GB2617100A - Implantable bioelectronic device and method of using same - Google Patents

Abstract

An implantable bioelectronic device comprises a flexible base material (102) having a top layer and a bottom layer opposite thereto, the flexible base material comprising at least one electrode (104) and a plurality of holes (106); a biological sample seeded on the top layer; and a biodegradable hydrogel. The biological sample can be human induced pluripotent stem cell (iPSC) derived cells that can be differentiated into desired cell types including neurons. The implantable bioelectronic device, when in use in-vitro, enables the biological sample to grow on the top layer prior to a coating with the biodegradable hydrogel, and wherein the implantable bioelectronic device, when in use in-vivo, enables connecting a first element (114, fig 1F) and a second element (116, fig 1F) for restoration of an interrupted biological function therebetween. The first element can be an electrically active cell such as a living nerve, or a damaged nerve's distal or proximal end. The second element can be an electrically active cell, a muscle tissue or an electrical component such as a prosthetic limb, a prosthetic arm, a prosthetic foot, a prosthetic ear, etc.

Description

IMPLANTABLE BIOELECTRONIC DEVICE AND METHOD OF USING SAME TECHNICAL FIELD

This invention relates to medicament dispensers for bioelectronic devices. In particular, 5 though not exclusively, this invention relates to an implantable bioelectronic device and to a method of using the implantable bioelectronic device.

BACKGROUND

Neurological disability affects over 1.3 billion people worldwide, imposing significant health, economic and social burden. A major hurdle in reversing the effect of injury to the nervous system is the inherent inability of neurons to regenerate and to re-build disrupted neural circuits. Moreover, due to the aforementioned inability of the neurons, the neurons also fail to restore a lost neurological function in a peripheral neural system.

In this regard, implantable neurotechnology (including neural interfaces such as neuroprosthesis) and cell therapy (including cell transplantation) are rapidly developing as potential effective treatments to restore the lost neurological (biological) function. Notably, the neuroprosthesis aims to bypass the site of injury with implantable electronic devices by connecting directly one part of the nervous system to another (or a prosthetic limb); and the cell transplantation aims to repair the injury site. Conventional implantable electronic devices include, but may not be limited to, epineural cuff electrodes, Utah electrode arrays, flat interface nerve electrode (FINE), Longitudinally implanted interfascicular electrodes (LIFE), Transversal interfascicular multichannel electrodes (TIME), Regenerative sieve electrodes, and Regenerative microchannel electrodes, that are translated into clinics. However, the conventional neural interfaces only provide symptom-management strategies to progressive diseases, such as that of the nervous system, but translation into the clinic remains limited due to their limited long-term reliability. Moreover, the implantable electronic devices alone lack selectivity and specificity of subpopulations of neurons to record or elicit action potentials to or from the damaged neurons due to an imperfect interface between the implanted electronic device and native tissues. Furthermore, both strategies alone have shown limited efficacy due to several challenges, such as lack of cell guidance (that results in a struggle to re-establish functional connections in existing circuits) and survival after implantation and a foreign body reaction (FBR) that generates a dense scar tissue (or collagen layer) around the electronic interface, preventing the electronic signals reaching the target nerve tissue thereby impairing working thereof. Consequently, the electronic device needs to be replaced with a new one until the FBR process repeats itself. Additionally, Wallerian degeneration is also an issue in amputee patients where the damaged peripheral nerve fibres at proximal stump die back up towards the torso of the subject. In such cases, even if an electronic device is implanted at the proximal nerve stump, the living nerves continue to die moving further away from the bioelectronic device deeming it useless over time.

There remains a need for improved implantable devices that can enhance the functional neurological restoration. It is an object of the invention to address at least one of the above 5 problems, or another problem associated with the prior art.

SUMMARY OF THE INVENTION

A first aspect of the invention provides an implantable bioelectronic device, the implantable bioelectronic device comprising a flexible base material having a top layer and a bottom layer opposite the top layer, the flexible base material comprising at least one electrode and a plurality of holes; a biological sample seeded on the top layer of the flexible base material; and a biodegradable hydrogel, wherein the implantable bioelectronic device, when in use in-vitro, enables the biological sample to grow on the top layer of the flexible base material prior to a coating thereof with the biodegradable hydrogel, and wherein the implantable bioelectronic device, when in use in-vivo, enables connecting a first element and a second element for restoration of an interrupted biological function between the first and second elements.

It has been found that such an arrangement may advantageously provide for a combinational biohybrid approach of implantable electronics and living cells for functional neurological restoration could address these issues. In particular, such an arrangement has been found to advantageously allow for a 'controllable' synaptic integration between implanted cells and existing circuitry. In this regard, flexible devices are combined with various soft materials with stem cell-supportive capacity to enables connecting bioelectronics to human physiology, and also regenerating human physiology with medical devices. In essence, such an arrangement is way of 'plug into' the nervous system that serves as a living interface that allows connection of living nerves at one end, to electrical components at another in a subject at a desired location, such as, for example, a human nerve injury or an animal (such as a rat) nerve injury model. Attributes to such a biohybrid implant are: an ability to host and interact with human stem-cell derived cells; promotion of organised functional cellular integration with living tissue; reduction of scar tissue (FBR) formation; and restoration of any lost biological function.

This technology aims to shift this paradigm to move towards curative solutions by combining latest technology in tissue engineering and flexible bioelectronics. Additionally, the disclosed implantable bioelectronic device may allow a biohybrid bridge to link severed human nerves to a smart prosthetic device that allows intuitive control close to that of a natural hand. Moreover, it has been found that in such an arrangement, it may be possible to modify the geometry of the implantable bioelectronic device and the type of biological sample to be grown thereon independently based on the subject and the desired location. Beneficially, the implantable bioelectronic device provides improved electrophysiology recordings from the implantable bioelectronic device compared to conventional thin film electronics alone. Additionally, the disclosed implantable bioelectronic device allows for chronic implantations and survival of the human-based biological sample inside for example a rat subject.

Suitably, the flexible base material is a thin film biohybrid that mimics the stiffness of the 5 host nerve. Herein the top layer lays on top of the bottom layer of a planar thin film, and the top layer serves as an electrically active surface that comprises the electronic circuit of the implantable bioelectronic device. Optionally, the electronic circuit comprises at least one electrodes and insulators. Beneficially, plurality of electrodes may be used for highly selectivity. Optionally, the at least one electrode is a gold electrode. Optionally, each electrode 10 has an area of 50timx5Otim with 400itm spacing between adjacent electrodes on the flexible base material. Suitably, the at least one electrode is coated with poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) conducting polymer.

