WO2017148460A2

WO2017148460A2 - Device and method for structure-controlled electrospinning

Info

Publication number: WO2017148460A2
Application number: PCT/DE2017/000049
Authority: WO
Inventors: Frank Willems; Wolfgang Witt
Original assignee: Bisping Medizintechnik Gmbh
Priority date: 2016-03-01
Filing date: 2017-02-28
Publication date: 2017-09-08
Also published as: DE112017001094A5; WO2017148460A3

Abstract

The invention relates to a device and method for producing a polymer fiber structure by electrospinning comprising: an outlet nozzle (1) for a polymer beam (2); an electrically conductive collector surface (5) which is arranged opposite the outlet nozzle (1), a high voltage being applied therebetween to draw the polymer beam (2) to the collector surface. The device is characterised by a deflection unit (3) which is arranged between the outlet nozzle (1) and the collector surface (5) and about a polymer beam base axis (8) and is designed to deflect the polymer beam (2) by means of at least one electric or magnetic field which is perpendicular thereto in at least one direction, wherein the at least one electric or magnetic field is produced similar to the Braun tube by means of a corresponding deflection voltage (U1, U2); a deflection voltage unit (4) for generating the at least one deflection voltage (U1, U2); and a control unit (9) which controls the deflection voltage unit (4) in order to generate a predefined pattern and the polymer fiber structure with the polymer beam (2) on the collector surface (5).

Description

DEVICE AND METHOD FOR A STRUCTURE-CONTROLLED ELECTRIC SPINNING

The invention relates to an apparatus and method for electrospinning polymer fiber structures.

EP 2185 749 B1 discloses a method and an apparatus for electrospinning polymer fiber structures or nano-fiber structures according to the preamble of claim 1. In this case, a polymer or a polymer solution is forced through an outlet nozzle and pulled from there as a polymer beam on the shortest path to an opposite collector surface, which has an applied high voltage with respect to the outlet nozzle. In this case, the collector surface, such as a plate, on a controllable x-y actuator is adjusted by a control unit according to a pattern. As a result, the polymer fiber structures can be produced and built up according to the predetermined pattern. The disadvantage here is a mechanical effort, acceleration forces for adjusting the collector surface as well as acceleration forces acting on the just emerging polymer fiber structure, which is not yet solidified. If the actuator is to allow both very small displacements in the μιη- range and larger displacements in the mm range, great demands are placed on the actuator.

DE 10 2009 015 226 A1 discloses a method and an apparatus for electrospinning polymer fiber structures, wherein the collector surface comprises a conductive pattern connected to the high voltage unit such that the polymer beam preferably precipitates over the conductive pattern and forms a corresponding polymer fiber structure , The disadvantage here could be that the collector surface also has to be changed and replaced in the case of another pattern or another polymer fiber structure to be produced. EP 2 221 402 A1 discloses a method and a device for the electrospinning of polymer fiber structures, wherein the polymer emerging from the outlet nozzle or the polymer solution immediately after it is further heated by laser light to evaporate.

EP 2 325 361 A1 discloses a method and a device for electrospinning polymer fiber structures, wherein as a polymer which is forced out of the outlet nozzle, a special polymer of two or more polymer threads is used, of which at least one polymer thread is conductive and with the high voltage unit in Connection stands.

Often, adjusting or optimizing parameters in the electrospinning devices is also associated with a change in hardware components of the device, so that changes are limited in time and cost considerations.

Therefore, it is an object of the invention to eliminate the disadvantages of the prior art, in providing a device for electrospinning of 2- and 3-dimensional polymer fiber structures, with the various polymer fiber structures controlled as pure PC and with as few components to be exchanged and possible is made possible cost. If possible, such small structures as in the nm and μιη range should be controllable.

The above objects and other objects to be taken from the description are achieved by a device and a method according to the features of independent claims 1 and 10. Further advantageous embodiments of the invention are specified in the dependent claims.

