention, the cathode and / or the anode are in liquid-filled spaces, the cathode or the anode chamber, preferably by an anion- or cation-selective membrane, with a cut-off region, preferably <100D, are electrically separated from the donor and acceptor chambers, respectively. Between the donor and the acceptor chamber is the membrane of the invention. In a further preferred embodiment, a serial arrangement consisting of a cation-selective membrane which delimits a donor chamber to the cathode, a membrane according to the invention, which defines the anode chamber and the anode-side anode chamber an acceptor. Preferably, a plurality of this sequence is to be arranged in series. The last arrangement with such a sequence is closed on the anode side by an anion-selective membrane which adjoins an acceptor chamber. The acceptor and / or the donor chambers can in each case be connected to one another via external connections or can be filled individually from a receiver vessel of the starting solution or of the acceptor medium. In a serial Connection of the chambers with each other, it is particularly advantageous to initiate the starting solution (donor solution) preferably on the cathode side in the donor chamber system of the ED unit and admit the acceptor solution on the anode side in the acceptor chamber system. As a result, a particularly advantageous cross-flow separation is achieved in which carboxylic acids are transported from the starting solution into the acceptor medium.

A further particularly preferred method application of the membranes according to the invention takes place in the form of a hollow-chamber dialyzer, as is known, for example, in medical technology. In one embodiment, a starting solution is passed through a distribution system in tubes or capillaries, which have emerged from a manufacturing process according to the invention and can be used as a separation membrane by these are finally connected to the distribution device. The preferred tubes or capillaries preferably have a diameter between 50μηη and 3cm, more preferably between Ι ΟΌμιτι and 1 cm and more preferably between 1 mm and 5mm and have a length which is preferably between 1 cm and 10m, more preferably this is between 5cm and 2m and more preferably between 10cm and 100cm. The tubes or capillaries are finally connected at the other end to one or more catcher (s). An electric field can be introduced to the liquid medium in the distributor and / or the collecting device, preferably by a connection to a cathode chamber or by placing it within the distributor or collecting system. The cathode chambers are electrically separated from the starting medium by a cation-selective membrane. The tubes / capillaries are in an open or closed container, which receives an acceptor medium or which can be passed through the container. The acceptor medium is electrically connected to an anode, which is preferably electrically separated from the acceptor medium by an anion selective membrane. By applying a voltage between one or more anode (s) and cathode (s), a transport of carboxylic acids from the starting medium, which flows through the tubes / capillaries, takes place into the acceptor medium, which is located on the outer sides of the tubes / capillaries. The flow rate (s) of the starting and / or accepting medium is preferably between 1 mm / min and 100 m / min, more preferably between 5 cm / min and 50 m / min and more preferably between 10 cm / min and 1 m / min. But also a reverse separation direction for carboxylic acids is conceivable. Thus, one or more cathodes may be placed in the distributor or collecting device and one or more anodes may be placed in the surrounding container and / or the Ausgangsmediunn is passed on the outer sides of the tubes or capillaries and the acceptor medium flows through the tubes / capillaries.

 Such applications are preferably carried out at temperatures of the solutions between 5 ° C and 120 ° C, more preferably between 10 ° C and 75 ° C, and more preferably between 15 ° C and 45 ° C. Preferably, the pressure prevailing in the chamber systems, e.g. monitored by pressure sensors, and monitors the differential pressure between the chamber systems. Preferably, pressure equalization takes place between the donor and acceptor chamber systems. In a process execution, a differential pressure between the chamber systems is adjustable. In a process execution, other parameters of the acceptor and / or donor medium are monitored, such as. PH, conductivity, temperature, ion concentrations or viscosity.

 The material of which the usable electrodes are made can be taken from the prior art. However, electrodes are preferred, consisting of or with a permanent coating of carbon, platinum, gold or silver. The solutions filled the anode and cathode compartments preferably contain ionic or ionizable compounds suitable for charge transport. Such compounds are known in the art.

In a process embodiment, a concentration gradient existing between the starting and accepting medium is used to transport carboxylic acids through one of the membranes of the present invention. In another preferred embodiment, the acceptor medium is an organic solvent.

In a further preferred embodiment, the membranes according to the invention are carried out together with cationic compounds which are bound and / or unbound in the acceptor chamber. This is particularly advantageous because carboxylic acids that pass through the membrane into the acceptor chamber can be bound by these compounds, thereby increasing the solubility of the carboxylic acids (eg, by arginine and triethylamine) or lowering them (eg, by sodium, calcium, Polycations) can be. Particularly preferred are polycationic compounds which are capable of simultaneously binding a multiplicity of carboxylic acids. Particularly preferred is polyethyleneimine. In a particularly preferred embodiment of the method, carboxylic acids which have been passed from the donor solution through the separation membrane can be immobilized / bound by means of cationic and / or polycationic compounds and can be removed and obtained in complexed form directly from the acceptor medium.

In a further preferred process, the membranes of the invention are used in a DD or ED process to produce carboxylic acids from a Donormediunn transport in an acceptor mediated and to win the separated carboxylic acids in one or more further process steps. For this purpose, for example, the carboxylic acid-enriched acceptor solution can be separated and the carboxylic acids dissolved therein can be protonated by a pH reduction, which can be adjusted by means of an acid, whereby a phase separation is achieved and the carboxylic acid phase can be separated.

 Preference is given to the use of membranes with nanocavity polymer structures for the separation of carboxylic acids, in which cationic compounds are present in dissolved and / or undissolved form in the acceptor medium.

applications

 Selective removal of carboxylic acids is required in many applications. Membranes of the invention may be used for product recovery or purification of media. Thus, for example, carboxylic acids which are present by a chemical or bio-technological process or by a purification in an aqueous medium can be separated off. As a result, for example, fatty acids can be selectively obtained, find an application, for example as food or a biodiesel, lubricant or soap production are supplied. But also starting materials or products from chemical or pharmaceutical synthesis can be recovered or separated in pure form. Carboxylic acids are furthermore to be separated off, for example, in the dairy industry, the beverage industry, from mixtures of a chemical reaction or synthesis, from cleaning solutions which, for. B. in the aqueous purification of oils and fats, waste water of industrial or municipal origin. Examples of oils are industrial oils, vegetable oils, fuels, used cooking oils. Other applications are possible in bio-diesel production, biomass separation, bio-technological process technology, purification of blood plasma, process fluids, pharmaceutical synthesis mixtures and liquids in chemical analysis.

The method according to the invention is particularly suitable for separating carboxylic acids and in particular fatty acids from the blood of a human by way of dialysis.

 Thus, another aspect of the present invention is directed to a method which is a dialysis method and which serves to separate fatty acids from blood.

In one embodiment of the dialysis method for separating fatty acids from blood, step a) comprises providing blood. Another embodiment relates to a dialysis method for separating fatty acids from ex vivo blood, comprising the step of a) providing blood or blood products. Thus, fluids can be used as the starting medium, such as blood or blood products, Dairy products, beverages, aqueous synthesis media or aqueous extractions of synthesis mixtures, cleaning media or effluents of industrial or municipal origin, but are not limited thereto.

