DE19913862C2 - Process for the biocatalyzed conversion of poorly water-soluble substances - Google Patents

Description

The invention relates to a method for the implementation of sparingly soluble in water Compounds in an aqueous environment using a biocatalyst.

The implementation of poorly water-soluble substrates with biological systems is in the simple batch reactor mostly uneconomical, if due to less Water solubility presented only low substrate concentrations and thus low product concentrations can be achieved. This applies equally to one Implementation with a cell-free system, the implementation with pure Enzymes are carried out as for implementation with certain selected cells.

A first improvement provides for the process to be continued with restraint perform the catalyst in the reaction chamber. This execution leads to an improvement in productivity by a corresponding increase in Space-time yield and thereby a reduction in the cost of capital. The However, product concentration in the reaction space remains low. In addition, it may not be necessary to separate the implemented residual substrate from the product.

Therefore, there is a further improvement, usually the reaction system add an organic phase as a second immiscible liquid phase (e.g. DE-A-44 36 149 and DE-A-39 13 367). This organic liquid phase becomes like this chosen that due to the distribution coefficient of the substrate between organic phase and water phase no oversaturation of the aqueous phase can occur in which the reaction takes place. So the organic phase  represents a substrate reservoir. At the same time, this serves as immiscible organic Extraction phase of the product formed in the reaction. By a 'Mixer-settler' arrangement becomes the organic phase after the reaction separated from the aqueous phase with the biocatalyst. In the organic In this phase, high product concentrations can be achieved. The selection the organic phase is of course not free, but is by predefined the solubility behavior of the connection to be implemented.

The use of an organic phase, the ideal distribution coefficient for Enables substrate and product, but often leads to destruction of the biological catalyst in the aqueous phase. Both proteins and intact cells are very sensitive to the presence of non- physiological components in their environment and already relatively small Amounts of organic solvents can denaturate the proteins or cause a decrease in the vitality of the cells. To solve this problem is therefore attempted by using membrane processes to prevent direct contact between the biocatalyst and the organic phase (according to DE-C-35 33 615 and US-A-5,077,217). The provision of a large phase separation area is cumbersome and even separates completely out if the process is to be operated on a larger scale.

Another approach to providing poorly water soluble substrate is that Suspension of the substrate as a microcrystalline solid in aqueous Reaction medium ('microcrystalline solid fermentation'). That during the The reaction product usually also precipitates in the reactor, so that after complete sales, only one solid-liquid and one solid-solid Separation must be done to get the product. This However, the method is not applicable if the product formed Concentrations below the saturation limit for the biocatalyst is toxic and is also not very practical if the reaction inhibits the product entry.  

There is therefore no satisfactory procedure available to get bad in Implement water-soluble compounds using biological aids. A however, such a process is considered very desirable since it is pure chemical implementations, of course, using all available organic solvents can often be performed have the desired reaction selectivity, which z. B. in stereoselective Syntheses can be a major disadvantage. You will also be in such cases where the product of implementation on experimental animals or People should be administered, certainly a manufacturing process, without Prefer to use potentially toxic solvents.

It was the object of the present invention, a method for implementation a first, poorly water-soluble compound (substrate) into a second To provide the compound (product) using biological aids expires and leads to an acceptable yield. The procedure is supposed to be particularly suitable to be used on an industrial scale. In addition, the process is intended to manufacture any product are suitable, z. B. does not matter whether these products more or less are toxic to the biocatalyst.

This object is achieved by the method according to claim 1 solved.

The object is achieved in that a separation of the components of the Procedure is made, the first connection and the Biocatalyst remain in the bioreactor and the second compound from the Bioreactor is excreted, and being the first compound as microcrystalline crystals are present.

The starting point in the method according to the invention is the implementation of poorly water-soluble compounds. There is no limit to solubility to indicate the first compound in water. It is obvious that at Carrying out the process on an industrial scale is already a relative not a slight restriction of the yield due to reduced solubility  Is acceptable, whereas on the laboratory scale such a restriction u. U. can still be tolerated.

