CA3119480A1 - Methods of making and bioelectronic applications of metalized graphene fibers - Google Patents
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Abstract
Description
GRAPHENE FIBERS
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application claims priority to and the benefit of US Provisional Application No.
62/770,540 entitled "Methods of Making and Bioelectronic Applications of Metalized Graphene Fibers" filed on November 21, 2018, the contents of which is hereby incorporated by reference in its entirety.
TECHNICAL FIELD
BACKGROUND
Furthermore, during the stimulation and recording, the electrode must deliver and record sufficient amount of charge, but not exceed the threshold for triggering electrolysis of the surrounding media. The low surface area of conventional metal-based electrodes intrinsically
[0006] These limitations have motivated the evaluation of other materials such as nanostructured carbon, nanostructured fibers, metal oxides, metal nitrides and organic conductors, to provide enhanced electrochemical characteristics with biocompatibility.
However, such materials provide additional challenges. For example, coating with titanium nitride (TiN) improves the charge injection capacity of Pt electrodes from 0.05-0.26 mC/cm2 to 0.87 mC/cm2 over a capacitive mechanism, which is favorable for in-vivo studies.
Activated Iridium oxide (IrOx) further enhances the charge injection capacity of Pt electrodes to 1-5 mC/cm2 through a faradaic mechanism, however, it has limited stability and safety margin for neural stimulation. Deposition of conducting polymers such as PEDOT:PSS, PEDOT:pTS, PEDOT:C104, PEDOT:CNT further increase the charge injection capacity to 2.92, 2.01, 2.09, and 1.25 mC/cm2, respectively, compared with Pt (0.05-0.26 mC/cm2).
These polymers also reduce the electrode impedance to 8, 26.5, 203 and 42 MS2 um2, respectively, compared with Pt (-390 MS2 um2). However, the heterogeneous nature of the coated microelectrode is prone to galvanic coupling that can result in side reactions, corrosion, delamination and consequently early failure. The selected materials and fabrication process must also minimize electrode delamination to ensure robust and reliable operation.
Nanotubes and graphene microfibers provide excellent electrochemical properties, high surface area, mechanical strength, high flexibility, and biocompatibility, and thus ideal for electrode fabrication. Indeed, carbon nanotube fibers demonstrated significant electrochemical activity, sensitivity, and resistance to biofouling when implanted, compared with metal electrodes and conventional carbon fibers. However, while the neat carbon nanotube based fiber microelectrodes are stable and able to record neural activity for relatively long periods of time, the spinning process used to manufacture nanotubes is challenging.
Additionally, the high cost for producing super aligned carbon nanotube arrays (dry spinning), as well as the extremely rigorous conditions needed for their manufacturing including high temperature (>
1000 C), and the use of corrosive solvents (e.g. fuming sulfuric acid and chlorosulphonic acid), drastically limits the production of carbon nanotube-based microfibers.
SUMMARY
The graphene-fibers may be manufactured using liquid crystalline dispersions of graphene oxide (LCGO). The graphene fibers have unique mechanical and electrochemical properties in addition to its natural biocompatibility. The resulting microelectrode arrays provide better performance when compared to conventional graphene or Pt electrodes. In particular, in some embodiments, the low impedance and porous structure of graphene fiber results in an unrivalled charge injection capacity and the improved ability to record and detect neuronal activity, while the thin Pt layer transfers the collected electrons along the microelectrode efficiently. Further, the resulting microelectrode arrays can also detect neuronal activity with improved signal to noise ratios when compared to conventional microelectrode arrays.
Optionally, the acid includes hyporphosphorous acid. Optionally, the metal layer includes at least one of platinum, iridium, iridium oxide, platinum-iridium, and titanium nitride.
Optionally, the metal layer has thickness in the range between about 10 nm to about 500 nm.
Optionally the insulative coating includes Parylene-C.
Optionally, the peripheral nerve may be peripheral to at least one of the heart, lungs, stomach, liver, spleen, pancreas and pelvic organs.
