COCHLEAR ELECTRODE ARRAY
A cochlear lead includes a plurality of electrode assemblies partially embedded in a flexible body configured to stimulate an auditory nerve from within a cochlea. Each of the electrode assemblies includes a flexible electrically conductive material forming a plurality of support structures and an electrode pad attached a support structure, the electrode pad having a surface that is configured to be exposed to cochlear tissue and fluids and has a charge transfer to the cochlear tissue and fluids that is higher than the flexible electrically conductive material.
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The present application claims the priority of U.S. patent application Ser. No. 13/516,982 (now issued as 9056196) and claims priority under 35 U.S.C. 119(a)-(d) or (f) and under C.F.R. 1.55(a) of previous International Patent Application No.: PCT/US2010/060306, filed Dec. 14, 2010, entitled “Cochlear Electrode Array” which claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application No. 61/288,201, entitled “Cochlear Electrode Array” filed Dec. 18, 2009, which applications are incorporated herein by reference in their entirety.
BACKGROUNDIn human hearing, hair cells in the cochlea respond to sound waves and produce corresponding auditory nerve impulses. These nerve impulses are then conducted to the brain and perceived as sound.
Damage to the hair cells results in loss of hearing because sound energy which is received by the cochlea is not transduced into auditory nerve impulses. This type of hearing loss is called sensorineural deafness. To overcome sensorineural deafness, cochlear implant systems, or cochlear prostheses, have been developed. These cochlear implant systems bypass the defective or missing hair cells located in the cochlea by presenting electrical stimulation directly to the ganglion cells in the cochlea. This electrical stimulation is supplied by an electrode array which is implanted in the cochlea. The ganglion cells then generate nerve impulses which are transmitted through the auditory nerve to the brain. This leads to the perception of sound in the brain and provides at least partial restoration of hearing function.
The accompanying drawings illustrate various embodiments of the principles described herein and are a part of the specification. The illustrated embodiments are merely examples and do not limit the scope of the claims.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
DETAILED DESCRIPTIONAs mentioned above, individuals with hearing loss can be assisted by a number of hearing devices, including cochlear implants. Cochlear implants are made up of both external and implanted components. The external components detect environmental sounds and convert the sounds into acoustic signals. These acoustic signals are separated into a number of parallel channels of information, each representing a narrow band of frequencies within the perceived audio spectrum. Ideally, each channel of information should be conveyed selectively to a subset of auditory nerve cells that normally transmit information about that frequency band to the brain. Those nerve cells are arranged in an orderly tonotopic sequence, from the highest frequencies at the basal end of the cochlear spiral to progressively lower frequencies towards the apex. An electrode array is inserted into the cochlea and has a number of electrodes which corresponded to the tonotopic organization of the cochlea. Electrical signals are transmitted through a wire to each of the electrodes in the electrical array. When an electrode is energized, it transfers the electrical charge to the surrounding fluids and tissues. This triggers the ganglion cells to generate nerve impulses which are conveyed through the auditory nerve to the brain and perceived as sound.
In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present systems and methods. It will be apparent, however, to one skilled in the art that the present systems and methods may be practiced without these specific details. Reference in the specification to “an embodiment,” “an example,” or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment or example is included in at least that one embodiment, but not necessarily in other embodiments. The various instances of the phrase “in one embodiment” or similar phrases in various places in the specification are not necessarily all referring to the same embodiment.
A cochlear electrode array is a thin, elongated, flexible carrier containing several longitudinally disposed and separately connected stimulating electrode contacts, conventionally numbering about 6 to 30. According to one illustrative embodiment, the electrode array may be constructed out of biocompatible silicone, platinum-iridium wires, and platinum electrodes. This gives the distal portion of the lead the flexibility to curve around the helical interior of the cochlea.
To place the electrode array into the cochlea, the electrode array may be inserted through a cochleostomy or via a surgical opening made in the round window of the cochlea. The electrode array is inserted through the opening into the scala tympani, one of the three parallel ducts that make up the spiral-shaped cochlea. The electrode array is typically inserted into the scala tympani duct in the cochlea to a depth of about 13 to 30 mm.