 Accordingly, a further aspect of the present invention relates to the use of the open-cell membranes according to the invention or the open-pore membranes according to the invention obtainable or obtained by one of the inventive methods described herein for the electrophoretic separation of carboxylic acids from liquid mixtures.

 In one embodiment of the present invention, the open-celled membranes according to the invention or the open-pored membranes according to the invention are obtainable or obtained by one of the methods according to the invention described herein for the electrophoretic separation of carboxylic acids from liquid mixtures.

 In a further embodiment of the present invention, the open-pored membranes according to the invention or the open-pore membranes according to the invention are obtainable or obtained by one of the methods according to the invention described herein for the electrophoretic separation of carboxylic acids from liquid mixtures.

 In a preferred embodiment of the present invention, the open-cell membranes according to the invention or the open-pore membranes according to the invention are obtainable or obtained by one of the methods according to the invention described herein for the electrophoretic separation of carboxylic acids from aqueous media.

 In a particularly preferred embodiment of the present invention, open-pored membranes according to the invention or the open-pore membranes according to the invention are obtainable or obtained by one of the inventive methods described herein for the electrophoretic separation of carboxylic acids from aqueous media, wherein the aqueous media are blood and blood products, used.

Description of the figures

1 shows the SEM image of an anodic aluminum oxide membrane, the surface of which had previously been functionalized with polylysine and then the reaction of phenylalanine in THF to form the space-spanning polymer structure network. Examples

The following examples are provided herein to show preferred embodiments of the invention. Other modifications and alternative embodiments with respect to the various aspects of the present invention will be apparent to those skilled in the art. Accordingly, the description is merely intended to teach the general teachings and practice of the present invention. It should be understood, however, that the shown and described forms of the present invention should be considered as examples of the embodiments. Elements or materials can be interchanged from those used in the examples.

Example 1 :

 Synthesis of reactive monomer solutions and pentafluorophenyl ester compounds.

 A) α-amino acid-N-carboxyanhydrides (NCA) suitable for ring-opening polymerization (ROP) were prepared by the Fuchs-Farthing method. This was followed by suspending 5 g of the free a-amino acid (phenylalanine, arginine (protecting group 2,2,4,6,7-pentamethyldihydrobenzofuran-5-sulfonyl), lysine (protecting group tert-butyloxycarbonyl), benzylglutamate) in 60 mL of THF. Subsequently, 1/3 equivalent of bis (trichloromethyl) carbonate was added. The reaction was carried out under protective gas at 50 ° C with continuous stirring. After 2 hours, 180 mL of n-pentane were added and the solid was filtered off via a reverse frit and washed with n-pentane. For purification, the dried solid was dissolved in the required amount of THF and treated with n-pentane until a slight crystallization began. The crystallization was completed for 15 hours at -28 ° C. The solid was again filtered off and washed repeatedly with n-pentane. The purification step was repeated twice. The purity of the product was checked for its melting point.

B) Synthesis of N- (methoxycarbonyl) -amino acids

HR ^! - CHE-COOH + CHj-O-CO-Cl

L NaOK'Wa ₂ 0 ₃ - NiCl

 2. HCl - H, 0

CH3-O-CO - R ^! N-CHE ² - COOH In a 2-liter three-necked flask equipped with a KPG stirrer, 1 mol of amino acid and 0.5 mol (53 g) of sodium carbonate are successively dissolved in 1 l of NaOH (1 N). The solution is cooled with ice / brine mixture to 0 ° C, then 1 mol (94.6 g) of methyl chloroformate (also pre-cooled) is slowly added dropwise within 30 min with stirring. The mixture is stirred for a further 1 h with cooling and 1 h at RT. Afterwards, carefully with conc. HCl acidified to pH 2-3. The product is extracted by repeated shaking with a total of 1 .4 l of ethyl acetate / THF (5: 2). The aqueous phase is back-extracted twice with 200 ml of ethyl acetate each time. For the preparation of N-Moc-D, i-phenylalanine and N-MOC-L-phenylalanine, extract only with dichloromethane. After drying the combined organic phases with sodium sulfate, the solvent is removed completely on a rotary evaporator. The crude product is used without further purification. C) The synthesis of pentafluorophenyl esters suitable for a chemosorptive SAM formation was carried out according to the following scheme:

1 eq carboxylic acid, 1, 1 eq pentafluorophenol and 1, 1 eq DCC are dissolved in 50 ml of dry dichloromethane (for malonic, naphthene, terephthalic and phthalic acid in DMF) under ice-cooling in a 100 ml one-necked flask. After addition of the catalyst, a white solid (dicyclohexylurea) forms rapidly. The suspension is stirred for 48 h at room temperature, then treated with 20 ml of hexane and filtered from the solid in vacuo (G2 filter crucible). After evaporation of the solvents on a rotary evaporator, the crude product is separated from the newly formed solid via a short silica gel column with the mobile phase hexane / chloroform 3: 1. Cryoling of the solvents with good yields (in parentheses) of the activated carboxylic acids: pentanoic acid Pff (86%), hexanoic acid Pff (83%), octanoic acid Pff (71%), hexadecanoic acid Pff (73%), eliadic acid PfP (78%), phenylacetic acid Pff (98%). ), Cinnamic acid PFAP (64%), β-naphtholic acid PfP (84%), phthalic acid PFAP (84%).

D) 3- (guanidinopropyl chloride) trimethoxysilane

Synthesis: 10.0 g APTS (55 mmol, 1 eq) and 8.2 g 1-aminopyrazole-HCl (55 mmol, 1 eq) are dissolved in 30 mL MeOH _a bs. dissolved and stirred for 48 h at room temperature with attached drying tube (CaC ^ filling). Subsequently, the solvent is distilled off in vacuo at 65 ° C. The crude orange product is purified by short path distillation in vacuo (10 mbar) at 150 ° C. The product obtained is an orange-colored, highly viscous oil. For transfer to the sample vessel, it is dissolved in methanol and dried in a vacuum oven at 80 C for several hours. E) alkyl imidazole silanes

 Synthesis: In a 100 ml one-necked flask, 13.72 g (0.05 mol, 1 eq) of imidazole silane and 2.5 eq of haloalkane (C8 and C16) are boiled under N2 atmosphere for 24 h at reflux (100-140 ° C ). After cooling to room temperature, the mixture is washed three times with hexane. For this purpose, either add the hexane to the reaction solution, stir vigorously for 15 min and then pipette off the hexane or the reaction mixture is taken up with DCM and shaken out three times with hexane. The lower phase is separated on a rotary evaporator from residual solvent.

Example 2:

 Surface functionalization of membranes and coupling reactions with activated carboxylic acids and reactive monomers.

 The following membrane materials (carrier membranes) were used: ultrafiltration membranes of (a) zirconium oxide ceramic with an asymmetric pore size distribution (Kerafol, Germany), (b) PTFE membrane, average pore diameter 1, 0 μιτι (Emflon, Pall, Germany), (c ) Glass frit, grade D (Schott, Germany), (d) polyethersulfone membrane (Supor, Ο, δμηη, Pall, USA) and (e) anodized aluminum oxide membranes with channel diameters of 200 nm (Anodisc, Whatman, Germany).

A) Purification of substrates for surface functionalization.