BRIEF DESCRIPTION OF THE DRAWINGS
Some of the figures may have been simplified by the omission of selected elements for the purpose of more clearly showing other elements. Such omissions of elements in some figures are not necessarily indicative of the presence or absence of particular elements in any of the exemplary embodiments, except as may be explicitly delineated in the corresponding written description. None of the drawings are necessarily to scale.
DETAILED DESCRIPTION
In comparison with conventional graphene electrodes or platinum (Pt) electrodes, the hybrid platinized graphene fibers discussed herein may be robust and provide better performance. In particular, embodiments of microelectrode arrays built in accordance with the disclosure herein may include low impedance and porous structure of graphene fiber with a thin platinum layer thereupon. The graphene fiber may provide for an unrivalled charge injection capacity and the ability to record and detect neuronal activity, while the thin Pt layer transfers the collected electrons along the microelectrode efficiently. Accordingly, the microelectrodes may be capable of detecting neuronal activity with a high signal to noise ratio.
When a microelectrode is longer than a few millimeters, the resistivity increases significantly, which poses a significant challenge to low noise recording. By contrast, a system built in accordance with the present disclosure may overcome this limitation by applying a thin coating of metal (e.g., platinum in the range of 200 nm) as the current collector on the wet-spun graphene microfibers. This modification integrates the electrochemical characteristics of graphene and electronic properties of the metal to the microelectrodes, without limiting its mechanical flexibility and high surface area. The low impedance and porous structure of graphene fiber result in an unrivalled charge injection capacity with the ability to record and detect neuronal activity, while the thin metal layer transfers the recorded electrons along the microelectrode efficiently.
provides a schematic diagram of a process for manufacturing a metalized graphene fiber microelectrode and implanting the microelectrode in the brain. In particular, at 101, liquid crystal graphene oxide (LCGO) process is used to generate graphene oxide fibers 103 which are deposited within an acid bath 105. The bath may be rotated 109 and results in production of graphene fibers (GF) 111. The GF may be cut into smaller pieces 113 and coated by a metal to form a metal-coated graphene fiber 115. The metal-coated graphene fiber 117 may then be covered by an insulating material. The insulating material may then be cut such that one conducting surface and/or a sharp tip is exposed for recording and/or stimulation. One or more insulated metal-coated graphene fibers may be assembled 119 and implanted into a brain 121. A cross-sectional view 123 illustrates the movement of electrons 125 through the metal layer of the insulated metal-coated graphene fiber.
provides a flowchart illustrating the method for manufacturing a metalized graphene fiber microelectrode. In a first step 1125, graphene fibers (GF) are fabricated using wet-spun liquid crystal graphene oxide (LCGO) process.
Description of the process for fabricating GF using LCGO, and further Solid State Exfoliation of Graphite is described in Esrafilzadeh, D., Jalili, R., Stewart, E. M., Aboutalebi, S. H., Razal, J. M., Moulton, S. E. & Wallace, G. G. (2016). High-performance multifunctional graphene-PLGA
fibers: toward biomimetic and conducting 3D scaffolds. Advanced Functional Materials, 26 (18), 3105-3117, which is hereby incorporated by reference in its entirety. In a second step 1127, the fabricated GF are reduced in an acid bath. In a third step 1129, a metallic layer is deposited over at least a portion of the individual GF filaments. In a fourth step 1131, the GF
filaments (with the deposited metallic layer) is cut into individual pieces and attached to conductive wires. In a fifth step 1133, the individual pieces are coated with an insulative material. In a sixth step 1135, active sites of the microelectrode including the GF filaments are exposed 1135.
A less conductive metal, such as platinum, may then be used to metalize the graphene fibers.
However, the metal layer may be used to improve overall conductivity by collecting the charges.
Alternatively, the graphene structures may be bioprinted into any suitable shape for recording and/or stimulating.