According to the invention e. An apparatus for producing a 2 and / or 3 diminutive polymer fiber structure by electrospinning, comprising: - an outlet nozzle (1) connected to a reservoir (7) for a polymer or a polymer lymerlösung in order to press it as a polymer beam (2) through the outlet nozzle (1) or press;

- A collector surface (5) (or a substrate), which is electrically conductive and opposite to the outlet nozzle (1) is arranged;

- A high voltage unit (6) which generates a high voltage and between the discharge nozzle (1) and the collector surface (5) applies to pull the polymer beam (2) against the collector surface (5) and solidify there;

a deflection unit (3), which is arranged and formed between the outlet nozzle (1) and the collector surface (5) and around a polymer beam base axis (8), by at least one perpendicular thereto electric or magnetic field in at least one of the polymer beam (2) Distracting direction, wherein the at least one electric or magnetic field as in a Braun tube by a corresponding deflection voltage (U l, U2) is generated and wherein the polymer beam base axis (8) the polymer beam (2) without a deflection by the deflection unit (3) ;

- A deflection voltage unit (4) for generating the at least one deflection voltage (U l, U2); and

- A control unit (9) which controls the deflection voltage unit (4) so that the polymer beam (2) describes a predefined pattern on the collector surface (5) and thereby generates the polymer fiber structure.

Further embodiments can be found in the dependent claims and the description.

In particular, it is advantageous that the polymer beam can be deflected by the deflection unit completely silent and much faster than in a mechanical actuator or as known from the prior art. On collector surfaces also no conductive structures, which should follow the polymer beam, must be applied. Adjustments or optimizations are easily possible PC-controlled by the control unit. The hardware can be used for different types of patterns or Polymer fiber structures remain largely unchanged. This can save both time and money considerably.

A preferred embodiment according to the present invention is illustrated in the following drawings and detailed description, but is not intended to limit the present invention thereto.

Show it

1 is a schematic representation of a preferred apparatus for electrowinning a polymer fiber structure with a polymer jet exit nozzle communicating with a reservoir and a conductive collector surface as a counter electrode, between which a high voltage is applied to draw the polymer beam there wherein a deflection unit, such as a Braun tube, is disposed between the exit nozzle and the collector surface and around the polymer beam to deflect the polymer beam in accordance with deflection voltages.

Fig. 2 is a schematic representation of a device for electrospinning a

Inner coating for tubular substrates, such as a coronary or neurostent, wherein the outlet nozzle is elongated capillary-shaped to be pushed into the substrate, wherein a counter electrode over the substrate, which is pushed onto the outlet nozzle, arranged to an electric Field in between to pull the polymer jet emerging from the exit nozzle to the counter electrode.

Detailed description of an embodiment

FIG. 1 shows a preferred apparatus for producing a 2 and 3 dimensional polymer fiber structure by electrospinning, which comprises the following: summarizes:

- an outlet nozzle (1) which communicates with a reservoir (7) for a polymer or a polymer solution in order to press or press it as a polymer jet (2) through the outlet nozzle (1);

- A collector surface (5) or a substrate which is electrically conductive and opposite to the outlet nozzle (1) is arranged;

marked by

a deflection unit (3), which is arranged and formed between the outlet nozzle (1) and the collector surface (5) and around a polymer beam base axis (8), by at least one perpendicular thereto electric or magnetic field in at least one of the polymer beam (2) Distracting direction, wherein the at least one electric or magnetic field by a corresponding deflection voltage (U l, U2) or an associated deflection current is generated and wherein the polymer beam base axis (8) the polymer beam (2) without a deflection by the deflection unit (3) ;

The preferred deflecting device sketched schematically in FIG. 1 comprises a first deflection unit 3x, which consists of two electrodes which are arranged such that upon application of a first deflection voltage U l a corresponding electric field in the x-direction substantially perpendicular to the polymer beam 2 is generated.

As a result, electrically charged polymer molecules of the polymer beam 2 are deflected in the x direction as a function of the first deflection voltage U l. Analogous is a second deflection unit 3y, which also consists of two electrodes, constructed for an electric field in the y-direction, which is generated by a second deflection voltage U2. The first U 1 and the second deflection voltage U 2 are generated by the deflection voltage unit 4, which are each controlled by the control unit 9. Thus, a predefined pattern of the polymer beam 2 in the xy plane above the collector surface 5 can be easily and precisely controlled. Examples of spatial resolution and spatial extent are television picture tubes. A pattern generation or Bahnerzeugung by the polymer beam 2 over the collector surface 5 can therefore be made correspondingly fine in μπι range and in the mm range and in the cm range. The μπι range is preferably a range of 1 -5μιη or 1 - 1 Ομπι or 1 -100μιη 1 - 1 ΟΟΟμιη. The mm range is preferably a range of 0, 1 - 1 mm or 1-10mm. The cm range is preferably a range of 0, 1-l ern or 1 - 10cm or 1 - 100cm. The deflection unit 3 is preferably constructed as in a Braun image stirring device, in which an electron beam is deflected in a controlled manner instead of the polymer beam 2 and accordingly generates the pattern on an image surface.