In use, the cochlear electrode array delivers electrical current into the fluids and tissues immediately surrounding the individual electrode contacts to create transient potential gradients that, if sufficiently strong, cause the nearby auditory nerve fibers to generate action potentials. The auditory nerve fibers branch from cell bodies located in the spiral ganglion, which lies in the modiolus, adjacent to the inside wall of the scala tympani. The density of electrical current flowing through volume conductors such as tissues and fluids tends to be highest near the electrode contact that is the source of such current. Consequently, stimulation at one contact site tends to selectively activate those spiral ganglion cells and their auditory nerve fibers that are closest to that contact site.
Improved charge transfer from the surface of the electrode to the surrounding fluid and tissues reduces impedances and improves battery life of the cochlear implant system. While smooth platinum is a reliable stimulating surface for cochlear implants, it has been discovered that there are other biocompatible materials and surface structures that have better charge transfer between the electrode and surrounding tissues. One of these materials is activated iridium. To activate iridium, the iridium surface undergoes a number of electrochemical cycles in a water-based electrolyte to develop an “activated” iridium oxide surface that is superior to platinum for charge transfer.
However, iridium is a relatively brittle material compared to platinum. As a consequence, iridium may be less suitable for other electrode manufacturing steps which are used to form some types of cochlear electrode arrays. The new techniques and structures described below maximize the charge transfer of the electrode surface while maintaining the manufacturability of the electrode arrays. These automated or semi-automated techniques also minimize part-to-part variability and defects which result from less controlled manual processes.
As indicated above, the cochlear implant (300) is a surgically implanted electronic device that provides a sense of sound to a person who is profoundly deaf or severely hard of hearing. In many cases, deafness is caused by the absence or destruction of the hair cells in the cochlea, i.e., sensorineural hearing loss. In the absence of properly functioning hair cells, there is no way auditory nerve impulses can be directly generated from ambient sound. Thus, conventional hearing aids, which amplify external sound waves, provide no benefit to persons suffering from complete sensorineural hearing loss.
As discussed above, the cochlear implant (300) does not amplify sound, but works by directly stimulating the auditory nerve (160) with electrical impulses representing the ambient acoustic sound. Cochlear prosthesis typically involves the implantation of electrodes into the cochlea. The cochlear implant operates by direct electrical stimulation of the auditory nerve cells, bypassing the defective cochlear hair cells that normally transduce acoustic energy into electrical energy.
External components (200) of the cochlear implant system can include a Behind-The-Ear (BTE) unit (175), which contains the sound processor and has a microphone (170), a cable (177), and a transmitter (180). The microphone (170) picks up sound from the environment and converts it into electrical impulses. The sound processor within the BTE unit (175) selectively filters and manipulates the electrical impulses and sends the processed electrical signals through the cable (177) to the transmitter (180). The transmitter (180) receives the processed electrical signals from the processor and transmits them to the implanted antenna (187) by electromagnetic transmission. In some cochlear implant systems, the transmitter (180) is held in place by magnetic interaction with a magnet in the center of the underlying antenna (187).
The components of the cochlear implant (300) include an internal processor (185), an antenna (187), and a cochlear lead (190) which terminates in an electrode array (195). The internal processor (185) and antenna (187) are secured beneath the user's skin, typically above and behind the pinna (110). The antenna (187) receives signals and power from the transmitter (180). The internal processor (185) receives these signals and performs one or more operations on the signals to generate modified signals. These modified signals are then sent along a number of delicate wires which pass through the cochlear lead (190). These wires are individually connected to the electrodes in the electrode array (195). The electrode array (195) is implanted within the cochlea (150) and provides electrical stimulation to the auditory nerve (160).
The cochlear implant (300) stimulates different portions of the cochlea (150) according to the frequencies detected by the microphone (170), just as a normal functioning ear would experience stimulation at different portions of the cochlea depending on the frequency of sound vibrating the liquid within the cochlea (150). This allows the brain to interpret the frequency of the sound as if the hair cells of the basilar membrane were functioning properly.