NEURAL RECORDING MICROELECTRODES
This coagulation bath reduced the GO during the spinning process without compromising the flexibility and mechanical strength. Flexibility of a microfiber is an important characteristic for fabricating implantable microelectrode, as it minimizes foreign body reaction and maximizes greater proximal neuron survival in comparison with traditional metal electrodes.
of Figure 2 illustrates an enlarged SEM cross-section from Panel C of Figure 2, and shows aligned and highly organized characteristic features of graphene microfibers. Hundreds of individual graphene sheets are collapsed together during the coagulation bath creating a multi-layer core in the graphene fiber assembly.
Higher magnification SEM image of the cross-section of a typical fiber presented in Panel D of Figure 2 shows a particularly aligned feature of the graphene sheet layers.
Here, the in-situ reduction of fully ordered multi-layered GO sheets in liquid crystalline state inhibited the randomization of the morphology by preventing the relaxation phase. In fact, the inherent LC
order was maintained allowing the highly organized assembly of GO microfibers.
Furthermore, the in-situ reduction constrained any uncontrolled re-stacking of the sheets.
Consequently, a fully ordered and porous architecture was obtained. Such reduced graphene fibers provided an extremely high surface area of up to ¨2210 m2 g-1 that facilitated the accessibility of electrolyte and ionic diffusion into the resultant electrode.
of Figure 2 illustrates the electrical resistivity of graphene microfibers as a function of platinum coating and length. As illustrated, the resistance increases with fiber length. Further, GF-Pt electrodes illustrate lower resistance than GF
electrodes. The electric resistance of these microfibers was affected by their length, which increased from ¨2 to 20 kS2 as the length increased from ¨0.5 to 5 cm. To minimize the effect of the fiber length on the resistivity and facilitate the recording of fine nerve's signals, one side of the microfibers was sputter coated with up to ¨200 nm thick layer of Pt (GF-Pt). The Pt coating resulted in a significant increase in the conductivity from 205 16 S/cm to 460 30.3 S/cm.
Moreover, as Pt acts as current collector, the increase in the resistivity due to the length of microfibers became considerably less detrimental. Minimization of the resistivity is particularly desirable to achieve noise reduction, stability of recordings and effective electrical stimulation.
electrode. Panel G is an SEM image of the outer surface of a GF electrode coated with Pt.
Panel H is an SEM image of the outer surface of a GF electrode coated with Pt and insulated with Parlyene-C. Both Pt and Parylene-C coatings formed thin layers around the microfibers, retaining the porous structure and high surface area at the tip, as evidenced by high-resolution SEM microscopy images (see Panels I, J, K, and L of Figure 2). The high surface area results in high recording sensitivity, and a large charge injection capacity with low impedance at 1 Hz to 10 kHz. In particular, Panels I and J illustrate a cross-sectional SEM
image of GF-Pt electrodes, and Panels K and L illustrate SEM images of the tip of the final microelectrode.
Electrochemical impedance spectroscopy (EIS) and Cyclic voltammetry (CV) were performed with a CHI 660E electrochemical workstation (CH Instruments) in phosphate buffered saline (PBS, pH 7.4, Sigma-Aldrich) at room temperature. A three-electrode cell system was employed with the test sample as working electrode, a platinum sheet as counter electrode, and AglAgC1 as reference electrode. CVs were recorded between the voltages of -0.2 and 0.8 V at scan rates of 10-50000 mV/s. Each sample was tested for 3-5 cycles, and the cathodic charge storage capacity was calculated from the integration of current over time recorded in the last cycle at scan rate of 100 mV/s. Sweeps from -1.6 to 1.6 V
were performed to determine the water window (e.g., threshold to electrolysis) of GF-Pt-PC
electrodes, and the water oxidation and reduction potentials were determined when the sharp current peaks were detected. EIS was performed between frequencies of 1-104 Hz, and the specific impedance was calculated at 103Hz.
of Figure 3 illustrates the modulus of impedence of microelectrodes.