Suitably, the plurality of holes are configured for potential vasculature penetration through the implantable bioelectronic device to restore an impaired or lost biological function by allowing intuitive control to mimic natural control mechanism of body. Moreover, the vascularisation allows for diffusion of nutrients, oxygen perfusion and waste products removal to aid implanted cell survival. Optionally, the impaired or lost biological function may be an impaired signal transduction. Optionally, the each of the plurality of holes occupies an area in a range of 50itm to 200iim and surround the at least one electrode.

Optionally, the biological sample may be human induced pluripotent stem cell (iPSC) derived cells that can be differentiated into desired cell types including neurons. Beneficially, by seeding the biological sample on the implantable bioelectronic device, the subject's immune system is not adversely reactive towards the implantable bioelectronic device thereby avoiding the FBR formation at implantation sites.

Suitably, the biodegradable hydrogel is configured for coating the biological sample on the flexible base material. Beneficially, the biodegradable hydrogel protects the structure and function of the biological sample upon implantation of the implantable bioelectronic device into the subject. Additionally, beneficially, the biological sample and the biodegradable hydrogel layers improve the overall biocompatibility of the implantable bioelectronic device.

It will be appreciated that when in use in-vivo, the implantable bioelectronic device may be interfaced with a damaged nerve tissue, or at least partially transected host nerve and/or a nervous system tissue. In this regard, the implantable bioelectronic device may be interfaced with the nervous system tissue such as a nerve, the brain or the spinal cord.

In some embodiments, the flexible base material may further comprise at least one of: a chip, 35 at least one sensor (such as a biosensor, an optical sensor, a chemical sensor, and so on), at least one stimulator (such as an optical stimulator, a chemical stimulator, and so on).

In some embodiments, the restoration of the interrupted biological function between the first element and the second element is recorded as a stimulation data by the implantable bioelectronic device. Herein, the stimulation data are action potentials resulting from the host nerves in their native state or upon restoration of the interrupted biological function. It will be appreciated that the implantable bioelectronic device enable efficient electrical recording in-vivo. It will be appreciated that the stimulation is not always needed, it is needed only for the initial in-vivo characterisation of the implantable bioelectronic device. Notably, herein, the implantable bioelectronic device acts as a recording device. However, in the future this technology could also be used to stimulate host nerve or brain tissue and/or record the same with or without stimulation. It will be appreciated that in freely moving subjects there is no need to send a stimulation and then record the stimulation data. In the freely moving subject, the implantable bioelectronic device can just record live action potentials from the said subject.

In some embodiments, the electrical stimulation is provided as a pulse of an activation threshold ranging from 10 to 200 microampere using a pre-defined duration pulse. Notably, the nerves have a lower activation threshold. Optionally, the pulse may be of 100 microampere (pA). It will be appreciated that the pulses are optimised for different subjects, such as a rat, a human, and so on.

In some embodiments, number of electrodes is at least two, and wherein the at least two electrodes are arranged in a symmetrical array occupying an area in a range of 1.0 x 1.0 millimetre to 10 x 10 millimetre within the flexible base material. Optionally, the area of the at least two electrodes, such as multielectrode array (MEA) may be equal or more than the diameter of the nerve bundle (i.e. 1 mm) to allow higher selectivity of the implantable bioelectronic device. Notably, the area of the implantable bioelectronic device will vary depending on the nerve that the implantable bioelectronic device is interfaced with. Optionally, the at least two electrodes are arranged in a symmetrical array occupying an area of 2 millimetre (mm) x 2 mm. However, it will be appreciated that such area may be optimized for different subjects, such as a rat, a human, and so on. Notably, an area of 2 mm x 2 mm may be specific to the rat sciatic nerve but can easily be adapted to different nerve sizes, i.e. would need to be made larger or smaller for human nerves.

Suitably, the at least one electrode may be implemented as multiple independent electrodes for high selectivity. Optionally, the at least one electrode may be 32 in number and may be arranged in an array.

In some embodiments, the flexible base material comprises a polymer layer, selected from a parylene derivative, deposited on a flexible wafer, selected from a silicon, a glass, Or polymers.

In some embodiments, the biological sample is selected from pre-differentiated human induced pluripotent stem cells (PSC) derived cells.

In some embodiments, the first element is an electrically active cell and the second element is selected from an electrically active cell, a muscle tissue and an electrical component. 5 Optionally, the first element may be a living nerve, or a damaged nerve's distal or proximal end. Optionally, the second element may be a muscle cell or an electronic component such as a prosthetic limb, a prosthetic arm, a prosthetic foot, a prosthetic ear, and so forth. It will be appreciated that a lost (or impaired or interrupted) biological function between the first element and the second element may be restored using the implantable bioelectronic device 10 therebetween.

In some embodiments, the implantable bioelectronic device further comprises a processing arrangement for processing and analysing the recorded stimulation data; a memory unit; a transmitter that can translate the stimulation data, and a battery unit. Optionally, the transmitter is a short-range RE transmitter. Optionally, the battery unit is a small internal battery, such as a coin battery. Optionally, the implantable bioelectronic device may comprise a sensor arrangement, an amplifier, and so on.

A second aspect of the invention provides a method of using an implantable bioelectronic device, the method comprising performing an in-vitro activity for cell culture on the implantable bioelectronic device, the in-vitro activity comprising obtaining the implantable bioelectronic device, seeding a biological sample on top of the implantable bioelectronic device and allowing the biological sample to grow for a pre-defined time, coating a biodegradable hydrogel on the coated layer of the biological sample; and performing an in-vivo activity comprising implanting the implantable bioelectronic device having the biological sample and the biodegradable hydrogel thereon into a subject at a desired location, wherein the implantation of the implantable bioelectronic device enables connecting a first element and a second element for restoration of an interrupted biological function between the first and second elements.

Suitably, the pre-defined time of growth of a biological sample in-vitro is dependent on a specific cell culture. Notably, different cell types have different culture times to reach a desired growth. It will be appreciated that, in this regard, the biological sample is adhered onto the flexible base material prior coated with a layer of proteins. Moreover, a temporary set-up may be designed to enable culturing of the biological sample on the implantable bioelectronic device before the delicate removal thereof and subsequent implantation thereof into the subject. The temporary set-up may host the implantable bioelectronic device for 10- 30 days whilst performing human cell culture. The temporary set-up may host the implantable bioelectronic device for 10 days whilst performing human cell culture, such as human iPSC derived myocytes, thereon. It will be appreciated that the time period for hosting (namely, hosting period) the implantable bioelectronic device in the temporary set-up may vary based on the cell type desired to be cultured on the implantable bioelectronic device. In this regard, optionally, the temporary set-up may be of cell culture plates comprising polydimethylsiloxane (PDMS). Optionally, the temporary set-up may be implemented as a PDMS well and is removed before surgical implantation of the implantable bioelectronic device.