The membranes (a) - (d) were purified by means of a basic cleaning solution consisting of deionized H ₂ O, H ₂ O ₂ (35%) and NH ₃ (30%) in a ratio of 5: 1: 1 (v: v: v). cleaned at 80 ° C for 10 minutes. The procedure was repeated 5 times, finally cleaning with methanol. Thereafter, the membranes were stored in a solution of H ₂ SO and H ₂ O ₂ (7: 3) at 80 ° C for 10 minutes. Final purification with deionized H ₂ O and methanol. Membranes (e) were cleaned with H ₂ O ₂ (35%) at 80 ° C for 10 minutes. Final purification with deionized H ₂ O and drying at 70 ° C for 2 hours.

B) Surface functionalization.

The aminosilanes 3-aminopropyltriethoxysilane (APTS) and 3-trimethoxysilylpropyl-diethylenetriamine (TAPTES) (Sigma-Aldrich, USA) were dissolved in toluene and heated to 75 ° C. Here, the coating objects were stored for 4 minutes and then rinsed with toluene and dichloromethane and then dried in a vacuum oven at 80 ° C for 24 hours. Quality control by means of contact angle measurements. C) Covalent bonding of functional compounds.

 The membranes were placed in an aminosilane solution at a concentration of 1% by volume to 5% by volume in toluene at 120 ° C for 4 hours. Then clean the membranes with toluene and dry in a vacuum oven at 70 ° C.

The covalent coupling of the activated carboxylic acids to the membrane surfaces was carried out by placing in a 60 mmolare solution of pentafluorophenyl ester in DMF for 15 hours and 24 hours at temperatures between 0 ° C and 80 ° C. For flow-through coatings, the volume flow through the membrane was 1 mL / h to 2 mL / h.

C) Polycondensation of activated amino acid monomers and chemosorptive attachment of higher molecular weight compounds.

 This was done with reactive monomers on the aminosilanes via a ring-opening polymerization (ROP) of a-amino acid-N-carboxyanhydrides.

Surface functionalization with amino acid NCAs (concentrations 40 to 80 mmol in THF) was performed on the anodized aluminum membranes by a flow through method. For this purpose, the membranes were placed in a closed holding device, which allowed a continuous flushing of the membrane. In a glass syringe, the monomer solutions were mounted and fed through a device for automatic punch feed at a constant speed via a hose line of the holding device. The reaction took place over 6, 12, 24 and 36 hours. Furthermore, combinations of the amino acid NCA ^{'s have been used} to prepare polymer structures. The quality control of the polymerization result was carried out by means of contact angle measurements and SEM. The resulting support membrane with Cbz-lysine and Boc-arginine NCA had comparable properties in the following experiments compared to phenylalanine-NCA.

D) polycondensation of activated amino acid monomers and chemosorptive attachment of higher molecular weight compounds to form a xerogel

This was carried out with reactive monomers on the aminosilanes such as TAPTES or APTES via a ring-opening polymerization (ROP) of a-amino acid-N-carboxyanhydrides.

A filament ceramic of Kerafol was placed in 5% v / v TAPTES or APTES in 5 mL of absolute toluene and refluxed for 4 h at 95-120 ° C.

Subsequently, the aminosilane-functionalized filter ceramic was placed in a solution of amino acid NCA in 5 mL of absolute dichloromethane (c = 0.1 mM) for 48 h at room temperature. The reaction was carried out with phenylalanine, sarcosine, alanine, cysteine, valine, benzylglutamate, Cbz-lysine, Boc-arginine-NCA (guanidine-protecting group) and lysine NCAs. The resulting support membrane with Cbz-lysine and Boc-arginine NCA had similar properties in the following experiments compared to phenylalanine-NCA.

 Preliminary experiments with isoleucine, hexanoylthreonine, ε-Ν, Ν-dipentyl-lysine and γ-butyl glutamate were carried out with a positive result and showed preliminary results similar to the experiments with Cbz-lysine and Boc-arginine-NCA. Exemplary for phenylalanine NCA

 This was carried out with reactive monomers on the aminosilanes such as TAPTES or APTES via a ring-opening polymerization (ROP) of a-amino acid-N-carboxyanhydrides.

 A filament ceramic of Kerafol was placed in 5% v / v TAPTES or APTES in 5 mL of absolute toluene and refluxed for 4 h at 95-120 ° C.

Subsequently, the aminosilane-functionalized filter ceramic was placed in a solution of 131 .5 mg phenylalanine NCA in 5 mL absolute dichloromethane (c = 0.1 mM) for 48 h at room temperature. E) A thermally induced polycondensation of the reactive monomers was carried out with phenylalanine, sarcosine, alanine, cysteine, valine, benzylglutamate, Cbz-lysine, Boc-arginine-NCA (guanidine unit protecting group) and lysine NCAs , For this purpose, 1 g of one or more NCA was weighed into a 50 ml Erlenmeyer flask under argon. The Erlenmeyer flask was sealed with a glass stopper secured by a steel spring and kept at 120 ° C. for 12 h. The result was a solid mass which was mortared and taken up in THF. Here, linear and cyclic oligomers and polypeptides were detected. For the coatings, 250 mM solutions of polyphenylalanine, arginine, Boc-arginine, Cbz-lysine, lysine and benzylglutamate NCA and in further experiments together with oligomers and polypeptides, which were produced by a polycondensation, in methyl tert-butyl ether (MTBE). 0.5 mL of the solution was added dropwise to the 1, 33 cm ² porous support material (with or without amino functionality) and the MTBE evaporated at 25 ° C and 60 ° C in vacuo. This process was repeated 8 times and 16 times. The support was then heated to 110 ° C for 15 hours. The membranes were rinsed several times in TBME. The successful functionalization is checked by means of contact angle measurement and SEM.

Repeat experiments were carried out with 0.5 molar solutions of the mono- and oligomers in which the solvent was NMP, DMSO and DMF and the Membranes were repeatedly soaked with the solutions until no more recording of the solution was recognized. This was followed by thermal reaction at temperatures between 80 ° and 164 ° C for 8 and 16 hours. Subsequently, clean the membranes as described above. A solid analysis shows the presence of cyclic polypeptides. The resulting support membrane with Cbz-lysine and Boc-arginine NCA had comparable properties in the following experiments compared to phenylalanine-NCA.

F) Solvent-induced polycondensations were carried out by adding 250 mmolar solutions of phenylalanine, arginine, Boc-arginine, lysine, Cbz-lysine,

Benzylglutamate and valine NCAs and combinations of these were prepared in dimethylformamide. The support material (with or without amino functionality) was immersed in the solutions in an inert gas atmosphere. After 72 hours at room temperature or 60 ° C, the membrane was rinsed with 5 mL of THF. Supplementary studies were carried out in the same way with solvent mixtures of THF and DMF (80:20 v: v, and 50:50 v: v). The polymerization was investigated by means of contact angle measurement, infrared spectroscopy and scanning electron microscopy. For membranes in which SEMs were polymer structures on the outer surfaces of the membranes, they were treated with argon plasma. The resulting support membrane with Cbz-lysine and Boc-arginine NCA had comparable properties in the following experiments compared to phenylalanine-NCA.

G) Functionalization with polycations.