An electrode made from Pt wire of similar diameter with microfibers was also fabricated and tested as the control. EIS analysis showed that the impedance of graphene microelectrodes was ¨2 orders of magnitude lower than the Pt electrode in the range of frequencies tested (1 Hz to 10 kHz, Panel A). Particularly, the impedance at 1 kHz was over 50 times lower than the Pt electrode (-501d2 vs ¨3001(Q). This large reduction in the impedance of the graphene microelectrodes was as a result of the increased available surface area of fully ordered and separated graphene sheets. Furthermore, the impedance of the Pt modified microelectrodes (at 1 kHz) was ¨5 and ¨300 times lower than neat graphene and Pt microelectrodes, respectively. Adding a thin layer of Pt on the graphene microfiber (as current collector) resulted in a strong synergistic effect leading to a robust and superior hybrid microelectrode with lower impedance.
of Figure 3 illustrates the phase angle of impedance of microelectrodes. At an ideally polarisable electrode during the stimulation, the charge passed would be completely attributed to the capacitance rather than any Faradic reaction. The phase lag of microelectrodes, as illustrated in Panel B of Figure 3, indicates that the electrochemical interaction at the exposed tip is controlled by a capacitive charging-discharging process over the double layer of the microelectrode tip (an adsorption controlled process).
of Figure 3 illustrates CVs of the microelectrodes at 10 mV/s in PBS
solution. CV is a simple and fast technique for measuring the capacitance and Faradaic components at an electrode-solution interface. Panel C of Figure 3 compares cyclic voltammetry (CV) of different electrodes prepared in this example. Although, both graphene-based microelectrodes showed near-rectangular CV curves, the current of the Pt modified microelectrode was significantly higher than other electrodes. This improvement was due to integration of high conductivity of Pt coating coupled with the high surface area of the GO
electrode that allows effective diffusion of electrolyte ions, followed by a facile electron transfer via the Pt layer. Furthermore, the cathodic charge storage capacity of the Pt modified GO microelectrode, calculated from the CV, was 946 140 mC/cm2, a value of ¨3 orders of magnitudes higher than Pt electrode and ¨ 2 times higher than the unmodified graphene microfibers.
of Figure 3 illustrates the water window of microelectrodes, and Panel E of Figure 3 illustrates the voltage transient test of microelectodes. And Panel F of Figure 3 illustrates a comparison of the charge injection capacity, specific impedance, and geometrical area of a microelectrode built in accordance with the methods described herein in comparison with neural interface electrodes reported in literature.
A symmetric charge-balanced, cathodic first, biphasic current pulse with 100 [is width, 20 is interphase open circuit potential and 2.78 ms short circuit at 250 Hz was generated by a digital stimulator D5800 and A365 Isolator units (World Precision Instruments). The voltage waveform across the active microelectrode in response to the applied current pulse was recorded with an e-corder system (eDAQ). The maximum negative polarization potential (Einc) was calculated by subtracting the initial access voltage (Va) from the total voltage transient. The charge injection capacity was determined when Em, reached the water Ic'tC
reduction limit from the following equation: Qinj = -GSA' where Qinj is the charge injection limit capacity, I is the current pulse applied, t, is the pulse width, and GSA
is the geometric surface area.
Electrical stimulation initiates a functional response by depolarizing the membranes of excitable cells, which is achieved by the flow of ionic current between the electrodes. Voltage transient measurements were made to determine the maximum positive and negative polarization values across the electrode-electrolyte interface, and estimate the maximum charge that can be injected in a stimulation pulse without exceeding the water electrolysis limit. The potential is swept over a wide window to obtain the voltage range where the electrode, electrolyte and water are neither oxidised nor reduced.
To ensure the safe polarization of the microelectrode during stimulation, a CV of the microelectrode was recorded by sweeping the potential between the voltage limits of -1.6 V to 1.6 V (vs.