The illustrative cochlear lead (190) includes a lead body (445). The lead body (445) connects the electrode array (195) to the internal processor (185,
The wires (455) that conduct electrical signals are connected to the electrodes (465, 470) within the electrode array (195). For example, electrical signals which correspond to a low frequency sound may be communicated via a first wire to an electrode near the tip (440) of the electrode array (195). Electrical signals which correspond to a high frequency sound may be communicated by a second wire to an electrode (465) near the base of the electrode array (195). According to one illustrative embodiment, there may be one wire (455) for each electrode within the electrode array (195). The internal processor (185,
According to one illustrative embodiment, the wires (455) and portions of the electrodes (470) are encased in a flexible body (475). The flexible body (475) may be formed from a variety of biocompatible materials, including, but not limited to medical grade silicone rubber. The flexible body (475) secures and protects the wires (455) and electrodes (465, 470). The flexible body (475) allows the electrode array (195) to bend and conform to the geometry of the cochlea.
Each electrode pad (512) is tethered to rails (504) by two tethers (506). As used in the specification and appended claims, the term “tether” or “tethered” refers to a connection between an electrode and the structure that holds the electrodes in a fixed spatial relationship with other electrodes. Ordinarily, the tether (506) has a relatively small cross-section compared to the electrode pad (512) and connects the perimeter of the electrode pad (512) and the rails (504). The tethers (506) can hold the electrode pads (512) rigidly in place to completely fix the electrode spacing or semi-rigidly such that they are close to their final spacing and can be put into an alignment fixture to adjust the final spacing. In one embodiment, tether widths are between 50 and 250 microns and lengths of the tethers are between 100 and 500 microns. According to one illustrative embodiment, the electrode pads (512) and tethers (506) are formed from a single sheet of high charge transfer material.
According to one illustrative embodiment, the high charge transfer material may be iridium or an iridium alloy. For example, iridium could be activated by exposing it to a number of electrochemical cycles in a water-based electrolyte to develop an activated iridium oxide surface. This activated iridium oxide surface has a higher area and greater charge transfer characteristics than the underlying iridium material. The electrochemical activation of the iridium surface could be performed before or after the assembly of the electrode array.
The high charge transfer material may be patterned using a number of techniques including, but not limited to, short pulse laser micromachining techniques. As used in the specification and appended claims, the term “short pulse” means pulses less than a nanosecond, such as in the femtosecond to hundreds of picosecond range. A variety of lasers can be used. For example, very short pulse laser machining may be performed using a picosecond laser, at UV, visible, or IR wavelengths. These very short pulse lasers can provide superior micromachining compared with longer pulse lasers. The very short pulse lasers ablate portions of the material without significant transfer of heat to surrounding areas. This allows the very short pulse lasers to machine fine details and leaves the unablated material in essentially its original state.
The set (516) of tethered electrode pads (512) is fixed to a sacrificial substrate (502). According to one illustrative embodiment, the sacrificial substrate (502) may be an iron strip which is approximately the width of the electrode pads (512) and at least as long as the tethered set (516) of electrode pads. The tethered set (516) of electrode pads may be attached to the sacrificial substrate (502) in a variety of ways, including resistance welding or laser welding. One or more weld joints (508) can be made for each electrode pad (512). The spacing of the electrode pads (512) is initially maintained by the tethers (506). The tethers (506) are cut after the welds (508) are formed. According to one illustrative embodiment, the tethers (506) are cut at or near the dotted lines (514). After the tethers (506) are cut, the iron strip (502) maintains the desired electrode pad (512) spacing and orientation.
As discussed above, after the tethers (506,
The dashed trapezoid illustrates the wing portions (525), which will be folded up to contain the wires. The wings (525) may have several additional features, such as holes (515). According to one illustrative embodiment, during a later manufacturing step, a fluid matrix such as liquid silicone rubber is injected into a mold which contains the electrodes and their associated wiring. The fluid matrix flows through the holes (515), and then cures to form the flexible body. The holes (515) provide a closed geometry through which the fluid matrix can grip the electrode assembly.