Preferably, the deflection unit 3, as in television picture tubes, also be constructed by one or more magnetic coils which generate one or two magnetic fields, which are aligned so as to deflect the polymer beam in the x and / or y direction. The magnetic fields are generated by the corresponding deflection voltages (U l, U2) or the associated currents. For the sake of clarity, a deflection voltage (U 1, U 2) can also be understood here to mean a respective deflection current when magnetic fields are built up.

For clarity, the collector surface 5 is preferably a plate or a roller, whose radius preferably points in the direction of the polymer beam 2, so that the polymer beam 2 preferably strikes the surface of the roller perpendicularly in the undeflected case. The collector surface 5 or plate can be electrically conductive on the surface or below. The collector surface 5 may also be a substrate. The substrate is preferably self-conducting and electrically connected to the high-voltage unit 6, for example via the collector surface 5 or an underlying conductive plate. Preferably, the control unit (9) is adapted to receive the predefined patterns as data or as a signal and convert them into control signals for the deflection voltage unit (4), thereby passing the pattern through the polymer beam (2) on the collector surface (5) of building predetermined paths of the pattern.

Preferably, the deflection unit (3) is configured to generate two electric or magnetic fields which are substantially perpendicular to each other and to the polymer beam base axis (8) to thereby describe the pattern through the polymer beam (2) two-dimensionally parallel to the collector surface (5) , Wherein a perpendicular height of the pattern or the polymer fiber structure is built up by correspondingly repeated sweeping with the polymer beam (2).

Preferably, the collector surface (5) is connected to an actuating unit, which is controlled by the control unit (9) in at least one direction parallel to the collector surface (5) is movable, thereby to produce a larger dimension of the pattern can than by the deflection (3) alone is possible.

Preferably, the collector surface (5) is a rotating roller or substrate on which the polymer fiber structure having the predetermined pattern can be three-dimensionally applied around the roller or the substrate.

In this case, the roller or the substrate is preferably formed by being able to be rejuvenated or pulled inward after the electrospinning to its axis of rotation in order to detach it in this way from the polymer fiber structure inwards.

Preferably, the roller or the substrate is designed as 3D printing.

Preferably, the device has at least one displaceable additional collector surface above the roller or substrate in the direction of the polymer beam base axis (8), which is inserted over a base surface and sidewalls over the base surface and between the sidewalls after construction of a first polymer fiber structure additional collector surface, which is electrically connected to the collector surface (5), to be able to produce a second polymer fiber structure as a kind of roof structure or as a superstructure. The outlet nozzle (1) is preferably coated with gold, platinum, silver and / or with Teflon.

Preferably, the polymer or polymer solution is or comprises granules or filament yarns.

The polymer or the polymer solution is preferably polyurethanes or lactic acid or polylactides.

Preferably, the outlet nozzle (1) is heated in order to be able to press out the polymer or the polymer solution more easily and more homogeneously and to be able to produce the polymer jet.

Preferably, the polymer jet (2) is additionally heated in an area immediately downstream of an exit from the outlet nozzle (1), for example by IR radiation, non-coherent light or by coherent laser light.

Preferably, the environment of the polymer jet (2) between the outlet nozzle (1) and the collector surface (5) is evacuated or corresponds to the ambient pressure or has an overpressure. Preferably, the environment of the polymer jet (2) is filled with a gas or gas mixture, such as helium, nitrogen, another inert gas, a non-inert gas, or a combination thereof.

Preferably, the collector surface (5) has a second pattern as a conductive structure, which is preferably a latticed or diamond-like structure.

Preferably, the collector surface (5) comprises a plurality of individual collector surfaces (5), which are each separately connectable to the high voltage unit (6) via a switching electronics, wherein the control unit (9) is designed to control the switching electronics so that each substantially the individual Collector surface (5) or an area of individual collector surfaces (5) are connected to the high voltage unit (6), which coincide with a desired impact coordinate of the polymer beam (2) on the collector surface (5) or are arranged around it.

Preferably, the device comprises a ventilation device for ventilation over the collector surface (5) and along the polymer fiber structure to remove a solvent that is outgassing over the polymer fiber structure, wherein the ventilation device is preferably configured to generate a gas or gas mixture stream with a purge gas for aeration, wherein the purge gas is preferably air or another gas or a gas mixture which is suitable for removing the solvent as well as possible.