Ag/AgC1 electrode). In biological systems, this potential range is largely determined by the oxidation and reduction of water (water window). The water window was limited by the water oxidation and reduction voltages, indicated by a steep increase in the current. In this example, the water window of GF based microelectrodes was found between -1.0 V
to 0.9 V
(Panel D of Figure 3). The upper portion of Panel E of Figure 3 shows a typical input biphasic current pulse (300 [tA and 20 us delay). The potential excursion response (see lower portion of Panel E of Figure 3) to the current pulse shows an initial, rapid change in potential, known as the access voltage (Va=-1.35 V), due to the ohmic resistance of the electrolyte, followed by a slowly rising polarization voltage (Vp=-0.90 v), which is due to the charging of the electrode/electrolyte interface. The Vp was calculated by subtracting the Va from the maximum negative voltage in the transient (Vt=-2.25 V).
of Figure 4 confirms that there was no noticeable change in the electrochemical performance over the prolonged stability test.
Furthermore, the stability of graphene microfibers and the microelectrodes were evaluated against repeated bending and prolonged soaking in PBS solution (as illustrated in Panels C, D, E, and F of Figure 4). In particular, Panel C of Figure 4 demonstrates that the graphene microfibers show outstanding stability over the bending cycle test, as there was neither obvious difference in conductance between straight and bended GF-Pt fiber electrodes (105.2 2.7 vs 104.4 3.7 S/cm), nor after 200 times bending (105.2 2.7 vs 102.7 2.5 S/cm). Further, Panel D of Figure 4 illustrates that even after soaking in PBS for 2 weeks, only ¨8% conductivity loss was observed. The microelectrodes also could maintain 77.6% and 52.2% charge storage capacity after very tough durability and fatigue tests involving consecutive 200 times 360 folding (Panel E of Figure 4) and 2 weeks soaking in PBS (Panel F of Figure 4), respectively.
Geometrical Specific Charge Charge surface area Impedance impedance storage injection Material (kS2 at lkHz) capacity capacity Gina (MI 2 pm2) (MC/CM2) (MC/CM2) Graphene 50 7.5 19.5 2.9 798 110 8. 7 1. 3 fiber (GF) Pt coated 1.3 11 1.5 946 140 10.5 1.5 fiber (GF-Pt)
Dexamethasone (2 mg/kg) was administered subcutaneously over the shoulders to reduce the inflammatory response and was followed by the subcutaneous administration of 0.5%
lidocaine (0.16 cc) directly under the scalp incision site. After exposing the skull, a 2.0 mm by 2.0 mm craniotomy was created with a center at our initial coordinates of implantation of 2.5 mm rostral and 2.5 mm lateral from bregma. The dura in the area was reflected using a dura pick followed by micro scissors to expose the surface of the cortex. The entire area was kept under liquid with frequent application of 7.4 pH sterile physiological phosphate buffered solution.
insulation (GF-Pt-PC). The second microelectrode consisted of a single, 40 p.m diameter graphitic fiber conductor encapsulated with Parylene-C insulator (GF-PC). The third microelectrode was a single, 40 p.m diameter GF-Pt-PC microelectrode. The final two microelectrodes consisted one GF-PC and one GF-Pt-PC with 20 p.m diameters.
The tips of the microfiber wire bundle were lowered until they came into contact with the cortical surface at the implantation coordinates, the distance counter on the micropositioner was reset and the device was lowered into the motor cortex at a speed of 1000 p.m/ s. If buckling of the wire began, the implantation was immediately stopped and the speed was reduced to 100 p.m/ s. A sterile stainless steel hypodermic needle was inserted into the rat tail to serve as the counter electrode. The optimal implantation depth was 1500 p.m.
Identical recording procedures were followed for all subsequent microelectrodes. After the investigation, the rat was euthanized using an overdose of 5% isoflurane vapor which was applied until breathing cessation occurred.