The compounds which are poorly soluble in water are not in as a group restricted in any way. All connections come in method according to the invention in principle. Can be in one A range of theoretically conceivable circumstances can be assumed. There is many cases where the pure chemistry to convert a first compound into one certain further connection fails because for some reason the Reaction has too low a yield, or a mixture in the bioreactor of products and / or starting compounds, which can be found under Uses customary methods and cleaning aids. It is especially in the manufacture of a very specific configuration of the Control molecule, such as B. in a stereoselective production, sometimes a insoluble problem to make such a production run satisfactorily. In addition, it should always be noted that a process is needed that also is industrially applicable and therefore not unnecessarily complex and complicated steps.

There is also a practical need for drug metabolites to be able to manufacture. Such metabolites can e.g. B. then be of interest if you look at these metabolites a different therapeutic effect or promises to improve the therapeutic range or if by Use of the metabolites improves absorption in the body of the body Patient can be effected. In addition to these options, where basically the Metabolite itself is to be investigated and developed as a drug there is another need where it is targeted pharmacokinetic and toxicological studies within drug development. Questions about special properties of the metabolites are gradually being asked to the standard package of a drug development and it's a whole special requirements for a development department, the desired ones Provide amounts of metabolites. Such questions in particular  can be much easier in the context of the inventive method and can be taken up with less effort.

The first, poorly water-soluble compound is partially in the bioreactor solid state before. This is logically due to its property poor solubility in water and by the fact that that The inventive method has such an embodiment that a Contact with organic solvents is largely excluded. The Possibility in the bioreactor or in an arrangement assigned to the bioreactor submit a second liquid phase, which has a liquid phase on the The basis of an organic solvent is in the invention Procedure deliberately avoided. However, it is obvious that one Procedure where the first compound is simply added to the bioreactor, leads to less appealing results if only one extremely low concentration is achieved in the aqueous environment. Because of this, looks the inventive method that the first compound in the aqueous Milieu in microcrystalline form. Usually used as microcrystals solid particles referred to, which have a grain size in the range of 1 to 30 microns exhibit. If the first compound in the aqueous medium has a grain size in this range, it is surprisingly observed that the Implementation of the first connection into the second connection is much faster and runs with a greater yield.

The method according to the invention specifically provides that the first is poor in Water-soluble compound microcrystalline in the aqueous medium with the Biocatalyst is suspended. The preparation of such a suspension can be carried out using common methods. An advantageous way of adding of the substrate in a reactor can use a completely with Water miscible solvent in which the first compound is good is solvable. By adding a small pulse of solvent with the dissolved The substrate in an area of maximum turbulence in the reactor becomes water  completely miscible solvents suddenly distributed. That falls before dissolved substrate in the reactor microcrystalline. This encore, which is manual or, according to a preferred embodiment, computer-controlled has proven to be very effective and workable. It contradicts the aim of the method according to the invention, without get along with organic solvents, but it has been shown that the required amount of the organic solvent is small and the abrupt distribution in the watery environment to an extremely low one Concentration of the organic solvent in the aqueous medium leads. Out for this reason, the presence of the organic solvent is not an issue Burden of the procedure. Should nevertheless within the framework of a certain Process for the production of the microcrystalline suspension a larger amount of an incompatible solvent must be known to the person skilled in the art after all, the possibility of initially suspending the microcrystalline first Establish connection and in the second step, i.e. before the biocatalyst is added to remove the organic solvent or at least its Reduce concentration to an acceptable level. Because of this writing However, the process complicates this preferred embodiment of the Process according to the invention at any time before, for the production of the microcrystalline Suspension a solution of the first compound in a compatible Submit solvent.

The implementation of the first poorly water-soluble compound is in Framework of the method according to the invention with a biological system (Biocatalyst). The biocatalyst can be a specific enzyme or a combination of several enzymes. This is mostly simple Embodiment of the method according to the invention without the presence of Whole cells have many practical advantages, but often do not become desired success if it concerns more complicated implementations. A such a biocatalyst can also be a system within the scope of the invention, that includes certain cells. The selection of cells will change according to the Direct question. If the procedure can be carried out with microorganisms is how B. with bacteria, fungi or yeast, there will be many advantages to this Choose variant. However, there is also the consideration of the Carrying out the process of plant cells or cells of animal origin to choose. It has already been mentioned above that an application for Manufacture of metabolites of drugs under the inventive method is obvious. Such manufacture can naturally excellent with the natural metabolizing cells, such as e.g. B. liver cells of humans or animals.