There is also presented a method of making the 2 and 3 dimensional polymer fiber structure by electrospinning performed with the above described apparatus and / or designs. The method comprises the following steps:

Placing the exit nozzle (1) opposite the conductive collector surface (5) or the substrate and applying the voltage therebetween;

- Squeezing the polymer or polymer solution through the outlet nozzle (1) so that it emerges as the polymer jet (2) and is electrostatically drawn against the collector surface (5) or the substrate and solidifies thereon as the polymer fiber structure;

Arranging the deflection unit (3) between the outlet nozzle (1) and the conductive collector surface (5) or the substrate and around the polymer beam base axis (8), wherein the deflection unit (3) is configured to guide the polymer beam (2) through the at least one for deflecting perpendicular electrical or magnetic field in the at least one direction, wherein the at least one electric or magnetic field by a corresponding deflection voltage (U l, U2) or the associated deflection current is generated and wherein the polymer beam base axis (8) the polymer beam (2) without the deflection by the deflection unit (3) corresponds;

- Applying and thus varying the at least one deflection voltage (U 1, U 2) that thereby the polymer beam (2) describes the predetermined pattern on the collector surface (5) so as to form the polymer fiber structure thereon.

Preferably, a deflection unit (3), as known from picture tubes, is used as the deflection unit (3). In this case, preferably the polymer jet (2) in two directions (x, y) perpendicular to the polymer beam base axis (8) deflected by a respective deflection voltage (U l, U2).

Preferably used as the polymers are polymers in association with pharmaceutical products, which pharmaceutical products are sirolimus, paclitaxel or other pharmaceutical products.

The polymers are preferably obtained from at least one polymer solution and / or from a granulate and / or from filament yarns or are composed accordingly.

The method is preferably used for coating and / or producing one or more of the following products, such as: stents, occluders, AV shunts, patches, mashes, vascular prostheses, cartilage prostheses, intervertebral discs, cosmetic implants, nets, hernias, layers for tissue Engineering, flow.

The method is preferably used for coating and / or for producing one or more of the following products: medical implants, cosmetic implants, germ barriers.

Preferably, the process is used to coat and / or manufacture one or more of the following products: filters, dosing devices, gassing films, hoses, membranes.

Preferably, the process is used for coating and / or preparing one or more of the following products: molecular sieves by incorporating zeolites, with or without retention of liquid. The molecular sieves are preferably applicable for an adsorption cooling, such as in a Zeolithkülschrank, for a water filtration and / or for sterilization.

Preferably, the method is used for coating and / or producing fibers or a fabric, such as athletic clothing, workwear, wherein a temperature or humidity can be regulated, for example, by a thermal insulation or a moisture absorption or by a capillary education.

Also provided is an apparatus for internally coating a tubular substrate (10), such as a coronary or plastic core, with a polymer fiber structure by electrospinning, comprising:

an elongated, preferably capillary-type, outlet nozzle (1) communicating with a reservoir (7) for a polymer or polymer solution for feeding the polymer or polymer solution from a front section as a polymer jet (2) through the exit nozzle (1) pressing or pressing, wherein the front portion is adapted to be inserted therein along a longitudinal axis of the substrate;

- A holding means for the substrate (10), which is adapted to hold the substrate (10) over the front portion of the outlet nozzle (1) pushed over it;

- A counter electrode (1 1), which is arranged at a distance from an outlet of the polymer jet (2) from the outlet nozzle (1), wherein the distance is dimensioned so that the substrate in a slid on the outlet nozzle (1) state between the outlet nozzle (1) and the counter electrode (1 1) fits;

- At least one actuating unit (12, 13) which is mechanically connected to the arrangement of the outlet nozzle (1), the counter electrode (1 1) and the substrate (10) and is formed, the outlet nozzle (1) together with the counter electrode ( 1 1) controllably to move relative to the substrate (10) and to twist;

- A high voltage unit (6) which generates a high voltage and between the outlet nozzle (1) and the counter electrode (1 1) applies to pull the polymer beam (2) in the direction of the counter electrode (1 1), which on an inner wall of the Substrate (10), which is pulled over the outlet nozzle (1) is drawn down and solidified;

- A control unit (9) which controls the at least one setting unit (12, 13) and preferably the high voltage unit (6) so that the polymer beam (2) along predefined paths on the inner wall of the substrate (10) can precipitate on it to form the polymer fiber structure. Preferably, the at least one setting unit (12, 13) is formed by making the outlet nozzle (1) controllably displaceable along the longitudinal axis.

Preferably, the at least one setting unit (12, 13) is formed by making the holding means for the substrate (10) controllably rotatable.