Membranes pretreated according to steps A) to E) or native membranes were placed in a 10 wt% polyethylenimine solution (methanol) at 25 ° C for 24 hours. For purification, the membranes were placed in methanol and then dried. This step was repeated three times. The functionalization was checked by infrared spectroscopy.

Furthermore, functionalizations were carried out with mixtures of polyethylenimine and oleic and stearic acid, which were dissolved in pentane. The solution was pipetted onto one side of the membrane several times.

 The after the o. A. Treatments obtained membranes were broken or cut and the broken edges and the outer surfaces assessed by electron microscopy. At the breaklines (where possible) and the outer surfaces of the membranes, water and oleic contact angle measurements were made.

 Results: Examples of membranes listed by the

Production methods are shown in Table 1. Table 1: Examples of membranes, their surface functionalization and polymerization process.

Designation Carrier-surfacePolymerization reaction Additional NC water contact membrane functionalization process duration [h] Functionalization Structures ³ angles [°]

 M1.0 a - - - - 36

 Ml.l a Eliadinsäure PfP - 8 - 79

 M1.2 a phenylacetic acid Pff - 8 - 68

 M1.3 a C16 imidazole silane - 8 - 92

 M1.4 a phenylalanine NCA OP / grafting-from 36 ++ 88

 M1.5 a lysine NCA ROP / grafting-from 24 + 82

 M1.6 a Arginine-NCA ROP / Grafting-from 24 + 75

 M1.7 a Benzylglutamate-NCA ROP / Grafting-from 12 - 61

 M1.8 a phenylalanine NCA LM induction 2 +++ 83

 M1.9 a lysine NCA LM induction 3 ++ 85

 Ml.10 a Arginine-NCA thermocatalysis 2 ++ 79

Ml.ll a Benzylglutamate-NCA LM induction 4 PEI ^b ++ 80

 M1.12 a phenylalanine NCA thermocatalysis 1 PEI +++ 117

 M2.0 b - - - - 121

 M2.1 b phenylalanine NCA thermocatalysis 2 +++ 111

 M2.2 b Lysine-NCA thermocatalysis 2 +++ 95

 M2.3 b arginine-NCA LM induction 4 +++ 93

M2.4 b benzylglutamate-NCA thermocatalysis 2 ++ 82

M2.5 b phenylalanine NCA thermocatalysis 2 PEI +++ 92

M3.0 c - - - - - 26

M3.1 c eliadic acid PfP - 24 - 77

M3.2c phenylacetic acid Pff - 24 - 65

M3.3 c C16 imidazole silane - 24 - 82

M3.4c phenylalanine NCA OP / grafting-from 8 + 100

M3.5 c lysine NCA ROP / grafting-from 8 - 92

M3.6 c arginine-NCA ROP / grafting-from 8 + 65

M3.7 c benzylglutamate-NCA ROP / grafting-from 8 - 62

M3.8 c phenylalanine NCA thermocatalysis 2 +++ 105

M3.9 c lysine-NCA LM induction 3 ++ 99

M3.10 c Arginine-NCA thermocatalysis 2 ++ 92

M3.ll c Benzylglutamate-NCA LM induction 3 PEI ++ 93

M3.12 c phenylalanine NCA thermocatalysis 1 PEI +++ 92

M4.0 d - - - - - 41

M4.1 d eliadic acid PfP - 24 - 78

M4.2 d C16 imidazole silane - 24 - 81

M4.3 d phenylalanine NCA ROP / grafting-from 24 + 76

M4.5 d PA lysine NCA ^C ROP / grafting from 24 + 70

M4.6 d PA-Arginine-NCA ROP / Grafting-from 24 + 71

M4.7 d Benzylglutamate-NCA ROP / Grafting-from 12 - 66

M4.8 d phenylalanine NCA thermocatalysis 2 +++ 85

M4.9 d lysine-NCA LM induction 3 ++ 80

M4.10 d PA-arginine-NCA thermocatalysis 2 +++ 88

M4.ll d arginine-LM induction 3 ++ 81

 Benzyl glutamate-NCA

 M4.12 d PA-arginine thermocatalysis 2 PEI +++ 83

 Benzyl glutamate-NCA

 M4.13 d phenylalanine NCA thermocatalysis 2 PEI +++ 93

 M5.0 e - - - - - 25

 M5.1 e eliadic acid PfP - 12 - 75

 M5.2 e phenylacetic acid Pff - 12 - 70

 M5.3 e C16 imidazole silane - 12 - 76

 M5.4 e Phenylalanine NCA OP / Grafting-from 36 ++ 71

 M5.5 e lysine NCA ROP / grafting-from 36 + 68

 M5.6 e Arginine-NCA ROP / Grafting-from 36 ++ 60

 M5.7 e Benzylglutamate-NCA ROP / Grafting-from 36 + 58

 M5.8 e phenylalanine NCA thermocatalysis 2 +++ 88

 M5.9 e Lysine-NCA LM induction 4 +++ 79

 M5.10 e Arginine-NCA thermocatalysis 2 +++ 83

M5.ll e Benzylglutamate-NCA LM Induction 1 PEI +++ 82 aNC structures = nanocavitary polymer structures with: - none, + predominantly partial, ++ predominantly complete and +++ complete space filling; ^b PEI = polyethyleneimine; ^C PA = phenylalanine

After a surface coating with activated carboxylic acids as well as after a ring-opening polymerization (ROP) of amino acid monomer solutions, which were initiated by a surface activation, under the selected reaction conditions, no strand-like or tissue-like structures had formed within the cleavage spaces of the membranes. At long reaction times of ROP with amino acid NCA's, partial or complete occlusion of the interiors of the support membranes occurred. In thermocatalytic and solvent-induced polymerization reactions of the amino acid NCA ^{'s used} , space-filling or space-spanning polymer structures with nanocavitary gaps and channels formed, with complete coverage of the inner membrane surfaces.

Coatings with alkylsilanes reached water contact angles (HPC) of 59 ° to 79 °. The WKW of the amino acid polymers were between 68 ° and 17 ° and those of the alkyl imidazole silanes between 66 ° and 92 °. The guanidine silanes showed WKW by 68 °. For the combination of amino acid polymers or guanidine silanes together with alkylsilanes, HPCs of 95 ° - 10 ° resulted. The fatty acid contact angles (HFCs) for coatings with alkanesilanes were between 10 ° and 25 °, for amino acid polymers between 0 ° to 20 °, for the alkyl imidazole silane functionalization between 0 and 10 °, and for surfaces with guanidine silanes around 30 °. For coating combinations of alkane silanes and amino acid polymers, the HFCs were below 10 °.

Example 3

 Investigation of the selectivity of the transport of carboxylic acids.