It can also be assumed that the improvement in genetic engineering methods for further possibilities of method according to the invention will perform.

The first compound that is poorly soluble in water is the biocatalyst in implemented a second connection. The type of implementation is within the The method according to the invention is not restricted in any way. It can therefore be any reaction that can be carried out with biocatalysts. Since the method according to the invention has the feature that one in water poorly soluble connection is implemented, the second connection is common be a more polar compound, which is characterized by an oxidative Reaction process has arisen from the first connection. However, there are reactions also conceivable where the second connection has the same polarity as the first compound has and the solubility in water u. May not has changed. It is within the scope of the description of the invention Spoken of a first, sparingly water-soluble compound, which is the starting product in the process and therefore also as a substrate can be designated. This first connection is through the biocatalyst implemented in a second connection. This second connection is the Compound obtained from the bioreactor at the end of the process becomes. It is therefore not necessary for the second connection to be in one single step has arisen from the first connection, it is in many cases even known that the implementation involves a chain of individual steps, the first connection accordingly first into another connection is implemented before the second connection is formed at the end of the process becomes. However, such reactions are also expressly from method according to the invention comprises.

The process according to the invention is carried out in a bioreactor. As Bioreactor are the containers in which biological Reactions are carried out with biocatalysts. Are bioreactors specially designed to provide the necessary optimal conditions for the To implement implementation. Every biocatalyst needs very specific ones Conditions regarding temperature, pH and nutrient concentration and the bioreactor is equipped with such aids to meet these conditions to be able to fulfill optimally. The bioreactor is usually one Mixing system equipped to ensure good mixing of the ingredients ensure with a heat transfer system at the optimal temperature to be able to adjust and with means to supply nutrients and oxygen. It may also be necessary to equip the bioreactor with aids which make it possible to carry out the process in a sterile manner, which in particular in processes that are carried out with whole cell systems, usually one Requirement will be. The selection of the separation process also plays a role in the exact design of the bioreactor.

The process according to the invention is naturally carried out in an aqueous environment be performed. An aqueous environment can contain demineralized water, distilled water, tap water or buffered water, usually however, a nutrient solution will be used within the scope of the invention, the Has water as the liquid phase but has a number of components which are necessary for the optimal functioning of the cells. To maintain a constant productivity of a cell culture will require that Milieu, which contains the cells, a constant composition procure. Doing so is at a pH within a certain small Framework, as well as the permanent presence of sufficient Amounts of raw materials, and it is also necessary to ensure that certain Metabolic products are constantly removed from the milieu. Procedure and The means to maintain constant conditions in the process are Biotechnologists are known and will not be discussed further.

The process according to the invention for biocatalyzed conversion is poor Water-soluble substances are characterized in that the substrate in the aqueous reaction medium is suspended with the biocatalyst and a Separation of the components in the process is made. The first, in water poorly soluble compound and the biocatalyst remain in the bioreactor, while the second compound is excreted from the bioreactor. These Measure represents a surprising improvement of the known methods and leads to considerably higher yields of the second formed Connection. It is not an unknown measure in itself biotechnological processes to remove end products from the reactor, such as e.g. B. in the manufacture of products that themselves have a negative impact have the course of the reaction. In these known methods is the Necessity and advantage of removing the second connection primarily in the property of this second compound, an influence on the reaction in the Exercise reactor. In contrast, the advantage of separating the second compound in the method according to the invention in such Find implementations from an initial, poorly water soluble and go out as microcrystalline crystals present compound.

The separation of the components present in the bioreactor is essential Part of the present invention. A separation of the second connection of the other components in the bioreactor, in particular of the biocatalyst and the first compound. The separation then offers the option of the second connection from the bioreactor to be eliminated. The first compound and the biocatalyst remain in the bioreactor. It goes without saying that this embodiment of the The process is best used in a continuous process to become. The reverse procedure, with the first connection and the biocatalyst is excreted from the bioreactor comes basically also considered, but less suitable for one continuous implementation. The procedure can, however, at any time as one single approach and in the case of experimental projects, which only a one-time establishment of a certain second connection there is also no reason not to use the procedure as the only approach perform, but it is believed that the benefits of The method according to the invention is most likely to be used in one continuous process.