Optionally, the desired location of implantation of the implantable bioelectronic device in the subject may be a sensorimotor nerve. Optionally, desired location of implantation of the implantable bioelectronic device in the subject may be the brain.

In some embodiments, the implantable bioelectronic device is according to the aforementioned implantable bioelectronic device.

In some embodiments, the implantable bioelectronic device is implanted in the subject such that a bottom layer of the implantable bioelectronic device is laid against a first part of the subject's body and a top layer having the biological sample and the biodegradable hydrogel thereon faces an electrically active cell proximal to the first part of the subject's body. In an example, the implantation is done into the proximal nerve stump, in such case, the implantable bioelectronic device is laid on the dermis of the subject's body and the top layer having the biological sample and the biodegradable hydrogel thereon faces the electrically active cell, such as the nerve tissue. In another example, the implantation is done into the distal nerve stump, in such case, the implantable bioelectronic device is laid between a severed nerve, or on the surface of the brain.

In some embodiments, the method further comprises recording a stimulation data, in-vivo, by the implantable bioelectronic device. In some embodiments, the method may comprise providing an electrical stimulation by the implantable bioelectronic device.

In some embodiments, the electrical stimulation is provided as a pulse of an activation threshold ranging from 10 to 200 microampere using a pre-defined duration pulse.

In some embodiments, number of electrodes is at least two, and wherein the at least two electrodes are arranged in a symmetrical array occupying an area in a range of 1.0 x 1.0 millimetre to 10 x 10 millimetre within the flexible base material. It will be appreciated that thousands of electrodes may be arranged to occupy an area of for example 0.5 x 0.5 centimetre when for example the brain is the target area.

In some embodiments, the method further comprises processing and analysing, using a processing arrangement, the recorded stimulation data; storing, in a memory unit, the recorded stimulation data; translating, using a transmitter, the recorded stimulation data, 35 and powering, using a battery unit, the implantable bioelectronic device.

In some embodiments, the method further comprises preparing the implantable bioelectronic device using at least one of: a photolithography technique, printing technique, a metal lift-off technique. Optionally, the printing technique is a three-dimensional bioprinting.

A third aspect of the invention provides a computer program product comprising a non-5 transitory machine-readable data storage medium having stored thereon program instructions that, when accessed by a processing arrangement, cause the processing arrangement to carry out the aforementioned method.

Throughout the description and claims of this specification, the words "comprise" and "contain" and variations of the words, for example "comprising" and "comprises", mean "including but not limited to", and do not exclude other components, integers or steps. Moreover, the singular encompasses the plural unless the context otherwise requires: in particular, where the indefinite article is used, the specification is to be understood as contemplating plurality as well as singularity, unless the context requires otherwise.

Preferred features of each aspect of the invention may be as described in connection with any of the other aspects. Within the scope of this application it is expressly intended that the various aspects, embodiments, examples and alternatives set out in the preceding paragraphs, in the claims and/or in the following description and drawings, and in particular the individual features thereof, may be taken independently or in any combination. That is, all embodiments and/or features of any embodiment can be combined in any way and/or combination, unless such features are incompatible.

BRIEF DESCRIPTION OF THE DRAWINGS

One or more embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which: Figure 1A is an illustration of an implantable bioelectronic device, in accordance with an embodiment of the invention; Figures 1B and 1C are enlarged views of the implantable bioelectronic device of Figure 1A; Figure 1D is an illustration of preparation of the implantable bioelectronic device of Figure 1A for cell culture; Figure 1E is graphical representation of impedance for a control device and the implanted implantable bioelectronic device of Figure 1A at different weeks of implantation; Figure 1F is an illustration of an experimental timeline showing transfer of the implantable bioelectronic device of Figure 1A from an in-vitro step to an in-vivo step; Figures 2A and 2B are illustrations of implantation of a control device and the implantable bioelectronic device of Figure 1A, respectively, in accordance with an embodiment of the invention; Figures 2C and 2D are graphical representations of biological sample stain intensity with respect to a distance thereof from the implantation site and in control device and the implantable bioelectronic device of Figure 1A, respectively; Figure 3 is a schematic illustration of an implantation of an implantable bioelectronic device, in accordance with an embodiment of the invention; Figure 4A are representations of a response of a stimulated nerve of the implantable bioelectronic device and a control device in comparison to a naive nerve hook electrode; Figure 4B is a representation of an average peak-to-peak compound action potential (CAP) amplitude recorded by the at least one electrode of the implantable bioelectronic device, the control device and the naïve nerve hook electrode of Figure 4A; Figure 4C is a graphical representation of peak-to-peak compound action potential (CAP) amplitude recorded by the 28-day implanted implantable bioelectronic device and the control device of Figure 4A; Figures 5A and 5B are graphical representations of nerve signal traces recorded by the chronically implantable bioelectronic device of Figure 4A over 4 weeks post-implantation and a signal-to-noise ratio (SNR) of the recorded traces, respectively; Figure 6A is a graphical representation of root mean square (RMS) time traces from three bipolar electrodes recorded by the implantable bioelectronic device of Figure 4A over 4 weeks post-implantation; Figure 6B is a graphical representation of quantification of correlation between the recorded RMS time traces of Figure 6A and stepping events; Figure 6C is a representation of time-frequency spectrogram and time trace of a recording from a bipolar electrode of Figure 6A at week 4 post-implantation; Figure 7 is an illustration of biological sample survival 7 days post-implantation of the implantable bioelectronic device; Figure 8 is a graphical representation of a cell nuclei stain intensity over a distance from 28 day-implanted implantable bioelectronic device and a control device; Figure 9 is a graphical representation of peak-to-peak compound action potential (CAP) amplitude recorded by the 28-day implanted implantable bioelectronic device of Figure 1A and a control device for 0.1 ms pulses of a range of amplitudes; Figure 10 is graphical representation of quantification of impedance of the implanted implantable bioelectronic device of Figure 1A over 4 weeks of implantation; Figure 11 is a schematic illustration of a step-by-step process involved in culturing biological sample onto the implantable bioelectronic device, in accordance with an embodiment of the invention; and Figure 12 is a flowchart of steps of a method of using an implantable bioelectronic device, in accordance with an embodiment of the invention.