 Round membrane pieces with a diameter of 12mm of treated

Membranes from experiment 2 with room-filling or space-spanning nanocavitamin polymer structures (M1 .8 and M2.5) and the corresponding native membranes (M1 .0 or M2.0) were pressure-tight in a Teflon septum, which in an electrodialysis unit between the donor and the acceptor chamber was located and electrically insulated from each other. The two chambers had a filling volume of 25 ml each and were separated from an outside adjoining anolyte or catholyte chamber by further Teflon SEAPs, into which a cation- or anion-selective membrane (Fumasep FKS or FAS, Fumatech, Germany) was pressure-tight. In the anolyte and catholyte chambers were platinum electrodes connected to a DC power source. A lid sealed the chambers against each other and against the atmosphere. Through a pneumatic connection, which was through the lid in the donor chamber, the pressure in this chamber could be monitored by means of a pressure transducer. The experiments were carried out with different test solutions, with which the donor chamber was filled in each case: Experiment D1) NaCl 1% by weight + caproic acid 100 mmol / l in 2% ammoniacal solution; Experiment D2) caprylic, myristic, myristoleic, palmitic, oleic, linoleic, and linolenic acids, each 20mmo / l, nano-emulsified in a 250mmol arginine solution; Experiment D3) oleic acid, 1-octadecanesulfonyl chloride + octadecyl sulfate and 1-octadecanol (10 mmol each) + DMSO 2% by weight in 20% ethyl alcohol solution; Experiment D4) NaSO ₄ 1% by weight + albumin 100mnnol / l + creatinine 50mol / l and linolenic acid 50mmol / l in aqueous solution of OOmmololar arginine. The acceptor chamber was filled in experiments D1 and D2 with a 10Ommolaren arginine solution and in the experiments D3 and D4 with a NaOH solution (0.1%) in which dissolved 0.5Gew% of polyethyleneimine. Magnetic stir bars were inserted in both chambers, which were rotated by an external magnetic stirrer at 100rpm during the investigations.

There were experiments for diffusion (DD) and electrophoresis (ED) of the test compounds. The diffusion experiments took place over a period of 6 hours. For electrophoretic mass transport, a voltage of 40 V was applied between the electrodes for 60 minutes. Samples were taken from the acceptor chamber every 60 minutes for the diffusion experiments and every 15 minutes for the electrodialysis experiments. Furthermore, samples of the starting solution and the solution were taken in the donor chamber after the end of the experiment. The samples were analyzed for the concentration of each substance used. From this, the proportion of the compounds transported through the membrane was calculated.

Results:

The results of the transport experiments are summarized in Table 2. Table 2: Results of translocation experiments on diffusion DD and electrophoresis ED.

'All value data as relative amount (%) of the starting amount that has been transported into the acceptor medium.

Membranes with nanocavity polymer structures were not permeable to hydrophilic compounds, while these membranes were permeable to both diffusive and electrophoretic mass transport of carboxylic acids. The electrophoretic mass transfer for carboxylic acids was increased compared to the native carrier membranes. For carboxylic acids compared to sulfates, which had a comparable molecular weight, a selective mass transport with a selectivity index αι of 158 for M1 .8 and 164 for M2.5.

where v is the transport velocity through the membrane, n is the transported amount of substance and n _{0 is} the amount of substance in the donor solution at time t = 0.

 Based on the corresponding alcohol, 1-octadecanol, the selectivity in electrodialysis was even higher. The selectivity index CIOH was 395 for M1 .8 and 820 for M2.5.

^U OH

^V O ⁿ O,

⁷ "o

For the sulfonate, which is formed from the sulfonyl chloride, it was not possible to calculate a selectivity index for the membranes M1.8 and M2.5 since the transported amount of sulfonate through the membrane was too small and could not be determined.

 Compared to electrodialysis, significantly less mass transport was observed in diffuse dialysis. The transported amount of sulfonyl chloride and sulfate was again so low that no selectivity index could be calculated for the membranes M1 .8 and M2.

In contrast, in the native membranes M1.0 and M2.0, selectivity indices for sulfonyl chloride and sulfate between 0.6 and 0.8 were observed in both electrophoretic and diffusive separations. For alcohol, low selectivity indices of 0.36 and 0.25 for M1.0 and M2.0 were determined for diffusive separation, and 3.9 and 4 for M1.0 and M2.0 for electrodialysis. In electrodialysis with the native membranes M1 .0 and M2.0, an EOF increased the pressure in the donor chamber to 152 or 166mbar, 235 and 243mbar, 195 and 205mbar and 165 and 188mbar in experiments D1 to D4. In contrast, the pressure in the donor chamber increased only minimally when using the membranes M1.8 and M2.5 at 3 and 2mbar at D1, 5 and 4mbar at D2, 2 and 1 mbar at D3 and 3 and 3mbar, respectively at D4. Example 4:

 Investigations on "membrane fouling" by organic media.

For the investigations were membrane pieces with a diameter of 12mm, of polyethersulfone and anodized alumina membranes, which were treated in experiment 2 and room-filling or space-spanning nanocavity polymer structures had (M4.13 and 5.1 1) and the native membranes (M4.0 or M5.0). In addition, treated membranes from Example 2 were investigated, which had been coated with functional compounds but had no space-filling or space-spanning polymer structures (M4.2 and M5.2).

 Experiments on diffusion and electrophoretic mass transfer were carried out analogously and with the same experimental setup as in Example 3. To test for a change in mass transport by fouling processes, 6-lauroleic acid (C12: 1) was added to the following organic media at a concentration of 100 mmol / L: V1 calf serum, V2 sludge (10 wt% dry matter), V3 buttermilk and V4 beer fermentation solution , The acceptor chamber was filled with a 200 mm arginine solution.

The electrodialysis was carried out at a voltage of 15 V with a current of 100 mA for 6 hours. Every 15 minutes, a sample was taken from the acceptor chamber to determine the lauric acid concentration and to detect proteins. The time to reach a lauroleinic acid concentration of 10mnol / l was determined (duration 1). Subsequently, both chambers were emptied and then filled with the same starting solutions as in the previous experiment, and started an identical experimental procedure. Again, the duration was determined until reaching a lauroleinic acid concentration of 10mnnol / l (duration 2). Thereafter, the membranes were swirled in a water bath and then dried. The dried membranes and 2 membranes with and without polymer structures that were not used in the experiments (reference samples) were stained with fluorescein isothiocyanate. The fluorescence microscopic staining intensity of the membranes used in the experiments was compared with that of the reference samples. Results: The numerical results are given in Table 3. Table 3: Membrane foulin experiments.

aDuration 1 = duration in minutes until a lauroleinic acid concentration in the acceptor chamber of 10 mmol / l is reached during the first test run; ^b duration 2 = duration in minutes until lauric acid concentration in the acceptor chamber reaches 10 mmol / l during the second test run; ^c Protein 1 = Semiquative detection of protein in the acceptor chamber solution at the end of the first trial run, detection limit 0.5 g / l; ^d Protein 2 = Semiquative detection of protein in the acceptor chamber solution at the end of the second run, detection limit 0.5 g / l The separation of the membranes with nanocavitären polymer structures was comparable in the investigated starting solutions. This remained, after exposure of the membrane with an organic medium, unchanged in a repeated separation for a further 6 hours. Supports of organic compounds were virtually undetectable on these membranes. In contrast, there were significant to strong deposits on membranes that had received hydrophobic functionalization and in the native membranes after the electrodialysis experiments. In these membranes, the transport performance for fatty acids was significantly reduced in the repeated electrodialysis experiment compared to the first attempt as an expression of membrane fouling. In the experiments using membranes with hydrophobic surface functionalization and native membranes, the protein detection in the acceptor solutions was positive, whereas proteins were not determinable in the acceptor solutions in the experiments with membranes that had room-filling or space-spanning polymer structures.