A second dashed rectangle outlines a flap (530), which will be folded over a wire and welded to mechanically secure it to the electrode. This wire provides electrical energy to the electrode. The spacing (535) of the winged tabs (513) along the rails (505) matches the pitch of the underlying electrode pads (512,
One or more welds (524) are made to join each of the winged tabs (513) to the underlying electrode pads (512,
According to one illustrative embodiment, all of the electrode assemblies for a single cochlear implant are machined from the two sheets of conductive material, one flexible sheet of material and the other high charge transfer sheet of material. For example, the electrode pads and winged tabs can be machined from a flexible sheet of conductive material at their desired spacing in the cochlear lead and be held in place to an outer frame by small tethers. The winged tabs can be formed with a number of features that facilitate the final assembly of the cochlear lead. As discussed above, precision short pulse laser machining and automated alignment of the components can reduce the amount of manual work required and improve yields.
The curable liquid fills voids within the composite electrode assembly (902) and entirely encapsulates it except for one surface of the electrode pad (512). This allows the electrode pad (512) of each composite electrode assembly (902) to contact the tissue in the cochlea where each electrode is located after inserting the lead into the cochlea. The high charge transfer at the surface of the electrode pad (512) provides for more efficient stimulation of the cochlear tissue than if the conductive material of the winged tab were used as the stimulating surface.
The tethered set (511) of electrode pads is aligned with the winged tabs (513) and then fastened in place. As discussed above, one method of fastening the winged tabs (513) and the electrodes together is resistance or laser spot welding. The tethers (506) can then be cut or broken along the dashed line (514).
Although a sacrificial strip (502) is illustrated as a means for holding the winged tabs (513) and electrode pads (512) in place, a wide variety of other techniques could be used. For example, the winged tabs (513) and/or electrode pads (512) could be placed on an adhesive surface. The adhesive surface would hold the various components in place through the assembly process. The adhesive surface could then be removed mechanically or chemically. For example, a solvent such as acetone or isopropyl alcohol could be used to facilitate the removal of the adhesive surface. Additionally or alternatively, a wax or other compliant surface could be used to hold the various components in place. For example, the winged tabs could be pressed into a wax surface or other deformable surface. After the assembly process, the wax could be removed by heating.
After the designated wire (1305) is secured in place, the wings can be folded up to form a wire bundle (1310) which contains the wires which continue through the cochlear electrode array to provide current to other electrodes. The sacrificial substrate can then be removed and the entire electrode array can be partially encased in a silicone rubber body (1300), leaving the outer surface of electrode pad (512) exposed through the central aperture (523).
This alternative method may have a number of advantages. For example, the electrode surface is somewhat recessed, which may protect it from damage. Additionally, because the electrode pads are not welded to the sacrificial strip and are not bent during the assembly process, more fragile surface layers can be used on the electrode pads to improve the charge transfer of the electrode.
Platinum black is a fine powder of platinum which can be deposited over a solid platinum substrate. This process produces a surface area which is much higher than the geometric surface area of the underlying substrate and exhibits charge transfer characteristics which are superior to non-textured platinum surfaces. The platinum particles are typically sprayed or hot pressed onto the substrate layer. According to one illustrative embodiment, platinum black may be electroplated onto a platinum substrate. The platinum substrate is first cleaned, and then placed in a water solution which contains chloroplantanic acid and lead acetate. An electrical current is then passed through the water solution such that chlorine evolves at the anode and deposits platinum black particles on the platinum substrate.
While iridium oxide films are known to have charge transfer characteristics which are superior to most forms of platinum, the iridium oxide films are also known to be brittle and have delaminating problems when the underlying surface is bent. To avoid this, the films and structures described above could be deposited on the electrode substrate (1405) which is not required to flex during the manufacture or use of the electrode array.