DETAILED DESCRIPTION

Referring to Figure 1A is an illustration of an implantable bioelectronic device 100, in accordance with an embodiment of the invention. The implantable bioelectronic device 100 comprises a flexible base material 102 having a top layer 102A and a bottom layer 102B opposite the top layer 102A, the flexible base material 102 comprising at least one electrode 104 and a plurality of holes 106; a biological sample (not shown) seeded on the top layer 102A of the flexible base material 102; and a biodegradable hydrogel (not shown), wherein the implantable bioelectronic device 100, when in use in-vitro, enables the biological sample to grow on the top layer 102A of the flexible base material 102 prior to a coating thereof with the biodegradable hydrogel, and wherein the implantable bioelectronic device 100, when in use in-vivo, enables connecting a first element 114 and a second element 116 for restoration of an interrupted biological function between the first element 114 and second element 116. It may be appreciated that the top layer 102A and the bottom layer 102B are two faces of the flexible base material 102. The bottom layer 102B refers to a side of the flexible base material 102 on top of which lies the top layer 102A that comprises multiple electrodes, such as the electrode 104 and plurality of holes 106, as shown along with the biological sample and the biodegradable hydrogel. Notably, the bottom layer 102B is a side that may be placed against a part of body of the subject for the biological sample, occupying the opposite top layer 102A on the implantable bioelectronic device 100, to interact with the damaged nerves/tissue of the subject and restore interrupted biological function. Notably, the top layer 102A and the bottom layer 102B are fabricated from for example a parylene derivative and gold, while the bottom layer 102B lacks the biological sample and the biodegradable hydrogel that are only present on the top layer 102A.

Figures 1B and 1C are enlarged views of the implantable bioelectronic device 100 of Figure 1A. Here brightfield images show biological sample 108 (human iPSC derived myocytes) at Day 8 of culture as viewed under scale bars of 465 pm (Figure 1B) and 230 pm (Figure 1C), respectively.

Figure 1D is an illustration of preparation of the implantable bioelectronic device 100 of Figure 1A for cell culture. As shown, the biodegradable hydrogel 110 coats over the cultured biological sample 108 (human iPSC derived myocytes). Upon cell culture, the implantable bioelectronic device 100 is removed from the cell culture plate 112 comprising polydimethylsiloxane (PDMS) wells 112A, and implanted into a subject at a desired location (such as a rat peripheral nerve).

Figure 1E is graphical representation of impedance for a control device and the implanted implantable bioelectronic device 100 of Figure 1A at different weeks of implantation. As shown, over 4-week period post-implantation, impedance increases for the functional electrodes 104 of the implantable bioelectronic device 100 comprising biological sample cultured thereon at 1000 Hz every week over 4-week period post-implantation. As shown, impedance is highest at the week 4. A control device that lacks the biological sample 108 cultured thereon shows no impedance.

Figure 1F is an illustration of an experimental timeline showing transfer of the implantable bioelectronic device 100 of Figure 1A from an in-vitro step to an in-vivo step. As shown, the biological samples 108 are seeded onto the implantable bioelectronic device 100 at day zero.

Herein, the biological sample 108 is human muscle cells (or myocytes). After 48hrs (Day 2) the differentiation process is initiated. At Day 8 the muscle cells mature into myotubes, therefore between Day 8-10 is optimal timing for the implantation of the implantable bioelectronic device 100 into a subject, such as a peripheral nerve rat model. The implantable bioelectronic device 100 is then implanted for a period of 4 weeks. During this 4-week period, live chronic and acute electrophysiology recordings are performed on the subject. As shown, during implantation, the cell-laden side of the implantable bioelectronic device 100 is transferred a few centimetres towards the midline of the subject and anchored subcutaneously to support cell survival for at least seven days after implantation and to further be receptive to axon growth and innervation.

It will be appreciated that the term "implantable bioelectronic device" refers to a biohybrid device that comprises cells, such as human-derived cells, for example myocytes, combined with (such as by way of seeding thereon) an implantable electronic device, and the term "control device" refers to an implantable electronic device lacking cells, i.e. no human-derived cells, such as myocytes are seeded on the control device.

Figures 2A and 2B are illustrations of implantation of a control device and the implantable bioelectronic device 100 of Figure 1A, respectively, in accordance with an embodiment of the invention. As shown in Figure 2B, 28-day post-implantation, the implantable bioelectronic device 100 survival of human iPSC derived muscle cells 202 to restore lost biological function in the subject. However, the control device shows no restoration of lost biological function due to lack of biological sample thereon. Grey traces depict human iPSC derived muscle cells 202 and Black traces depict host cells 204.

Figures 2C and 2D are graphical representations of biological sample stain intensity with respect to a distance thereof from the implantation site and in control device and the implantable bioelectronic device 100 of Figure 1A, respectively. As shown in Figure 2C, the human nucleoli stain intensity (ratio to background) for the implantable bioelectronic device 100 (dashed line) decreases over distance from the implant while the human nucleoli stain intensity (ratio to background) for the control device (dotted line) is nearly constant over distance from the implant.

Figure 2D shows the average human nucleoli stain intensity in the lOpm layer closest to the implant. As shown, the implantable bioelectronic device 100 show a significantly enriched 10 presence of iPSCs compared to control device (Student's t-test). Circles in plot represent average in individual subjects (rats), bar indicates mean of the group.

Figure 3 is a schematic illustration of an implantation of an implantable bioelectronic device 300, in accordance with an embodiment of the invention. The implantable bioelectronic device 300 enable transected host nerves 302 to retain healthy nerve electrophysiology 28 days post-implantation. As shown, transected host nerve 302 (here, forearm nerve bundles) chronically implants either the implantable bioelectronic device 300 (such as the implantable bioelectronic device 100 of Figure 1A) or a control (lacking iPSCs) implantable bioelectronic device. The nerve response to electrical stimulation is evaluated using the chronically-implanted devices, i.e. either the implantable bioelectronic device 300 (such as the implantable bioelectronic device 100 of Figure 1A) or a control (lacking iPSCs) implantable bioelectronic device. In this regard, nerve response to electrical stimulation is evaluated using a pair of hook electrodes 304 around the forearm nerve bundle approximately four centimetres above the point of transection and implantation.

Figure 4A is representations of a response of a stimulated nerve of the implantable bioelectronic device (left panel) in comparison to a control device (right panel). As shown, compound action potentials (CAPs) are recorded from the implantable bioelectronic device but not from the control device. As shown, traces of nerve response to 100 pA, 0.1 ms stimulation pulses, are taken from different electrodes of the implantable bioelectronic device. CAP recorded from a naive nerve hook electrode are for comparison, wherein the naive nerves are non-transected. Notably, the naive nerve hook electrode mimic signals from a nerve in a conscious rat, as signals are not fired when the rat is under anaesthesia. Stimulation time identified by square in the traces of each of the nerve responses.

Figure 4B is a representation of an average peak-to-peak compound action potential (CAP) amplitude recorded by the implantable bioelectronic device of Figure 4A. Notably, higher CAP 35 amplitudes (voltages) are represented by lighter colours in the heatmap, with exact values represented by the numbers. Disconnected sections have an impedance >500 k52. The traces from the implantable bioelectronic device of Figure 4A taken are indicated by left-corner numbers 1 through 5 (top panel).