The first compound is eliminated from the bioreactor Concentration kept at a constantly low level, which is for the process the reaction is extremely favorable. It is under a preferred Embodiment provided, the bioreactor with a detection system equip so the concentration of the second compound is constant can be monitored. It is a more preferred embodiment of this Design the acquisition system so that the acquisition is carried out on-line can be and the regulation of the separation is controlled automatically. The on-line registration of the second connection can be carried out arbitrarily, an apparatus-simple procedure is preferred, such as e.g. Legs spectrophotometric detection of the concentration of the second compound. However, more complicated systems are also conceivable and the expert There are a number of measures available in the literature.

The type of separation can be designed as desired. It becomes practical be dependent on how the properties of the second one differ in the special case Connection of those of the first compound and the biocatalyst differentiate. A relatively simple separation can be done if the second compound shows a changed solubility profile in water, where this changed solubility profile in the context of the invention Process will often be an increase in solubility in water. Because the first Compound in water is only present in very small amounts, for the Disconnect the first connection from the second connection Filtration process can be chosen, the filtrate in solution the second Has compound and the surface of the filter medium the dispersed Retains particles of the first compound. Since the procedure is the first Connection as microcrystals, of course, must be sufficient Filtration performance of the filter medium must be observed. Whether in the separation process, especially in a filtration process, the biocatalyst also with the first connection is disconnected depends on whether this also how the first connection can be disconnected. Is the biocatalyst as Microorganism or as cells, so it becomes easy with the first connection be separated from the liquid phase. Even if the biocatalyst is on Enzyme includes, which is not bound to solid particles, but freely dissolved in the aqueous environment, there is no separation by filtration a special method must be selected. Then it must Filter media (membrane) are used that have a separation limit below the Size of the enzymes used, such as ultrafiltration membrane with a corresponding cut-off, in contrast to microfiltration membranes. The same applies if the biocatalyst comprises more than one enzyme.

Filtration is certainly a part of the present invention preferred embodiment for separating the second connection. Filtration processes generally apply in technology and especially in biotechnology is a well known and preferred method and will be seen as the means of choice in many conceivable cases. The filtration can be designed as surface filtration be, however, the formation of a filter cake in the context of a continuous process will often not be an advantage, which is why here cross flow filtration is preferably used, with a flow parallel is generated to the filter surface and no filter cake forms. It puts also represents a preferred embodiment as a filtration principle Use rotary filters.

The design of the bioreactor is based on the selected separation process be strongly influenced. In the case of a configuration as a filtration, the Filtration process usually in a bypass assigned to the bioreactor be performed. In the preferred cross-flow filtration, the aqueous one Suspension past the filter in such a bypass. In contrast, a rotary filter can be used directly in the liquid phase of the bioreactor be installed and the arrangement of the bioreactor will not bypass contain. If the process provides for a rotation process, the bioreactor can itself be designed as a rotatable centrifuge. This arrangement of the Bioreactor also does not contain a bypass.

The separation performance of the solid-liquid separation must be based on the volume flow of the separated aqueous reaction medium with the dissolved product so be set that neither a toxic concentration of the second Connection in the reactor is exceeded, still a precipitation of the product in the Reactor takes place.

A regulation of the volume flow of the separated aqueous Reaction medium with the dissolved second compound can be Measurement of the product concentration in the aqueous reaction medium enables : If a specified limit concentration is exceeded, the Volume flow of the separated aqueous reaction medium increased. At If this is not reached, this volume flow is reduced.

To ensure safe continuous separation of biocatalyst and To achieve microcrystalline substrate, the physical properties on which the selected solid-liquid separation is based, between biocatalyst and be as similar as possible to the substrate.

If cross-flow filtration is used for continuous separation, the particle sizes of the biocatalyst and substrate above the pore size of the membrane used.

Becomes a centrifugal separator, sediment or decanter for continuous Separation used, the sink rates of biocatalyst and substrate must be greater than the required limit sink rate.

The concentrated solids (biocatalyst and substrate) are after the Solid-liquid separation is returned to the suspension reactor.