Anoise
bundled microelectrodes inserted 1.5 mm into the motor cortex of a Long Evans rat at the location of 2.5 mm rostral and 2.5 mm lateral from bregma. Panel E of Figure 5 shows 1543 single unit signals obtained over 10 minutes of recording time from one of the GF-Pt-PC
implanted microelectrodes. The dark line in the center of the waveforms represents the average single unit signal which has an amplitude of -70.2 [tV, and a peak to peak value of 130.5 V. The units of the second active electrode (not shown), have a similar shape with a slightly lower mean amplitude of -54.3 [tV with a peak to peak value of 89.7 [tV. The SNR for the two microelectrodes are 7.10 dB and 4.43 dB.
amplitudes, peak-to-peak voltages of 183.4 [tV and 123.6 V, and signal-to-noise ratio (SNR) of 9.2 dB
and 8.4 dB
respectively. All of our GF-Pt microelectrode signals have demonstrated recording signals which are larger than previously reported. On the other hand, the GF-only microelectrode showed a weaker performance. Although it possessed a signal amplitude of -93.9 [tV and a peak-to-peak voltage of 146.4 V, the noise was considerably larger which lead to a reduced SNR of 3.0 dB.
Accordingly, the robust, flexible and free-standing graphene-fiber based microelectrode arrays with an extremely thin platinum coating demonstrate high performance neural recording microelectrode with low impedance, high surface area and a high charge injection capacity. In-vivo studies show that microelectrodes implanted in the rat cerebral cortex can detect neuronal activity with remarkably high signal-to-noise ratio (SNR).
The example experiments have demonstrated the ability of the platinum modified graphene microfibers for single unit recording capability with high signal-to-noise ratio. Additionally, the recorded units captured by these electrodes were not dissimilar to those reported with other small microelectrode platforms.
Further, Panel C of Figure 11 illustrates that the peak current is linearly dependent on square root of scan rate at high scan rate with linear regression equation as y=-1.6698*10-8+5.4659x (R2=0.999), suggesting a diffusion-controlled process.
A
composite waveform 1301 may be determined.
As illustrated, the graphene fiber electrode, made in accordance with the disclosure described herein, is able to record spontaneous neural activity from one of the terminal branches of the spleenic nerve. As illustrated in the panel 1401, the test involves the recording of baseline activity for 2 min. After that an intravenous injection of nitroprusside (NPS) a vasodilator drug that reduces the blood pressure is administered (green arrow shows the time of injection). Approximately 1 min after the injection, a high amplitude neural activity is recorded from the graphene electrode (white vertical traces). Off-line analysis shows two specific waveforms in that evoked activity. One waveform is illustrated at 1403 that appeared 367 times after the NPS, with high incidence prior to 1000 seconds and relatively low frequencies, and the other waveform illustrated in 1409 observed 52 times that appeared at lower frequencies. Also illustrated is the power spectrum signal 14-7 and 1413, and frequency 1405 and 1411, respectively. Figure 14 demonstrates the ability to record physiological relevant neural signals in the spleen using the graphene fiber electrode wrapped around this small (60-80 micrometer) size nerve.
= 20 and 40 pm). Panel A of Figure 20 provides modulus impedance of microelectrodes.
Panel B of Figure 20 provides phase angle of impedance of microelectrodes.
Panel C of Figure 20 provides CVs of the microelectrodes at 10 mV s-1 in PBS solution.
Panel D of Figure 20 provides water window of the microelectrodes. Panel E of Figure 20 provides voltage transient test of microelectrodes. Panel F of Figure 20 provides a comparison of the charge injection capacity, specific impedance at 1 kHz, and geometrical area of the modified microelectrodes with conventional neural interfacing electrodes.
Panels G
and H of Figure 21 show the CV of the modified microelectrodes after successive bending and prolonged PBS soaking, respectively. Number of repeats is four independent tests.
PERIPHERAL NERVOUS SYSTEM NEURONS USING GRAPHENE ELECTRODES
(-372 mC/cm2) and low impedance (-20 Me), however the stiffness of the metal shafts and delamination of the carbon nanotube coating limits the chronic use of these electrodes. The production of graphene fibers from liquid crystalline dispersions of graphene oxide (LCGO) demonstrated excellent electrochemical and mechanical characteristics.