Figure 4C is a graphical representation of peak-to-peak compound action potential (CAP) amplitude recorded by the 28-day implanted implantable bioelectronic device and the control device and the control device of Figure 4A. The implantable bioelectronic device and the control device are stimulated with a 100 pA pulse stimulation. As shown, the control device exhibits no CAPs in response to stimulation, while the implantable bioelectronic device exhibit CAPs in response to stimulation. Circles represent values for each subject (mean across entire MEA), bar indicates mean of whole group.

Figures 5A and 5B are representations of nerve signal traces recorded by the implantable bioelectronic device of Figure 4A over 4 weeks post-implantation and a signal-to-noise ratio (SNR) of the recorded traces, respectively. As shown in Figure 5A, the nerve electrical recordings from the implantable bioelectronic device progressively improve over four weeks post-implantation, coinciding with nerve regeneration and synaptic integration with the implanted human iPSC muscle cells (biological sample). Herein, Black traces show bandpass filtered (0.2 -4 kHz) time traces recorded from a pair of electrodes in the MEA (bipolar configuration) and Gray traces show root-mean square (RMS) of black traces with 0.5 s rolling window. As shown, the nerve signal amplitude increases over implantation period.

As shown in Figure 5B, circles show mean value per bipolar electrode and line shows mean of group, N = 2 subjects (rats). Statistical comparison is done via one-way ANOVA followed by Tukey post-hoc. P values not shown are > 0.05. Within the first two weeks of implantation a little activity is observed in the awake animals. By the third and in particular the fourth weeks, however, signals greatly and significantly increase in amplitude such that at weeks 1 to 4: 12.9, 11.3, 19.7, 32.0 dB mean signal-to-noise ratio, respectively. It will be appreciated that the readings were recorded in real-time in freely moving animals.

Figure 6A is a graphical representation of root mean square (RMS) time traces from three bipolar electrodes recorded by the implantable bioelectronic device of Figure 4A over 4 weeks post-implantation. As shown, the three bipolar electrodes (dashed line, dotted line and dashed-dotted line) are normalised to range from 0 to 1 for each week. Points when the subject (the rat) is reaching out and stepping with the implanted body part (paw) is indicated by black squares under each trace. Increased correlation between recorded activity and body part movement, indicative of good nerve recording from said body part, develops at week 4 post-implantation, with less activity seen outside of stepping events.

Figure 6B is a graphical representation of quantification of correlation between the recorded 35 RMS time traces of Figure 6A and stepping events. Circles show mean fraction of RMS activity occurring during steps. These values are adjusted to account for time stepping/not stepping in that session. Line shows mean of group, N = 2 subjects (rats). Statistical comparison is done via one-way ANOVA followed by Tukey post-hoc. P values not shown are > 0.05.

Figure 6C is a representation of time-frequency spectrogram and time trace of a recording from a bipolar electrode of Figure 6A at week 4 post-implantation. As shown, high activity is 5 seen when the subject steps up and leans with paws (splaying of digits visible in non-implanted forearm, which retains an intact forearm nerve bundle, delimited by black dotted lines) on chamber walls. Comparatively less activity is seen before and after this event, as animal remains on the bottom of the chamber, indicating that recorded activity is driven by attempted paw use. Notably, in a freely moving chronic biohybrid rat group, at early 10 implantation timepoints recorded activity appeared to be independent of movement of the operated limb. However, by week four post-implantation activity increasingly correlated with movement of the implanted paw.

Figure 7 is an illustration of biological sample 702 survival 7 days post-implantation of the implantable bioelectronic device 704. As shown, the biological samples 702 stained dark grey 15 (using a human nucleoli dye) confirm survival post-implantation along with the host cells 706 that are in light grey.

Figure 8 is a graphical representation of a cell nuclei stain intensity over a distance from 28 day-implanted implantable bioelectronic device 100 of Figure 1A and a control device. As shown, all bioelectronic device implants show an increased cellular density close to the implant surface. Notably, no major differences in host cell density are seen across the implantable bioelectronic device 100 of Figure 1A and the control device.

Figure 9 is a graphical representation of peak-to-peak compound action potential (CAP) amplitude recorded by the 28-day implanted implantable bioelectronic device 100 of Figure 1A and a control device for 0.1 ms pulses of a range of amplitudes. Circles represent values for each subject (mean across entire MEA), bar indicates mean of whole group. While all nerves implanted with the implantable bioelectronic device 100 produced CAPs in response to 100 pA stimulation pulses, their average amplitudes differed, suggesting a degree of variability in implantable bioelectronic device 100 integration across animals. Consistent with normal nerve behaviour, stimulation with pulses of lower amplitude than activation threshold resulted in no CAP. Stimulation with higher amplitude pulses eventually resulted in CAPs recorded in both groups, the implanted implantable bioelectronic device 100 and the control device. Notably, CAPs recorded by the control device under these stimulation conditions consisted exclusively of an H-reflex, and may have instead been mediated by EMG from reflex activity of other nerves at the same cervical level as the forearm nerve bundle.

Figure 10 is graphical representation of quantification of impedance of the implanted implantable bioelectronic device of Figure 1A over 4 weeks of implantation. As shown, impedance increases for the functional every week over 4-week period post-implantation with the impedance being highest at the week 4.

Figure 11 is a schematic illustration of a step-by-step process 1100 involved in culturing biological sample onto an implantable bioelectronic device 1102, in accordance with an 5 embodiment of the invention. As shown, firstly, the implantable bioelectronic device 1102 are fabricated using photolithography techniques, and are then temporarily adhered to cell culture plates 1104 for biological sample, such as for example the human iPSC derived muscle 1106 (as used in this example), culture thereon. Once the human iPSC derived muscle 1106 are mature a biodegradable hydrogel, such as a fibrin hydrogel 1108 (as used in this 10 example), is polymerised on top of the implantable bioelectronic device 1102 and mature human iPSC derived muscle 1106 to ensure they are not damaged during surgical implantation. The device is then removed from the cell culture plate 1104 and implanted into the rat peripheral nerve 1110.

Referring to FIG. 12, illustrated is a flowchart 1200 of steps of a method of using an implant-able bioelectronic device, in accordance with an embodiment of the invention. At step 1202, an in-vitro activity is performed for cell culture on the implantable bioelectronic device. The in-vitro activity comprises obtaining the implantable bioelectronic device, seeding a biological sample on top of the implantable bioelectronic device and allowing the biological sample to grow for a pre-defined time, coating a biodegradable hydrogel on the coated layer of the biological sample. At step 1204, an in-vivo activity is performed. The in-vivo activity comprises implanting the implantable bioelectronic device having the biological sample and the biodegradable hydrogel thereon into a subject at a desired location, wherein the implantation of the implantable bioelectronic device enables connecting a first element and a second element for restoration of an interrupted biological function between the first and second ele-ments.