The separated aqueous reaction medium with the dissolved product is continuously dissipated.

To maintain a desired reaction volume, simultaneously a corresponding volume flow of water for biocatalysis in the Suspension reactor metered, the water optionally nutrients or Co-substrates can be added.

The method according to the invention produces a number of improvements. The method is not only suitable for carrying out the implementation of poorly water-soluble compounds, it will also be possible that Use procedures when a first connection is to be implemented, which has highly toxic properties, which is the result of the application of Microorganisms or cells as a biocatalyst is a major disadvantage. With such a toxic first compound, the problem is not that no higher concentrations can be reached in the aqueous environment, but that such higher concentrations with a view to permanent operation implementation should be avoided.

Another aspect of the method according to the invention is the possibility substrates that are relatively soluble in water before being converted into a difficult to remove Transfer form to retain it crystalline in the reactor. A It is possible to complex substrates that are readily soluble in water Cyclodextrins. Such a complex is hardly soluble in water. The procedure is already used in technology to be toxic in environmental technology To make compounds available for microorganisms (see, for example, A. Schwartz, R. Bar; Appl. Environ. Microbiol. 61: 7 (1995): 2727-2731).  

The possibility offered by the method according to the invention is also simultaneous holding back the biocatalyst and its substrate in the bioreactor is very advantageous. Especially in the context of a continuous process, where it the goal is to carry out a certain implementation over longer periods of time, wherein during the process the excretion of the reaction product it makes no sense to choose a separation method that also causes a separation of the biocatalyst and the first compound because these two components were later brought together again in the process anyway Need to become. To design the process so that it is only separated, what needs to be separated and leaves together, what should stay together, not only corresponds to the logic of the process engineer, but avoids it also any unnecessary waste of effort and resources.

If a toxic second compound is formed during a reaction, the method according to the invention has the great advantage of being simple to be able to separate toxic compound from the bioreactor. It is not Problem to design the process so that the concentration of toxic second connection through an adapted regulation of the separation process, which, as stated above, cleverly through an on-line Monitoring is controlled below a predetermined low value to keep. It is obvious that doing this is extremely useful Possibility can even be applied when both first and second Compound are water-soluble, since it is very advantageous in this case, the first Connection by appropriate preparation as microcrystals in the bioreactor to submit. By adjusting the grain size of the first compound, which in this particularly preferred embodiment are water-soluble can, the easy way of separating the toxic second Connection made in the process in an artificial way.

That the inventive method is also very advantageous avoids the use of an additional organic liquid phase, is now apparent in light of the above description.

This avoidance is beneficial in several ways. Not just one Cost increase due to the purchase of such solvents avoided, in the end another financial consequence is also avoided, when it comes to the disposal of such solvents. Here too it should be noted that already relatively small cost advantages in industrial Scale can be of great importance.

Since the method according to the invention is clever and surprising How different aspects of an implementation process can be combined with the Process a high space-time yield can be achieved.

The following fields of application are suitable for the invention Process to: a biotechnological production of pharmaceuticals in the Pharmaceutical industry, a biotechnological production of fine chemicals in the Chemical industry and a biotechnological production of flavorings in the Food industry.

The invention is illustrated by the following figures:

Fig. 1 shows the schematic diagram illustrates a bioreactor for carrying out the method,

Fig. 2 is the representation of the regioselective oxidation of terfenadine in the stirred reactor.

Fig. 1 shows a bioreactor 1 , which is suitable for performing the method according to the invention. The bioreactor 1 essentially consists of a container made of stainless steel, which is surrounded by a jacket 2 , which has heating or cooling agents to maintain the optimum temperature. The reaction solution 6 , which is an aqueous solution, is located in the bioreactor 1 . The bioreactor 1 is equipped with a line 3 for supplying oxygen or air (or another oxygen-containing gas mixture). A motor 4 drives a stirring means 5 . A feed line 7 leads the first connection to the reactor. If this first connection is desired as microcrystals in the system, the solution of the first compound in an organic solvent is shot into the aqueous solution 6 via this feed line. A further feed line 8 leads to the aqueous solution, which aqueous solution optionally contains cosubstrate or further auxiliaries required in the process. A possibly required correction means can be supplied via yet another supply line 9 . B. can be a chemical to adjust the correct pH. Part of the gas phase can be removed via a line 10 . A bypass is assigned to the bioreactor 1 , which comprises a filter 13 and a line 12 upstream and a line 14 downstream of the filter. A pump 11 is located in line 12 .