Preferably, the at least one setting unit (12, 13) is formed by making the counter electrode (1 1) controllably rotatable about the outlet nozzle (1).

List of reference numbers used:

1 outlet nozzle

2 polymer beam

3 deflection unit

3x first deflection unit in x-direction

3y second deflection unit in the y direction

4 deflection voltage unit

5 collector surface

6 high voltage unit

7 reservoir

8 polymer beam base axis

9 control unit

10 substrate

1 1 counter electrode

12 first actuator

13 second actuator

UO high voltage

U l first deflection voltage in (x-direction)

U2 second deflection voltage (in y-direction)

x, y, z Cartesian coordinates as directions

Claims

claims:

1 . An apparatus for producing a 2 and 3 dimensional polymer fiber structure by electrospinning, comprising:

marked by

a deflection unit (3), which is arranged and formed between the outlet nozzle (1) and the collector surface (5) and around a polymer beam base axis (8), by at least one perpendicular thereto electric or magnetic field in at least one of the polymer beam (2) Divert the direction, wherein the at least one electric or magnetic field is generated by a corresponding deflection voltage (U l, U2) and wherein the polymer beam base axis (8) the polymer beam (2) without a deflection by the deflection unit (3) corresponds;

A device according to claim 1, wherein the control unit (9) is arranged to receive the predefined pattern as data or as a signal and to convert it to control signals for the deflection voltage unit (4) thereby build the pattern through the polymer beam (2) on the collector surface (5) along predetermined paths of the pattern.

A device according to claim 1 or 2, wherein the deflecting unit (3) is adapted to generate two electric or magnetic fields which are substantially perpendicular to each other and to the polymer beam base axis (8), thereby to pattern the polymer beam (2). describe two-dimensional parallel to the collector surface (5), wherein a perpendicular height of the pattern or the polymer fiber structure is constructed by correspondingly repeated sweeping with the polymer beam (2).

4. Device according to one of the preceding claims, wherein the collector surface (5) is connected to an actuating unit, which is controlled by the control unit (9) in at least one direction parallel to the collector surface (5) is movable, thereby a larger dimension of the pattern to be able to generate, as it is possible by the deflection unit (3) alone.

A device according to any preceding claim, wherein the collector surface (5) is a rotating roller or substrate on which the polymer fiber structure having the predetermined pattern can be three-dimensionally applied around the roller or substrate.

A device according to claim 5, wherein the roller or the substrate is formed by being rejuvenable or retractable toward the axis of rotation thereof after electrospinning so as to detach it inwardly from the polymer fiber structure; and or

wherein the roller or the substrate is formed as a 3D print; and / or wherein the device has at least one displaceable additional collector surface above the roller or the substrate in the direction of the polymer beam base axis (8), which comprises a first polymer fiber structure having a base surface and sidewalls over the base surface and between the side walls is inserted to on the additional collector surface, which is electrically connected to the collector surface (5), to be able to produce a second polymer fiber structure as a kind of roof structure or as a superstructure.

7. Device according to one of the preceding claims, wherein the outlet nozzle (1) is coated with gold, platinum, silver and / or with Teflon; and / or wherein the polymer or polymer solution is or comprises granules or filament yarns; and or

wherein the polymer or polymer solution is polyurethanes or lactic acid or polylactides; and or

wherein the outlet nozzle (1) is heated; and or

wherein the polymer beam (2) is additionally heated in an area immediately behind an exit from the outlet nozzle (1) by IR radiation, non-coherent light or coherent laser light; and or

wherein the environment of the polymer jet (2) between the outlet nozzle (1) and the collector surface (5) is evacuated, corresponds to the ambient pressure or has an overpressure; and / or filled with a gas or gas mixture containing helium, nitrogen, another inert gas or a non-inert gas or a combination thereof; and or

- Wherein the collector surface (5) has a second pattern as a conductive structure, which is preferably a lattice-shaped or diamond-like structure.

8. Device according to one of the preceding claims, wherein the collector surface (5) comprises a plurality of individual collector surfaces (5) which are each separately connected to the high voltage unit (6) via a switching electronics, wherein the control unit (9) is formed, the switching electronics in such a way that in each case essentially the individual collector surface (5) or an area of individual collector surfaces (5) is connected to the high-voltage unit (6) which are coincident with or arranged around a desired incidence coordinate of the polymer beam (2) on the collector surface (5).