The steps 1202 and 1204 are only illustrative and other alternatives can also be provided where one or more steps are added, one or more steps are removed, or one or more steps are provided in a different sequence without departing from the scope of the claims herein.

EXAMPLE

In an exemplary implementation of the disclosed method, the biological sample are seeded onto the flexible base material, arranged in a cell culture plate, such as a PDMS cell culture plate, at day zero. After 48hrs (i.e. at day 2) the differentiation process of the biological sample initiates. At day 8 myotubes mature and a biodegradable hydrogel is polymerised on top of the grown cells and the implantable bioelectronic device to ensure they are not damaged during surgical implantation. The implantable bioelectronic device is then removed from the cell culture plate and implanted at a desired location in a subject, such as a peripheral nerve in a sutured forearm of rats between day 8-10. The implantable bioelectronic devices are then left implanted for a period of 4 weeks. During this 4-week period, live chronic and acute electrophysiology recordings are performed on the subject. During the acute electrophysiology, i.e. 28 days post implantation, the implanted nerve is electrically stimulated with a 100 pA pulse, a compound action potential (CAP) is recorded from the implantable bioelectronic device but not control implants that lack the implantable bioelectronic device. Notably, the CAP features recorded are consistent with those found in intact sensorimotor nerves, indicating healthy nerve physiology in the transected forearm nerves bundle (comprising combined ulnar and median nerves) implanted with the implantable bioelectronic device.

In an alternative implementation, the cell culture process comprises seeding iPSC clusters on the biodegradable hydrogel layer previously laid down on the MEA surface, followed by induction of differentiation 48 hours later. This resulted in the formation of mature myotubes on the surface of the biohybrid device by Day 8. The iPSC-derived myotubes exhibited acetyl-choline-induced contraction at Day 8 of culture. Notably, prior to cell seeding, there is reported a 97°/o yield, 1.84±2.20 k52 and post Week 4 in-vivo, there is reported a 25°/o yield, 159.00±35.80 kQ, mean±SD).

Device Fabrication: The iPSCs are cultured on a thin, flexible parylene-based multi-electrode arrays (MEAs). Herein, a 2pm-thick parylene C layer is deposited on silicon wafers (100 mm outer diameter, thickness of 1 mm) using an SCS Labcoater 2. The MEAs are fabricated using standard photolithography techniques to contain 32 conducting polymer (PEDOT:PSS) electrodes arranged in a symmetrical grid, such as a 2 x 2 mm area within the larger parylene-based flexible base material. The flexible base material also comprises a plurality of circular holes (openings) to permit growth of vasculature from the back of the parylene-based flexible base material of the implantable bioelectronic device and support cell survival post-implantation of the implantable bioelectronic device.

Gold electrodes and interconnects are patterned through a metal lift-off process. AZnL0F9260 photoresist is spin-coated at 3,500 r.p.m. on the substrate, baked at 110°C for 120 s, exposed to ultraviolet light using a Karl Suss Contact Mask Aligner MA/BA6 and developed with AZ 760MIF developer. A 10-nm-thick Ti adhesion layer, followed by a 100-nm-thick Au layer, is deposited (Angstrom EvoVac Multi-Process) and patterned by soaking the substrate in a bath of acetone for 10 minutes. A second 2pm-thick layer of parylene C (insulation layer) is deposited, followed by spin coating a layer of soap solution (2% Micro-90 diluted in deionized water) before an additional sacrificial 2pm-thick layer of parylene C (for the subsequent peel-off process) is also deposited. The layers of parylene are then patterned with another layer of positive photoresist (AZ9260) to shape the PEDOT:PSS electrodes and contact pads. This photoresist is then dry etched using reactive ion etching to expose electrodes and contact pads. Once etched a thin film of PEDOT:PSS is spin-coated onto electrodes (as previously described by Rivnay et el. 2016). The solution is spin coated 3 times with soft bakes in between for 60s at 120°C. After the final spin coat there is a hard bake for lhr at 130°C. Post baking the wafer is left over night in SI water to remove excess PSS. The following day the sacrificial layer of parylene C can be removed, leaving the finished device ready for use.

Biological Sample: In this regard, OPTI-OX human induced pluripotent stem cells (iPSCs) is selected as the biological sample for the biohybrid cell population. Notably, these cells differentiate into myotubes from Day 8 in cell culture post doxycycline and retinoic acid induction and regenerate within 3 weeks after injury. At this timepoint, the cultured myotubes are generally considered fully differentiated and receptive to axon growth and innervation. Moreover, said cells are well-suited to host sensorimotor nerves, whose motor axons typically innervates muscle tissue, while their human iPSC-derived nature makes their use clinically translatable. It will be appreciated that the biological sample may also differentiate into other cell types, including neurons. However, the disclosed method employs only pre-differentiated biological sample desired for a specific application.

Cell culture: Glass wells or custom-made polydimethylsiloxane (PDMS) wells are attached to the MEAs using PDMS as a glue. The devices are plasma treated at 25 W for 1 min to make the surface hydrophilic for cell culture. The inside of the well is kept wet from this point on with DI water. The implantable bioelectronic device is entirely sterilized for a minimum of 30 min in 70% ethanol and rinsed with Dulbecco's phosphate-buffered saline (DPBS).

OPTi-MyoD hiPSCs are defrosted and expanded in Essential 3TM Flex Medium for approximately 3 to 4 days in 6 wells plates. This gave approximately 1.5 million cells/mL. OPTi-MyoD hiPSCs are seeded onto devices with densities of 100,000 cell/cm2. Differentiation is initiated 48 hours after cell seeding. The MyoD media is supplemented with fresh lpg/mL doxycycline (Sigma) and 1pM Retinoic acid (Sigma) and 40ng/mL of FGF2 (R&D). The cell culture media is changed every day from day 0 to day 5. From day 6 onwards, MyoD media is supplemented only with 1pM Retinoic acid, 3pM of CF-11R99021 (Tocris) and 10% KOSR (ThermoFisher) and no doxycycline.