Example 5:

 Study on biocompatibility and hemocompatibility.

 The following membranes from Example 2 were tested: M1 .1, M1 .12, M4.2, and M4.8 and the native membranes M1 .0 and M4.0. The experiment was carried out according to Example 3. The donor chamber was in the test series A) with whole blood, which was anticoagulated with heparin in a concentration of 1, 1 IU / ml and in the experiment B) filled with blood serum. The investigations were carried out at a temperature of 37 ° C. The acceptor chamber contained a 10 molar arginine solution. A DC voltage of 5V at 50mA was applied to the electrodes. The test duration was 120 minutes.

 After the end of the study, samples were taken from the acceptor chamber and analyzed for the content of fatty acids and proteins. The determination of the fatty acids was carried out by gas chromatography. All tests were repeated twice and the mean of the values obtained was calculated.

The whole blood (VB) or the serum (S) from the donor chamber were separated and further analyzed. EDTA or citrate were added to the VB to reach final concentrations of 4 and 13 mM, respectively. Before centrifugation, the number of platelets was determined with a Coulter AcT diff ™ haematology analyzer (Coulter Corporation, USA). The EDTA-primed VB was centrifuged at 2.200 g for 10 min. At 41 ° C and the citrated VB was centrifuged for 10 min at 1.000 g and for 10 min at 10,000 g at 41 ° C. The content of thrombin-anti-thrombin complex (TAT) and factor XIIa-AT - Complex formation was quantified with an enzyme immunoassay (EIA) (Enzygnosts, Behringwerke, Germany). Further, quantification was by an EIA for β-thromboglobulin (β-TG) and the complement factors C5b and sC5b-9. The values obtained were compared with those from a reference sample in which the VB or S had been stored in a PTFE container of the same duration and agitation as in the electrodialysis apparatus.

The membranes used were briefly swirled after the experiments in a water bath and then divided. A portion of the membrane pieces were dried and examined for the protein adsorption carried out. The other part of the membrane pieces was immediately further processed for the analysis of the cell occupancy of the surfaces.

The adsorbed protein content was determined by enzyme linked immunosorbent assays for fibrinogen, fibronectin and albumin. The mean coverage densities of hydrophobized membranes and membranes with nanocavity polymer structures were related to the staining index, which was determined for an unused starting membrane. The extent of adhesion of platelets and leukocytes was determined by fluorescence microscopic analysis after staining with calcein AM and propidium iodide and is reported as relative surface coverage to total surface area. Cytotoxicity was determined by determining the LDB levels of VB after electrodialysis and is reported as a relative increase over the value of a reference sample stored under agitation in a PTFE container over the duration of the experiment.

Results: The results are summarized in Table 4.

Membranes with nanocavity polymer structures caused only minimal activation of the coagulation and complement system during electrodialysis compared to a native membrane or a membrane with a hydrophobic surface functionalization. Furthermore, there was a significantly lower superficial occupancy of serum proteins and blood cells than was the case with native membranes and membranes with a hydrophobic surface functionalization. While there was evidence of surface cytotoxicity in electrodialyses using native membranes and membranes with hydrophobic surface functionalities, those were not found in membranes with nanocavity polymer structures. Table 4: Results of bio- and hemocompatibility studies.

* Value data in% as relative change compared to the reference sample; ^a TAT: thrombin-antithrombin complex; ^b ß-TG = beta-thromboglobulin; ^c platelets / leukocytes = area occupied by platelets or leucocytes in relation to the total area.

The adherent cells on the surfaces of membranes with nanocavity polymer structures were 97-99% considered live, whereas on native membrane surfaces this was only 79-84%.

During electrodialysis, serum and whole blood fatty acids had been transported to the acceptor chambers. The concentrations were between 8 and 13 mmol / l for the native membranes, 12 and 16 mmol / l for membranes with a hydrophobic surface functionalization, and 22 to 34 mmol / l for membranes with nanocavity polymer structures. Proteins were found only in the native membranes and membranes with hydrophobic surface functionalization on the acceptor side.

Example 6

 Investigation of the use of membranes with nanocavitary fission spaces for the selective separation of fatty acids from aqueous mixtures.

Ceramic zirconia sintered membranes with a mean channel width of Ο, δμηη, a material thickness of 3 mm and dimensions of 30 × 30 cm were supplied to a surface pretreatment according to Example 2 (M1 .1 1 or M1 .12). The presence of nanocavity tissue-like polymer structures that occupy space or space throughout the lumen system, i. the pores of the membranes could be documented electron microscopically.

In each case, 10 of the prepared membranes were placed in an electrodialysis device by gluing them in a frame device made of PTFE. Furthermore, cation-selective membranes (Fumasep, FKS, Fumatech, Germany) were introduced into a similar frame device. The frame devices were stacked so that alternately one of the prepared separation membranes and a cation-selective membrane confined a donor chamber and an acceptor chamber, each having a depth of 1 cm. The anolyte compartment was electrically terminated with an anion selective membrane against the last acceptor chamber. The first donor chamber was adjacent to the cation-selective membrane of the catholyte chamber. The stack as well as the outside anolyte and catholyte compartments were pressed together by an external device so that the chambers were pressure sealed against the environment. Another identical ED unit was manufactured using native ceramic zirconium oxide membranes. During ED, a DC voltage of 40V was applied at 0.3A. The donor and acceptor chambers were each serially connected by a tube system. The inlet and the flow direction of the chamber systems were opposite, the introduction of the starting medium was in the first cell, the Cathode chamber adjoined. Both systems were designed with a flow rate of 1 liter / min. applied. In a comparative experiment untreated ceramic membranes were used with the same experimental setup. The acceptor solution consisted of a 0.5 molar arginine solution introduced from a storage vessel into the acceptor chamber system. After exiting the ED unit, the fatty acid-enriched acceptor solution was collected in a vessel and the volume determined. Furthermore, samples were taken for analysis. There was a quantitative determination of iron, magnesium and phosphorus, as well as a semiquantitative determination of glycolipids.

 A hexane-extracted rapeseed oil was degummed with an aqueous arginine solution. The aqueous phase (WP) contained 12% by weight free fatty acids, 8% by weight phospholipids and 6% by weight glycolipids, as well as lipoproteins and dyes, as well as iron, magnesium, sodium, calcium and potassium ions. This WP was a greenish cloudy emulsion and was introduced into the donor chamber system with a peristaltic pump.

 To each of 50 liters of the collected acceptor solutions was added HCl (37% by weight) until the pH of the solution became 2.5. The then floating oil fraction was transferred to another collection vessel. The remaining solution was then re-raised to a pH of 12 with NaOH and reused after separation of sodium and chloride ions.

 From the depleted aqueous cleaning medium samples were taken for analysis. The fatty acid analysis was carried out by GC of the methyl ester. For this purpose, a sample processing by addition of HCl and extraction of the fatty acids with hexane. This was followed by methylation.