Apparatus according to any one of the preceding claims, further comprising an aeration device for venting above the collector surface (5) and along the polymer fiber structure to carry away a solvent that is outgassing over the polymer fiber structure, the venting device being preferably configured to form a gas or gas mixture stream to produce with a purge gas for aeration, wherein the purge gas is preferably air or another gas or a gas mixture which is suitable to remove the solvent as well as possible.

A method of making a 2 and 3 dimensional polymer fiber structure by electrospinning with a device according to any one of the preceding claims comprising the steps of:

Placing an exit nozzle (1) opposite a conductive collector surface (5) or a substrate and applying a voltage therebetween;

- Squeezing a polymer or a polymer solution through the outlet nozzle (1) so that it emerges as a polymer jet (2) and is electrostatically drawn against the collector surface (5) or the substrate and solidifies thereon as the polymer fiber structure;

marked by

Arranging a deflection unit (3) between the outlet nozzle (1) and the conductive collector surface (5) or the substrate and around the polymer beam base axis (8), wherein the deflection unit (3) is formed by at least one of the polymer beam (2) deflect the vertical electric or magnetic field in at least one direction, wherein the at least one electric or magnetic field is generated by a corresponding deflection voltage (U l, U2) and wherein the polymer beam base axis (8) the polymer beam (2) without a deflection by the deflection unit ( 3) corresponds; - Applying and thus varying the at least one deflection voltage (U 1, U2) that thereby the polymer beam (2) describes a predetermined pattern on the collector surface (5) so as to form the polymer fiber structure thereon.

1 1. A method according to claim 10, wherein the deflection unit (3) is a deflection unit (3) as known from kinescopes, and wherein the polymer beam (2) is in two directions (x, y) perpendicular to the polymer beam base axis (8). is deflected by a respective deflection voltage (U l, U2).

12. A method according to claim 10 or 11, wherein as the polymers, polymers are used in conjunction with pharmaceutical products, wherein the pharmaceutical products are sirolimus, paclitaxel or other pharmaceutical products; and or

wherein the polymers are obtained from at least one polymer solution and / or from a granulate and / or from filament yarns.

13. The method according to one or more of the preceding claims 10- 12, wherein the method for coating and / or manufacturing of one or more of the following products is used, such as stents, occluders, AV shunts, patches, Mashes of vascular prostheses, cartilage prostheses, intervertebral discs, cosmetic implants, nets, hernias, layers for tissue engineering, flow.

14. The method according to one or more of the preceding claims 10-13, wherein the method is used for coating and / or for the production of one or more of the following products, medical implants, cosmetic implants, germ barriers.

1 5. The method according to one or more of the preceding claims 10-14, wherein the method for coating and / or for the production of one or several of the following products: filters, dosing devices, gassing membranes, hoses, membranes.

A process according to one or more of the preceding claims 10-15, wherein the process is used for coating and / or preparing one or more of the following products, molecular sieves, by incorporating zeolites, with or without liquid storage for an adsorption cooling, such as in a zeolite, for a water filtration and / or for sterilization.

17. Method according to one or more of the preceding claims 10-16, wherein the method is used for coating and / or manufacturing of fibers or a fabric, such as for athletic clothing, for protective workwear, wherein a temperature or humidity can be regulated, for example, by a thermal insulation or a moisture absorption or by a capillary education.

An apparatus for internally coating a tubular substrate (10), such as a coronary or neurostent, with a polymeric fiber structure by electrospinning, comprising:

- A counter electrode (1 1), which is arranged at a distance from an outlet of the polymer jet (2) from the outlet nozzle (1), wherein the distance is dimensioned so that the substrate in a on the outlet nozzle (1) slipped state between the outlet nozzle (1) and the counter electrode (1 1) fits;

- At least one actuating unit (12, 1 3), which is mechanically connected to the arrangement of the outlet nozzle (1), the counter electrode (1 1) and the substrate (10) and is formed, the outlet nozzle (1) together with the counter electrode (1 1) controllably to move and twist relative to the substrate (10);

- A control unit (9) which controls the at least one setting unit (12, 13) and preferably the high voltage unit (6) so that the polymer beam (2) along predefined paths on the inner wall of the substrate (10) can precipitate on it to form the polymer fiber structure.

19. The device according to claim 18, wherein the at least one actuating unit

(12.1 3) is formed by controllably displaceable the outlet nozzle (1) along the longitudinal axis; and or

- makes the holding means for the substrate (10) controllably rotatable; and or

- makes the counter electrode (1 1) controllably rotatable about the outlet nozzle (1).