Means for determining the concentration of the second compound in the aqueous solution are not shown in the figure. Such means are expediently arranged in line 12 . For automatic control of the method, such means will be integrated in a computer system, also not shown, which controls the action of the pump 11 to regulate the filter output.

If the process according to the invention is carried out in a plant as shown in FIG. 1, the aqueous reaction solution 6 , which contains the aqueous medium, the biocatalyst and the first compound and the second bond, is pumped through the filter 13 by the action of the pump 11 . According to a preferred embodiment of the method, the filter 13 can be a cross-flow microfilter.

A separation is achieved by the filter effect, with a concentrated suspension being in line 14 , which has the first, poorly water-soluble compound and the biocatalyst and the filtrate 15 represents the separated aqueous medium with the dissolved second compound. The concentrated suspension is returned to the bioreactor via line 14 . The filtrate with the dissolved second compound is continuously removed.

In an arrangement not shown, the insulation of the second connection made from the filtrate. This insulation can be done with common means be made. After removing the second connection from the Filtrate can be used again in the process to make a desired Maintain reaction volume. Should not be included in the procedure the filtrate after isolation of the second compound reuse must be ensured by another measure, that the volume remains constant throughout the system.

The method according to the invention is based on an exemplary embodiment are explained. This example concerns the regioselective oxidation of Terfenadine.

example Terfenadine

Terfenadine is an antihistamine, which is due to its Non-sedative effect since its market launch in 1985 to around 1991 dominated the market. Because of its side effects (irregular heartbeat in case of overdose or in certain combinations with others Medicines) has steadily lost market share since 1991 and was at the end 1996 at approx. 18% (Medical Sci. Bull., 1996; 19 (2), 3).

Closer examination of the effects of terfenadine revealed that Liver is oxidized to fexofenadine by cytochrome P450 (CYP3A4) (J.E, Coutant, Journal of Chromatography, 1991; 570,139-148).

Only this oxidation product is pharmacologically active. Of great interest was that the side effects were due to the non-oxidized terfenadine be generated.  

For this reason, the active ingredient fexofenadine in 1998 Prescription antihistamines introduced in Germany to help Bypass side effects of terfenadine.

Various routes have now been published for the synthesis of fexofenadine (S. H. Kawei, Journal of org. Chem., 1994; 59, 2620-2622; S. Patel, Synthetic Communication, 1996; 4699-4710; Schwartz et al., Appl. Microbiol. Biotechnol., 1996; 44, 731-734).

Of obvious interest, however, is a synthesis route that focuses on could build up Terfenadin's existing production capacity and thus only the last step, ie the additional regioselective oxidation carries out. This is not possible in good yields with purely chemical methods feasible.

The possibility of biotransformation with whole cells offers alternatives. This is the basic ability to oxidize terfenadine-like Substances caused by the fungus Cunninghamella blakesleeana by Schwartz et al. (Schwartz et al., Appl. Microbiol. Biotechnol., 1996; 44, 731-734). The reaction scheme shows the conversion of terfenadine I into his Carboxylic acid III over alcohol II.

The aim of the invention was to activate the tertiary To achieve butyl group. A conversion of the starting compound I into the Alcohol II represents a significant improvement because the further implementation of the Alcohol II in the actual fexofenadine - i.e. the carboxylic acid III - without great Problems is feasible.

Reaction conditions

A 1.2 l stirred tank reactor with cross-flow microfiltration (Microdyn MD020TP2N, pore size 0.2 µm, 3 tubes with an inner diameter of 5.5 mm and a length of 0.75 m made of polypropylene, membrane area 0.036 m ² ) in the bypass, which is filled with 1.8 l sterile medium (see tab 1) is filled, is inoculated with a 4-day-old sporulated agar culture after homogenization using an Ultra-Turrax (30,000 rpm, 30 s). The bypass volume flow is set to 2.0 l / min.