Biodegradable hydrogel preparation: A fibrinogen stock solution is prepared at a concentration of 37.5 mg/ml in HEPES-buffered saline (HBS: 20mM HEPES, 150 mM NaCI, pH = 7.4) by slowly dissolving fibrinogen (F8630, Sigma Aldrich) for 2 hours at 37°C (solution named SOLFG) to result in Fibrinogen Solution (SOL-FG). Filter SOL-FG with a 0.22 pm filter for sterilisation (and removal of any aggregates). Perform any further dilutions in sterile HBS. Next a Calcium Thrombin Solution (SOL-CaTh) is created containing 3 U/mL thrombin and 60 mM calcium ions. A 120 mM stock solution of CaCl2 in HBS is prepared. A thrombin (T9549, Sigma Aldrich) stock solution of 6 U/ml in HBS is prepared and kept on ice. A thrombin and CaCl2 solution is prepared by mixing equal volumes of SOL-Th and SQL-Ca, obtaining solution SOL-CaTh and kept on ice. A solution containing 1,000,000 cells/mL in cell culture media (SQL-Cells) is prepared and is used to coat cells that had been grown and differentiated on ParC based implantable bioelectronic devices. For the production of 150 pL gels (scale 5 accordingly) 54 pL of SOL-FG and 54 pL of HBS are mixed, and 54 pL of SOL-CaTh is added to the fibrinogen-cell mix and immediately 150 pL of the gelling solution is pipetted into the desired vessel and incubated at 37°C for 2 hours to allow gelation to occur. Once cells and fibrinogen are mixed, these solutions are used within 15 mins as cells/residual thrombin in cell culture media will start gelling the solutions. Final concentrations: FG = 3.125, 6.25, 12.5, 10 25 mg/mL, Th = 1 U/mL, CaCl2= 20 mM.

Animal procedures: It will be appreciated that all animal work is performed in accordance with the prescribed procedures, such as the UK Animals (Scientific Procedures) Act 1986. 190 -240 g Hsd:RH-Foxnlrnu athymic nude rats (Envigo, France) are used in this study. Surgical procedures are performed under isoflurane anaesthesia, with the animal's body temperature regulated using a thermal blanket.

For implantation of the implantable bioelectronic device, an incision is performed with a sterile knife (or blade), at the desired location in the subject, i.e. at elbow height in the forearm nerve bundle (combined ulnar and median nerves) under the triceps muscle in rats, immediately prior to device implantation to promote tissue regrowth and angiogenesis in the vicinity of the implant. The scoring is done and then the proximal nerve stump is sutured, using a 9-0 nylon suture (Ethicon), the cell-laden side of the implantable bioelectronic device that is transferred a few centimetres towards the midline of the animal and anchored subcutaneously above the latissimus dorsi muscle. Beneficially, said implantation strategy can support cell survival for at least seven days after implantation. Animals are allowed to recover from the surgical procedure and provided with analgesics (Meloxicam, Carprofen) for two days post-implantation, as well as immediately prior to surgery. Animals are housed in groups of three or four with ad libitum access to food and water. Control implants (lacking cells) are implanted in an identical way.

Device electrical characterisation: Impedance measurements are completed with a potentiostat (Autolab PGSTAT128N) in a three-electrode configuration. An Ag/AgGI electrode is used as the reference electrode, a Pt electrode is the counter electrode and the working electrode is the recording electrode of the MEA. The characterization is performed in DPBS solution.

Electrophysiology recordings under anaesthesia: 28 days post-implantation, the implantable bioelectronic device is stimulated using an acquisition and stimulation system (a 32-channel RHS headstage and RE-IS Stim/Recording Controller, Intan Technologies, USA) in-vivo using a pair of hook electrodes (platinum wire hooks) around the forearm nerve bundle approximately four centimetres above the point of transection and implantation. The hooks are connected to the same acquisition and stimulation system. The nerve is stimulated using a 0.1 ms duration pulse, an activation threshold of 10, 50, 100 or 200 pA, and 20-30 stimulation pulses delivered for each amplitude. The MEA connections are externalised through a headcap.

Stimulation data is recorded (and amplified (X192) and digitised) using the four-week implanted implantable bioelectronic device. To minimise EMG noise from nearby musculature, bipolar recording electrodes are set up between pairs of electrodes across the MEA. Notably, a compound action potential (CAP) is recorded from rats implanted with the implantable bioelectronic device but not controls. Notably, the CAP consists of a peak with an approximately 2 ms delay (corresponding to a conduction speed of -20 mjs), consistent with Aa/B fibre activation, followed by a later peak, likely corresponding to reflex activity initiated by sensory fibre activation (H-reflex). These CAP features are consistent with those found in intact sensorimotor nerves, indicating healthy nerve physiology in the transected forearm nerves implanted with the implantable bioelectronic device. Notably, H-flex (or Hoffmann's reflex) is an electrical stimulation-based reflectory reaction of sensory fibres. Typically, H-reflex test is indicative of muscle response to electrical stimulation thereof by an electrical stimulator.

Notably, the recordings are measured for animal in anesthetized state and in an awakened state (where they freely roam around in a transparent area of 0.3 m x 0.3 m) thereof. Analysis of the peak-peak amplitude of the response to stimulation in the raw recorded signals is carried out in Spike2 (Cambridge Electronic Design, UK, v9.04b) using a custom script. These referenced signals are then bandpass-filtered (0.5 -4 kHz, 4'h order Butterworth filter). Signal-to-noise ratio (SNR) is calculated as the ratio of the variance during high signal relative to background activity, both identified manually, expressed as dB. RMS traces are produced from the referenced and bandpass-filtered signals by calculating the signals RMS (root-mean square) at 50 ms intervals and averaging the values using a 0.5 s rolling window. Normalised signal is calculated by normalising each RMS trace (single recording session) to range from 0 (background noise) to 1 (highest amplitude signal). The fraction of signal amplitude occurring during step is calculated by comparing the average normalised RMS value during stepping events, relative to the same average value outside of these events. All plotting and statistical tests are carried out in Matlab (Mathworks, R2021b).

In this regard, two experimental animal groups are selected on which the electrophysiology recordings are performed. In the first animal group, the animal in under anaesthesia and a terminal electrophysiology ss performed. In the first animal group, a fake action potential (by using hook electrodes) is created to check whether the implantable bioelectronic devices after 4 weeks of implantation are capable of recording an action potential. In the second animal group, the animals are allowed to move freely. In such case, no stimulation pulse is needed as the animal is awake, and the action potentials can be recorded in real time through the implantable bioelectronic device implanted for 28 days (4 weeks). It will be appreciated that the stimulation pulse is not always needed, it is needed only for the initial in-vivo characterisation of the implantable bioelectronic device. Notably, for the purpose of both of these experiments, the implantable bioelectronic device act as recording devices. However, in the future this technology could also be used to stimulate host nerve or brain tissue and/or record the same with or without stimulation.

Immunohistochemistry and Imaging: The whole tissue embedding and staining process occurs on a Leica Bond RX autostainer. All steps are performed within a vacuum at 40°C for 1 hour. The steps are as follows: a wash in 70% Ethanol, 90% Ethanol, four 100% Ethanol washes, three xylene washes, followed by four liquid paraffin wax steps at 63°C. The sections are first baked and de-waxed using Bond Dewax Solution (Leica Microsystems AR9222), then we move on to the pre-treatment protocol where Bond ER2 Solution is their pH9 antigen retrieval solution (Leica AR9640) at room temperature. The Bond Wash used throughout is AR9590. For the staining protocol a Bond Polymer Refine Detection kit (Leica D59800) is used. The kit includes the peroxidase block, post-primary, HRP polymer secondary antibodies, DAB and haematoxylin.