Many of these films and structures could be damaged if they were directly deposited or produced on a winged tab which is then folded into the electrode/wire carrier configuration. For example, structured platinum, such as platinum black, platinum gray, sintered platinum, platinum nanoparticles, and platinum metal sponges can all be sensitive to folding or welding of the underlying substrate, tending to crack or delaminate from the substrate.
According to one illustrative embodiment, the electrode pad (512) may be a layer that is deposited directly on the bottom of the winged tab rather than on a separate piece of material. For example, the electrode pad (512) may be formed by depositing iridium on the base of a platinum winged tab. This deposition could be carried out by electroplating, electroless plating, sputter coating, vapor phase deposition, pulsed laser deposition, or other suitable methods. According to one illustrative embodiment, an iridium oxide film is sputtered onto the surface using DC reactive sputtering from an iridium metal target in an oxidizing environment. The thickness of the sputtered film may be from about 100 nanometers to several microns. This can result in a charge-injection capacity which is between 1 and 9 mC/cm̂2, which is comparable to an activated iridium oxide electrode pad. Additionally or alternatively, an iridium film may be deposited onto the surface and subsequently activated as described above.
According to one illustrative embodiment, iridium oxide nanoparticles could be joined to form a high surface area layer (1410) over the electrode substrate (1405). A wide variety of iridium oxide nanoparticles could be used, including nanoparticles which are spherical, faceted, nanorods, nanowhiskers, nanopyramids, and other shapes. Iridium oxide nanoshapes with a size between 20 and 80 nanometers can have a surface area of 10 to 50 square meters per gram. Larger nanoshapes which have a size of 100 nanometers can have surface areas of approximately 7 to 10 square meters per gram. These high surface areas, combined with the intrinsically high charge transfer characteristics of the iridium oxide can produce an electrode with a very high rate of charge transfer. These iridium oxide nanoparticles could be joined by sintering, embedding in a matrix, or by other means. In other embodiments, the iridium oxide nanoparticles could be grown directly on an iridium oxide substrate.
A variety of techniques and materials can be used to improve the mechanical and electrical properties of the thin films and structures. According to one illustrative embodiment, an iridium oxide thin film is deposited over a roughened platinum surface. For example, a platinum gray layer may be deposited over the platinum substrate (1405). This produces a microporous structure over the platinum which has good adhesion to the underlying platinum substrate. An iridium oxide thin film layer may then be deposited over the high surface area platinum gray layer. Because the iridium oxide thin film is deposited on a textured surface, its surface area and its adhesion to the surface is increased.
Additionally or alternatively, the adhesion of a sputtered iridium oxide layer may be improved by initially sputtering a combination of platinum and iridium oxide onto a platinum substrate (1405), and then gradually changing the composition to include more iridium oxide until only iridium oxide is deposited. This graduated coating may improve the adhesion and charge transfer between the platinum substrate (1405) and the iridium layer (1410).
As described above in
The tethered set of electrode pads is attached to the set of winged tabs such that an electrode pad covers the central aperture in each winged tab and the tethers are cut from the electrode pads (step 1520). The wires are attached to the winged tabs by folding a tab over a selected wire and welding the wire in place. The remaining wires are formed into a bundle by folding up the wings (step 1525). This process is repeated for each electrode assembly in the array until all of the wires are connected to an electrode pad and properly formed into the wire bundle. The sacrificial substrate can then be removed and the electrode array encapsulated (step 1530).
The process described above is only one illustrative method for forming a cochlear electrode array. The steps may be performed in a variety of orders and a number of additional steps may be used. For example, step 1515 can occur any time before step 1520. Additional steps, such as surface preparation, testing, or other steps, can be included in the process.
The preceding description has been presented only to illustrate and describe embodiments and examples of the principles described. This description is not intended to be exhaustive or to limit these principles to any precise form disclosed. Many modifications and variations are possible in light of the above teaching.