Electrodes built in accordance with the present disclosure are used to record brain and peripheral nerve activity.
Single fibers and multi-electrode arrays were implanted in the motor cortex and sciatic nerve of adult rats (n=5). The electrodes effectively recorded single neuronal units, with excellent SNR. Together, the data supports the use of graphene fibers as intraneural electrodes for the neural interfacing of brain and peripheral nerve activity.
4: INTRA AND EXTRANEURAL ACTIVITY IN THE VAGUS
NERVE RECORDED BY PLATINIZED GRAPHENE FIBER ELECTRODES
Interfacing the vagus nerve (VN) allows researchers to decode and modulate its activity. FDA approved clinical therapies based on VN stimulation include drug resistant epilepsy and depression, and the vagus nerve is currently being investigated for morbid obesity, tinnitus and stroke. The VN has a heterogeneous anatomical composition (-80%
afferents and ¨20% efferent fibers) resulting in complex functional electrophysiology that responds in a unique way to different physiological stimulus. Conventional electrodes to interface the VN are fabricated with platinum or platinum iridium and have limited sensitivity and low charge injection capacity (Qinj, ¨0.05-0.26 mC/cm2), whereas intraneural electrodes fabricated with carbon nanotubes have shown promise (CSC ¨372 mC/cm2, 12.5 kS2).
and in order to use them to record evoked electrophysiological activity in both, extraneural and intraneural configurations during: i) systemic reduction in Oxygen tension, ii) decreased mean arterial pressure induced by intravenous nitroprusside treatment, and iii) evoked activity in response to proximal VN stimulation using a platinum hook electrode. Specific activity waveforms and activity patterns were correlated to the treatments over baseline conditions with high signal to noise ratios (SNR-4.3). The data supports the use of platinized graphene fibers as extraneural and intraneural electrodes for interfacing the VN.
In particular, using LCGO 2601 followed by an extrusion in a coagulation bath 2603, graphene fibers 2605 are developed, cut 2607, coated with metal (i.e., platinum) 2609, coated with an insulating material (i.e., Parylene-C) to form a GF-Pt microelectrode 2611. A SEM image of the microelectrode is provided 2613.
Electrical activity from the vagus nerve 2709 was recorded and provided to researchers 2711.
Nitroprusside was administered 2713 via the femoral vein of the rat 2701.
Oxygenation measurements and/or blood pressure measurements were recorded 2715 at the femoral artery.
As shown in the top plots of Figure 29, the frequency and amplitude of compound action potentials increased as a function of intensity. As illustrated in the bottom panel, one wave form and its corresponding raster plot was identified.
PLATINIZED GRAPHENE FIBERS TO PERIPHERAL NERVES
microfiber and Pt microelectrodes, respectively. The Pt coating increases significantly the conductivity to from 200 to 460 S/cm of a 40 [tm GF fiber. Moreover, the cathodic charge storage capacity of the microelectrode, calculated from the CV, was 946 mC/cm2, a value ¨3 orders of magnitudes higher than Pt electrode and ¨ 2 times higher than the original GF
microfibers.
Unfortunately, these conventional cuff devices have relative thick walls (e.g., 280-600 p.m) needed to generate sufficient bending forces to keep them closed, which causes a significant foreign body response and epineurial fibrosis, negatively affecting the sensitivity of the interface. In addition, new clinical applications for the regulation of organ physiology involved in cardiac, respiratory, digestive and urinary conditions, focus on neuromodulation of autonomic peripheral nerves that are smaller and composed of fewer axons (i.e., approximately 600 axons averaging 2.5 p.m in the 60-80 p.m rat carotid sinus nerve). The nerve targets in these conditions also have a thinner epineurium, are formed mostly of unmyelinated axons and thus, likely more susceptible of damage by neurointerface devices.