Table 1 Minimal medium used

Glucose monohydrate 20.0 g / l (NH ₄ ) ₂ SO ₄ 12.0 g / l KH ₂ PO ₄ 2.8 g / l, MgSO ₄ 7H ₂ O 2.5 g / l CaCl ₂ 2H ₂ O 0.2 g / l Element solution 2.0 ml / l

Element solution

MnCl _2. 4H ₂ O 2.0 g / l ZnSO _4. 7H ₂ O 4.0 g / l CuSO _4. 5H ₂ O 2.0 g / l FeNH ₄ citrate 20.0 g / l Na ₂ MoO ₄ 2H ₂ O 0.03 g / l CoCl _2. 6H ₂ O 0.01 g / l EDTA 5.0 g / l

A reaction temperature of 30 ° C and a pH between 6.5-7.2 is regulated in the reactor. The pO ₂ is regulated with the gassing rate as a manipulated variable (20-1000 ml / min) to 60% (stirrer speed: 1200 rpm). After consumption of the amount of glucose submitted (checked off-line by glucose measurement), 20 g / l of glucose monohydrate are metered in until a total of 60 g / l of glucose monohydrate is reached. Then 6 g / (ld) glycerol are added.

Availability of terfenadine

The solubility of terfenadine is very low (21 mg / l, at pH 7.5 in water). Around to achieve the highest possible conversion rate in the stirred reactor, it must be ensured that at least the solubility limit for each Time in the stirred reactor is reached. Therefore the reaction was called 'Microcrystalline fermentation' carried out: Terfenadine is combined with this Water-miscible organic solvents such as B. methanol, Dimethylformamide (DMF) or dimethyl sulfoxide (DMSO) dissolved and in the Stirred reactor entered. If the solvent is in the aqueous medium distributed, terfenadine crystallizes out. In order to disperse the Educt, and thus to achieve a large solid surface in the reactor, the terfenadine solution was introduced at the point in the stirred reactor highest local energy dissipation.

The addition of terfenadine was automated by defining it under computer control Amounts of an alcoholic terfenadine solution with compressed air pulses (4 bar) in the 'stirred reactor' was 'shot'.

Retention of substrate and biocatalysts through microfiltration in the bypass

At the beginning of the glycerin metering, a filtrate volume flow of 50 ml / h was removed from the stirred reactor with crossflow microfiltration in the bypass (see Fig. 1). The results of a microcrystalline fermentation for the regioselective oxidation of terfenadine in this stirred reactor with cross-flow microfiltration are shown in Fig. 2.

In this Fig. 2, the rectangular symbols represent the real measured values of the concentration of alcohol II in the process, while the circular symbols are fictitious values which represent the concentration of alcohol II in the bioreactor, which theoretically in the bioreactor without separation by filtration would have been realized.

It can be seen that by setting the filtrate volume flow to 50 ml / h Concentration of alcohol II in the reactor limited to about 200 mg / l could. The total amount of product produced exceeds (balanced) 900 mg / l, the microcrystalline fermentation without microfiltration after 200 h maximum amount produced by 50%.

Integrated product separation through selective adsorption

In addition, it is possible to use the alcohol II formed with a Adsorption process (XAD-4 adsorber resin) selectively from the filtrate stream remove and concentrate in one step by a factor of 10 (elution with Methanol, yield: 95%).

Claims (7)

1. A method for converting a first compound (substrate) into a second compound (product) in a bioreactor containing an aqueous medium by means of a biocatalyst, the first compound being a poorly water-soluble compound, and
the components of the process are separated, the first compound and the biocatalyst remaining in the bioreactor and
the second compound is excreted from the bioreactor, characterized in that the first compound is present as microcrystalline crystals. 2. The method of claim 1, wherein the separation of the components is carried out continuously. 3. The method of claim 1 or 2, wherein the biocatalyst Is microorganism. 4. The method according to any one of claims 1 to 3, wherein the separation of the Components are made with a membrane separation process. 5. The method of claim 4, wherein the membrane separation process Cross flow filtration is. 6. The method according to any one of claims 1 to 5, wherein the separation of the second connection regulated by on-line recording of its concentration becomes. 7. The method according to any one of claims 1 to 6 for the implementation of Terfenadine.