Results: For uncoated membranes, an electroosmotic flow occurred which caused the volume of the acceptor solution to decrease rapidly and increase the volume of the depleted starting solution by the corresponding amount, thus prematurely stopping the experiment. In ED with membranes containing nanocavity polymer structures, the volumes of the donor and acceptor media remained the same. Furthermore, there was a depletion of the fatty acid content of the aqueous cleaning medium to 0.1% by weight by electrodialysis. In the clear and colorless acceptor medium there were no determinable concentrations of phosphorus, iron, magnesium, sodium, calcium or potassium at the end of the experiment. Glycolipids could also not be detected. The oily fraction separated from the acceptor medium consisted essentially of oleic acid, furthermore it contained linoleic acid, linolenic acid and stearic acid. Example 7

 Investigation of the selective separation of fatty acids from an aqueous one

Albumin solution. To an aqueous (0.9% NaCl) human albumin solution containing 20% by weight, 2% oleic acid was added, based on the weight of the albumin. The solution was stirred for 2 hours at 25 ° C. The donor chamber was filled to the brim with the solution. The experimental setup corresponded to that of Example 3. The acceptor chamber was filled in the test series V1 with a 150 mmolar arginine solution. In the test series V2, 0.5% by weight of polyethyleneimine was dissolved in the arginine solution. The electrodialysis was carried out in the test series I. with a voltage of 5 V and in the test series II. With 50V, each over 2 hours. The current flow and the pressure in the donor chamber were continuously measured. At intervals of 15 minutes and at the end of the study, samples for the determination of fatty acids and for albumin detection were taken from the acceptor chamber. The fatty acid analysis was carried out by GC, the determination of albumin spectroscopically with a Bromcresol-green reagent. As separation membranes, 12 mm-diameter pieces of the anion-selective polymer membranes Fumasep FAA-3-PK-130 (Fumatech, Germany) and PC 400D-250-250 and PC 200D-250-250 (PCA, Germany) were investigated. Furthermore, nanofiltration membranes in which hydrophobicization of the channel surfaces was carried out according to Example 2 (M5.1 and M5.3) were investigated. In addition, a track-etch polycarbonate membrane (Nuclepore, Whatman, USA, pore diameter 20 nm, thickness 5 μm), whose inner and outer surfaces had been coated over the entire surface according to Example 2 M1.1, was investigated (PC1.1). The selectivity of the transport properties was compared with membranes that had room-filling or space-spanning nanocavity polymer structures (M5.12 and M1 .8 from Example 2). The hydrophobized nanofiltration membranes had a water contact angle between 1 10 ° and 1 18 °. After the experiments, all membranes were removed and visually assessed.

Results: The numerical results are summarized in Table 5. Closed anion-selective membranes are impermeable to fatty acids. The membranes swelled during electrodialysis and deformed. The native ultrafiltration membranes allowed transport of fatty acids to form an electroosmotic flow. This was also the case with nanofiltration membranes whose surfaces had been hydrophobized. at Albumin was also transported through the membranes in the aforementioned membranes. On all of the above-mentioned membranes there were gel-like gel-like deposits containing albumin. The membranes with nanocavitational space-filling or space-spanning polymer structures had a significantly higher transport rate for fatty acids than the other open-pored membranes. At the same time, transport of albumin did not take place and virtually no electroosmotic flow occurred at the lower voltage applied to the membrane. At high voltage, there was little electro-osmotic flow, which was virtually eliminated by the presence of polycations in the acceptor solution. These membranes also had no albumin deposits.

^" Figure 5: Selective separation of fatty acids from an aqueous Al dumpling solution.

Test series / membrane P (mmHg) ^b Protein ^a Protein - _AK FS

 Test series deposition (mmol / 1)

I./Vl FAA-3-PK-130 2 ++ - <0.1

 I./Vl PC 400D-250-250 6 +++ - <0.1

 I./Vl PC 200D-250-250 3 ++ - <0.1

 I./Vl PC1.1 174 +++ ++ 4.3

 I./Vl M5.1 134 +++ +++ 5.9

 I./Vl M5.3 126 +++ +++ 6.2

 I./Vl M5.12 2 - - 15,2

 I./Vl M5.8 3 - - 17.4

 Il./Vl FAA-3-PK-130 6 +++ - <0.1

 Il./Vl PC 400D-250-250 11 +++ - <0.1

 Il./Vl PC 200D-250-250 9 +++ - <0.1

 Il./Vl PC1.1 366 +++ ++ 8.4

 Il./Vl M5.1 310 +++ +++ 12.3

 Il./Vl M5.3 321 +++ +++ 14,1

 Il./Vl M5.12 7 - - 37,8

 Il./Vl M5.8 10 - - 42,2

 I./V2 FAA-3-PK-130 2 ++ - <0.1

 I./V2 PC 400D-250-250 5 ++ - <0.1

 I./V2 PC 200D-250-250 4 ++ - <0.1

 I./V2 PC1.1 156 ++ ++ 5.3

 I./V2 M5.1 101 +++ + 6.4

 I./V2 M5.3 106 +++ + 7.1

 I./V2 M5.12 2 - - 16,2

 I./V2 M5.8 3 - - 19.8

 II./V2 FAA-3-PK-130 7 ++ - <0.1

 II./V2 PC 400D-250-250 11 +++ - <0.1

 II./V2 PC 200D-250-250 10 ++ - <0.1

 II./V2 PC1.1 125 +++ +++ 9.2

 II./V2 M5.1 111 +++ ++ 10.1

 II./V2 M5.3 103 +++ +++ 11.2

 II./V2 M5.12 2 - - 22,6

II./V2 M5.8 2 - - 28.3 ^a P _DK = Maximum pressure measured in the donor chamber during ED; ^b Protein deposition: donor-chamber-side coating with positive protein detection; ^c FS _A K = fatty acid concentration in the acceptor solution after the end of the experiment

Claims

 claims

Open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture consisting of:

 I) an open-porous carrier membrane having pores with a minimum diameter of 50 nm to 500 μιτι and a maximum diameter of 1 μιτι to 3 mm, and

 II) a space-spanning polymeric structural network in the pores of the support membrane.

An open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to claim 1, wherein the space-spanning polymeric structural network consists of vinyl polymers or polyamino acids.

Open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to claim 2, wherein the space-spanning polymeric structural network consists of homopoly-a- amino acids.

An open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to claim 2 or 3, wherein the polyamino acids consist of amino acid monomer units selected from the group consisting of or consisting of proteinogenic amino acids and their derivatives.