The small nerve size of these targets, their fragile nature, and restricted areas for implantation, are driving the development of new implantable electrodes that are small, flexible and with sufficient charge injection capacity for efficient and safe nerve stimulation.
When used as cuffless electrodes the segment around the nerve is deinsulated before placing it around the nerve.
Panel A of Figure 36 illustrates the use of a needle 3601 where the nylon suture 3603 is tied to the GF-Pt. Panel B of Figure 36 illustrates an embodiment where the GP-Pt fiber is driven into the muscle 3605.
Alternatively, or additionally, metalized graphene fibers may also be produced by 3D
printing, extrusion, wet spinning and the like.
For example, unmodified or functionalized graphene fibers can be used to measure extracellular concentration of a number of metabolic and biochemical biomarkers. These include reactive oxygen species such as hydrogen peroxide and oxygen, as well as a number of important neurotransmitters including serotonin, dopamine, glutamate, gamma aminobutyric acid. Metabolic biomarker include glucose, caffeic acid, and estradiol. Further, these can be used as single biosensors or as multi-functional sensor array, and for a broad range of samples including serum, urine, sweat, saliva, and others alike.
Further, electrodes can be implanted inside, sutured through or over internal organs, including but not limited to, heart, lungs, stomach, liver, spleen, pancreas and other pelvic organs.
From these recording and evoking their activity, for example the contribution of specific groups of nerve fiber types to the compound action potentials including A-alpha, A-beta, A-gamma, A-delta/B, and C fibers may be estimated. Further, stimulation of the splenic nerve may be used to neuromodulate the physiological activity of the spleen, including the release of inflammatory cytokines, which may be beneficial as a bioelectronic medical approach for diseases including Reumatoid Arthritis and Cronn's and the like.
Embodiments built in accordance with the present disclosure may be used to stimulate a number of tissues in the body including nerves and muscles for the prevention of muscle atrophy age-related, in rehabilitation to recover movements in limbs in paraplegic patients and in those treatments that require punctual electrical stimulation, such as tibial nerve stimulation and pelvic floor for the treatment of urinary incontinence and stimulation of muscles in the knee for osteoarthritis. Further, embodiments built in accordance with the present disclosure may also be used as bidirectional link with robotic prosthetic devices, peripheral neuromodulation and bioelectronic medicine applications.
Optionally, electrodes built in accordance with the disclosure herein may be used to stimulate a set of electrically responsive cells including neurons and muscles cells by sending a current through one or multiple implantable electrode. Additionally, activity from electrogenic cells including neurons and muscle cells by via the implantable electrodes built in accordance with the disclosures herein.
Claims (20)
a multi-layer graphene-fiber core;
an insulative coating surrounding the multi-layer graphene-fiber core; and a metal layer disposed between the multi-layer graphene-fiber core and the insulative coating.
forming a multi-layered graphene-fiber core by performing an in-situ reduction of fully ordered graphene oxide sheets in a liquid crystalline;
coating at least a portion of the multi-layered graphene-fiber core with a metal layer;
and coating the multi-layered graphene-fiber core and metal layer with an insulative coating.
exposing and isolating a target nerve from the surrounding tissue;
engaging an implantable electrode to the target nerve by at least one of passing the implantable electrode about the exposed target nerve and forming a knot with implantable electrode, and inserting the implantable electrode through the epineurium of the exposed target nerve, wherein the implantable electrode further comprises a multi-layer graphene-fiber core, an insulative coating surrounding the multi-layer graphene fiber core, and a metal layer disposed between the multi-layer graphene-fiber core and the insulative coating; and at least one of recording and stimulating from the peripheral nerve.
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| WO2024215255A1 (en) * | 2023-04-11 | 2024-10-17 | National University Of Singapore | Neural electrode, neural device and methods of fabrication thereof |
| CN116849667A (en) * | 2023-07-03 | 2023-10-10 | 北京大学 | Microelectrode and preparation method thereof |
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