Claims
1. A method of forming a charge transferring surface, the method comprising:
- partially encapsulating an electrode in a flexible body; and
- subsequently electrochemically activating a first exposed portion of the electrode to form an iridium oxide surface, the iridium oxide surface having a greater charge transfer density than an unactivated exposed portion of the electrode.
2. The method of claim 1 wherein the first exposed portion of the electrode is in a recess and the iridium oxide surface does not extend beyond the recess.
3. The method of claim 1, further comprising a second exposed portion of the electrode in electrical contact with the first exposed portion of the electrode, wherein the second exposed portion of the electrode does not form an iridium oxide surface when exposed to the same electrochemical activation as the first exposed portion.
4. The method of claim 3, wherein the first exposed portion of the electrode is part of an electrode pad comprising iridium and the second exposed portion of the electrode is part of a winged tab.
5. The method of claim 3, wherein the second exposed portion of the electrode is composed of platinum.
6. The method of claim 3, wherein the first exposed portion is a bottom surface of a recess, the second exposed portion is a side of the recess, and the iridium oxide surface does not extend beyond the recess.
7. The method of claim 3, wherein a connection between the first exposed portion and the second exposed portion of the electrode is free of activated iridium oxide.
8. A method for controlling element separation in a physical array, the method comprising:
- fixing multiple tethered electrode array elements to a temporary substrate with predetermined separations between the multiple tethered electrode array elements;
- removing tethers of the multiple tethered electrode array elements to form multiple untethered electrode array elements;
- forming a flexible body that connects the multiple untethered electrode array elements at the predetermined separations; and
- separating the temporary substrate from the multiple untethered electrode array elements.
9. The method of claim 8, wherein separating the temporary substrate from the multiple untethered electrode array elements comprises dissolving a portion the temporary substrate.
10. A method for forming an electrode in a cochlear electrode array, comprising:
- forming a first foil of electrically conductive material into a set of winged tabs;
- forming a second foil into a set of electrode pads;
- fixing a sacrificial substrate to one of: a winged tab and an electrode pad;
- attaching the set of winged tabs and the set of electrode pads together; and
- electrically connecting a selected wire to each of the winged tabs.
11. The method of claim 10, further comprising:
- bending a wing of each winged tab to constrain additional wires passing over the winged tab to form a wire bundle;
- removing the sacrificial substrate to form an electrode assembly; and
- partially encapsulating the electrode assembly in a flexible polymer body.
12. The method of claim 10, in which forming the first and second foil comprises short pulse laser machining
13. The method of claim 10, in which forming the first foil comprises forming a tethered set of winged tabs and forming a second foil comprises forming a tethered set of electrode pads.
14. The method of claim 13, further comprising cutting tethers of the tethered set of winged tabs after attaching the winged tabs and the electrode pads together.
15. The method of claim 10, in which the sacrificial substrate comprises an iron strip.
16. The method of claim 10, further comprising electrochemically activating an iridium material by subjecting a surface of the iridium material to a number of electrochemical cycles in a water-based electrolyte such that the surface of the iridium material develops an activated iridium oxide layer which has electrical charge transfer which is superior to the electrically conductive material which makes up the set of winged tabs.
17. The method of claim 10, in which the electrode pad is first attached to the sacrificial substrate and then attaching the winged tab and the electrode pad together.
18. The method of claim 10, further comprising:
- forming an aperture in the winged tab;
- attaching the winged tab to the sacrificial substrate; and
- attaching the electrode pad over the aperture in the winged tab.
19. The method of claim 10, in which the electrode pad and winged tab are attached using a resistance weld.
20. The method of claim 10, in which the electrode pads comprise a surface modified to be exposed to cochlear tissue and fluid, the surface having a charge transfer to the cochlear tissue and fluid that is higher than that of an unmodified substrate material.
Type: Application
Filed: Jun 9, 2015
Publication Date: Sep 24, 2015
Applicant: ADVANCED BIONICS LLC (VALENCIA, CA)
Inventors: CHULADATTA THENUWARA (CASTAIC, CA), TIMOTHY BEERLING (SAN FRANCISCO, CA)
Application Number: 14/735,000