An open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to claim 4, wherein the amino acid monomer units are selected from the group consisting of or consisting of alanine, phenylalanine, valine, isoleucine, leucine, proline, Νω-functionalized arginine, O-functionalized serine , Asparagine functionalized on the β-amide moiety, aspartic acid functionalized on the β-carbonyl moiety, glutamic acid functionalized on the γ-carbonyl moiety, glutamine functionalized on the γ-carbonyl moiety, histidine functionalized on the imidazole moiety, O-functionalized threonine, thyptophan functionalized on the indole moiety, S-functionalized cysteine or ε-Ν-functionalized lysine. More preferably, the monomer units of the polyamino acids are selected from the group consisting of or consisting of phenylalanine, valine, isoleucine, leucine, proline, Νω, Ν'ω-dialkyl-arginine, Νω, Νω-dialkyl-arginine, Νω-alkyl-arginine, Νω-carbamate-functionalized-arginine, Νω-carbamate-functionalized, N '-alkyl-arginine, Νω-acyl-arginine, Νω-alkyl, Ν'ω-acyl-arginine, Νω-alkylsulfonyl-arginine , Ω-alkylsulfonyl, ω-alkyl-arginine, β-amide-alkylated asparagine, aspartic acid-β-alkyl ester, glutamic acid-Y-alkyl ester, γ-amide-alkylated glutamine, imidazole-alkylated histidine, O-alkyl-serine, acyl

Sehn, O-alkyl-threonine, O-acyl-threonine, indole-alkylated thryptophan, O-alkyl-tyrosine, S-alkyl-cysteine, ε-Alkyl-alkyl-lysine, ε-Ν, Ν-dialkyl-lysine, ε -Ν-acyl-lysine, ε-Ν-alkyl, ε-Ac-acyl-lysine, ε-Ν-carbamoyl-lysine, ε-Ν-carbamoyl, ε-Ν-alkyl-lysine, ε-Ν-carbamoyl-lysine , ε-Ν-carbamate-functionalized lysine, ε-Ν-alky-N-carbamate-functionalized lysine, ε-Alkyl-alkylsulfonyl-lysine, ε-Ν-

Alkylsulfonyl and ε-Ν-alkyl-lysine.

6. open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to any one of claims 1-5, wherein the membrane is lipophilic and / or the space-spanning polymeric

Structural network is lipophilic.

7. open-pore membrane for electrophoretic separation of carboxylic acids from a liquid mixture according to any one of claims 1-6, wherein the space-spanning polymeric structural network is nanocavitary.

8. open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to any one of claims 1-7, wherein the contact angle for water on the surface of the inner pores, channels or slots of the open-pore membrane is> 70 °.

9. open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to any one of claims 1-8, wherein the open-cell membrane has a selectivity index for carboxylic acids over the corresponding alcohols of> 4.

10. open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to any one of claims 1-9, wherein the open-pore carrier membrane consists of a porous, free-carrying membrane, a fabric or textures or porous materials in a

Composite structure present.

1 1. Open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to any one of claims 1-10, wherein the space-spanning polymeric structure network spans the pores of the open-pore membrane and is not a pure surface coating of the pores of the open-pore membrane. 12. Open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to any one of claims 1- 1 1, wherein the surfaces of the space-spanning, polymeric structural network are functionalized with ionic and / or ionizable compounds. 13. An open-pore membrane for the separation of carboxylic acids from a liquid mixture according to any one of claims 1-12, wherein the surfaces of the space-spanning polymeric structural network are functionalized with amphiphilic compounds. 14. An open-cell membrane for the electrophoretic separation of carboxylic acids from a liquid mixture according to claim 12 or 13, wherein the surfaces of the nanocavity room-spanning polymeric structural network are functionalized with at least one polycationic compound.

15. A process for producing an open-pore membrane according to any one of claims 1 - 1 1 for the electrophoretic separation of carboxylic acids from a liquid mixture, comprising the steps:

 a) providing an open-porous carrier membrane with pores having a minimum diameter of 50 nm to 500 μιτι and a maximum

Diameter of 1 μιτι to 3 mm,

 b) introducing a solution of polymerisable monomers and / or oligomers into the pores of the open-pore carrier membrane from step a),

 c) polymerization of the polymerizable monomers or oligomers in the pores of the open-pore carrier membrane to form a space-spanning polymeric structure network in the pores of the open-pore carrier membrane. 16. The method according to claim 15, wherein the monomers and / or oligomers are room spanning polymerizable.

17. The method according to claim 15 or 16, wherein in step c) the formation of a space-spanning polymeric structural network by ring-opening Polymerization takes place, wherein the solution of the polymerizable monomers and / or oligomers is heated and / or the solution contains a solvent which initiates a ring-opening or radical polymerization.

Method according to one of claims 15-17, wherein in step c) a polycondensation of a thermal melt of the polymerizable monomers and / or oligomers takes place.

A method according to any one of claims 15 to 18, wherein the formation of the space-spanning, polymeric structural network takes place via a multifocal polymer growth.

A method according to any one of claims 15 to 19, wherein the formation of the space-spanning polymeric structural network takes place under static conditions.

A method according to any one of claims 15-20, wherein the solution of the polymerisable monomers and / or oligomers is at least one amino acid and / or at least one oligopeptide in an organic solvent.

A method according to any one of claims 15-21, wherein the polymerisable monomers or units of polymerisable polymers are selected from the group consisting of or consisting of alanine, phenylalanine, valine, isoleucine, leucine, proline, ω-functionalized arginine, O-functionalized serine , Asparagine functionalized on the β-amide moiety, aspartic acid functionalized on the β-carbonyl moiety, glutamic acid functionalized on the γ-carbonyl moiety, glutamine functionalized on the γ-carbonyl moiety, histidine functionalized on the imidazole moiety, O-functionalized threonine, thryptophan functionalized on the indole moiety, S-functionalized cysteine or ε-Ν-functionalized lysine. More preferably, the monomer units of the polyamino acids are selected from the group consisting of or consisting of phenylalanine, valine, isoleucine, leucine, proline, ω, ω'-dialkyl-arginine, ω, ω-dialkyl-arginine, ω-alkyl-arginine, ω Carbamate-functionalized-arginine, N-carbamate-functionalized, N'-alkyl-arginine, ω-acyl-arginine, ω-alkyl, ω'-acyl-arginine, ω-alkylsulfonyl-arginine, ω-alkylsulfonyl, ω Alkyl arginine, β-amide alkylated asparagine, aspartic acid β-alkyl ester, γ-alkyl glutamate, γ-amide-alkylated glutamine, imidazole-alkylated histidine, O-alkyl-serine, O-acyl-serine, O-alkyl - Threonine, O-acyl-threonine, indole-alkylated thryptophan, O-alkyl-tyrosine, S-alkyl-cysteine, ε-Alkyl-alkyl-lysine, ε-Ν, Ν-dialkyl-lysine, ε-Ν-acyl-lysine , ε-Ν-alkyl, ε-Ac-acyl-lysine, ε-Ν-carbamoyl-lysine, ε-Ν-carbamoyl, ε-Ν-alkyl-lysine, ε-Carb-carbamoyl-lysine, ε-Ν-carbamate -functionalized lysine, 8-N-alkyl, 8-N-carbamate-functionalized lysine, ε-Ν-alkylsulfonyl-lysine, ε-Ν-alkylsulfonyl, ε-N-alkyl-lysine and derivatives thereof.

23. The method according to any one of claims 15 - 22, wherein after step c) a step d2) Physiosorptives and / or chemosorptive application of at least one polycationic compound on the surfaces of the polymer structures of the space-spanning polymeric structural network is performed.

24. Open-pore membrane for the electrophoretic separation of carboxylic acids from a liquid mixture obtainable by the process according to one of claims 15 - 23.

25. Use of an open-cell membrane according to any one of claims 1-14 for the electrophoretic separation of carboxylic acids from a liquid mixture.

26. Use according to claim 25, wherein the liquid substance mixture is blood or blood products.