The staining protocol begins with 150pL of peroxidase block added to the tissue samples and incubate for 5 minutes at room temperature. The sample is then washed with 150pL of bond wash solution three times. Next 150uL of the primary antibody, mouse monoclonal to human nucleoli [NM95] (Abcam ab190710) for 60 minutes at room temperature. The sample is then washed with 150pL of bond wash solution three times. 150uL of the post-primary solution is incubated for 8 minutes at room temperature. Three 150pL further bond washes are performed. Next 150pL of HRP polymer secondary antibodies incubated for 8 minutes at room temperature. A 2-minute incubation with 150pL bond wash solution is performed followed by a wash with 150pL deionised water. Two washes with 150 pL DAB refine solution. 150pL of Hematoxylin is added and incubated for 5 mins. Followed by washes with 150pL deionized water, 150pL bond wash solution, 150pL deionized water. Samples are then ready to be imaged.

Imaqina: Image analysis is performed in Image] software (National Institutes of Health). The edge of the tissue facing the device is traced by the user by hand and subsequently unfolded to become a flat image. Colour deconvolution is run to separate the implanted cells of interest (brown stain) from the host cells (blue) by difference in histology stain colour. The stain intensity values are then imported into Matlab (Mathwords, R2021b) to produce a mean intensity over distance from the implant using a custom script. Following this, a 400x400 pixel box is chosen in the original image in a region of tissue far away from the device and the average background stain intensity is measured. The intensity profile is divided by this value to produce a normalised intensity for each stain. Graph plotting and statistical comparison is carried out in Matlab.

Claims (17)

1. CLAIMS1. An implantable bioelectronic device (100, 300, 1102), the implantable bioelectronic device comprising - a flexible base material (102) having a top layer (102A) and a bottom layer (102B) opposite the top layer, the flexible base material comprising at least one electrode (104) and a plurality of holes (106); a biological sample (108, 202, 1106) seeded on the top layer of the flexible base material; and - a biodegradable hydrogel (110, 1108), wherein the implantable bioelectronic device, when in use in-vitro, enables the biological sample to grow on the top layer of the flexible base material prior to a coating thereof with the biodegradable hydrogel, and wherein the implantable bioelectronic device, when in use in-vivo, enables connecting a 15 first element (114) and a second element (116) for restoration of an interrupted biological function between the first and second elements.
2. 2. The implantable bioelectronic device (100, 300, 1102) of claim 1, wherein the resto-ration of the interrupted biological function between the first element (114) and the second element (116) is recorded as stimulation data by the implantable bioelectronic device.
3. 3. The implantable bioelectronic device (100, 300, 1102) of claim 1 or 2, wherein the electrical stimulation is provided as a pulse of an activation threshold ranging from 10 to 200 microampere using a pre-defined duration pulse.
4. 4. The implantable bioelectronic device (100, 300, 1102) of any of the preceding claim, wherein number of electrodes (104) is at least two, and wherein the at least two electrodes 25 are arranged in a symmetrical array occupying an area in a range of 1.0 x 1.0 millimetre to 10 x 10 millimetre within the flexible base material (102).
5. 5. The implantable bioelectronic device (100, 300, 1102) of any of the preceding claim, wherein the flexible base material (102) comprises a polymer layer, selected from a parylene derivative, deposited on a flexible wafer, selected from a silicon, a glass, or polymers.
6. 6. The implantable bioelectronic device (100, 300, 1102) of any of the preceding claim, wherein the biological sample (108, 202, 1106) is selected from pre-differentiated human induced pluripotent stem cells (iPSC) derived cells.
7. 7. The implantable bioelectronic device (100, 300, 1102) of any of the preceding claim, wherein the first element (114) is an electrically active cell and the second element (116) is selected from an electrically active cell, a muscle tissue and an electrical component.
8. 8. The implantable bioelectronic device (100, 300, 1102) of claim 1, further comprising a - processing arrangement for processing and analysing the recorded stimulation data; - a memory unit; - a transmitter that can translate the stimulation data, and - a battery unit.
9. 9. A method of using an implantable bioelectronic device (100, 300, 1102), the method comprising - performing an in-vitro activity for cell culture on the implantable bioelectronic device, the in-vitro activity comprising obtaining the implantable bioelectronic device, seeding a biological sample (108, 202, 1106) on top of the implantable bioe-lectronic device and allowing the biological sample to grow for a pre-defined time, coating a biodegradable hydrogel (110, 1108) on the coated layer of the biological sample; and performing an in-vivo activity comprising implanting the implantable bioelectronic device having the biological sample and the biodegradable hydrogel thereon into a subject at a desired location, wherein the implantation of the implantable bioelectronic device enables connecting a first element (114) and a second element (116) for restoration of an interrupted biological function between the first and second elements.
10. 10. The method of claim 9, wherein the implantable bioelectronic device (100, 300, 1102) is according to any of the claims 1-8.
11. 11. The method of claim 9 or 10, wherein the implantable bioelectronic device (100, 300, 1102) is implanted in the subject such that a bottom layer of the implantable bioelectronic device is laid against a first part of the subject's body and a top layer having the biological sample (108, 202, 1106) and the biodegradable hydrogel (110, 1108) thereon faces an electrically active cell proximal to the first part of the subject's body.
12. 12. The method of claim 9 to 11, further comprising recording a stimulation data, in-vivo, by the implantable bioelectronic device (100, 300, 1102).
13. 13. The method of claim 9 to 12, wherein the electrical stimulation is provided as a pulse of an activation threshold ranging from 10 to 200 microampere using a pre-defined duration pulse.
14. 14. The method of claim 9 to 13, wherein number of electrodes (104) is at least two, and 5 wherein the at least two electrodes are arranged in a symmetrical array occupying an area in a range of 1.0 x 1.0 millimetre to 10 x 10 millimetre within the flexible base material (102).
15. 15. The method of claim 9, further comprising - processing and analysing, using a processing arrangement, the recorded stimulation data; - storing, in a memory unit, the recorded stimulation data; - translating, using a transmitter, the recorded stimulation data, and - powering, using a battery unit, the implantable bioelectronic device.
16. 16. The method of claim 9, further comprising preparing the implantable bioelectronic device (100, 300, 1102) using at least one of: a photolithography technique, printing technique, 15 a metal lift-off technique.
17. 17. A computer program product comprising a non-transitory machine-readable data storage medium having stored thereon program instructions that, when accessed by a processing arrangement, cause the processing arrangement to carry out the method of claims 9 to 16.