|Publication number||US3699970 A|
|Publication date||24 Oct 1972|
|Filing date||23 Jun 1970|
|Priority date||26 Jun 1969|
|Publication number||US 3699970 A, US 3699970A, US-A-3699970, US3699970 A, US3699970A|
|Inventors||Brindley Giles Skey, Donaldson Peter Eden Kirwan|
|Original Assignee||Nat Res Dev|
|Export Citation||BiBTeX, EndNote, RefMan|
|Referenced by (102), Classifications (10)|
|External Links: USPTO, USPTO Assignment, Espacenet|
United States Patent Brindley et al. 1 Oct. 24, 1972 154 STRIATE CORTEX STIMULATOR 3,449,768 6/1969 D6 16 .'....3/1  Inventors: Giles skey Brindley, London; Peter 2,784,375 5/1957 Mehlman ..324/57Q bEde: dvonaldm, Oxford, FOREIGN PATENTS OR APPLICATIONS 0t 0 n an 7 575,075 4/1924 France ..128/419 R  As ign g g z g 1,910,972 10/1969 Germany ..12s/404 orpora on, on on, n an Primary Examiner-William E. Kamm 2 1970 2 led o gj Attorrwy-Cushman, Darby & Cushman  Appl.No.: 49, 1
 ABSTRACT Foreign pp Priority Data An implantable neurological prosthetic device com- June 26 1969 Great Britain "3239859 prises a plurality of electrodes for stimulating the striate cortex, a matrix of normally closed gates con- 1 R 3 1, 324 57, nected in one-to-one relationship with said electrodes,  US. Cl 128/4 9 3340/4107 and a plurality of radio receivers tuned to predeteb [511 I t Cl A61 mined frequencies and constituting at least two  F t ld a 159 410 1 .di ting y9 ets, each gate being connected for e I' 7 switching to an open state to energize the respective Q 57 343/703- 4 "ohm said-electrodes by a unique group of at least ,1, a. v I two of said receivers from respectively different sets thereof. The receivers are themselves energizable by  References Cited externally located respective transmitters conveniently UNITED STATES PATENTS positioned by a technique in which the transmitter tuned circuit is included as one arm in a bridge circuit 3,195,540 7/1965 Waller ..l28/419 P balanced. for maximum absorption by the respective 3,491,377 l/l970 Bolle ..3/l mceiver tuned circuit. This technique is more 1 21 23232 genegall y applicable to any implant provided with a 6 6 6 6 6 v n 6 n Q 3,426,748 2/1969 Bowers ..l28/4l9 P 2,721,316 10/1955 Shaw ..3/1 8 Claims, 2 Drawing Figures 1 a ,1 7 EN APSULATEI Dfi B} E11 E1? 1-? 511 l "IN ANATOMICALLI D2 c1 R1 1 SHAPED MOULD OF R R SILICONE lauseEiz r (3 lit musmrrsk '2 0 POWER SOURCE PR POWER SOURCE TRANSMITTER-S P ATENTED 0m 24 I972 ENCAPSULATED-/- RB IN ANATOMICA LLY D2 T SHAPED MOULO 0F SILICONE RUBBER P WER SOU RCE PC, PR
POWER SOUQCE STRIATE CORTEX STIMULATOR Consideration has been given to the possibility of producing a prosthesis which will afford electrical stimulation of the striate cortex and give useful visual sensations to patients who have lost the use of their eyes. Initial work to this end has proved promising. Briefly, this work involved the implantation of an array of radio-driven stimulators. The implant comprised an intracranial part and an extracranial part. The intracranial part had the form of a cap of silicone rubber, molded to fit the calcarine and neighboring cortex of the right hemisphere, and bearing a plurality of platinum electrodes. The electrodes were joined in a one-to-one relationship by a cable to the extracranial part which comprised an array of radio receivers between the parieto-occipital skull and pericranium. Delivery of a train of short pulses of radio waves to one of the receivers resulted in the patient seeing a small spot of white light, or phosphene, while simultaneous delivery to a number of receivers produced a pattern of phosphenes. In practice, it was proposed that delivery to such a device be affected by a corresponding array of radio transmitters housed in a cap or hat for the patient.
Various aspects of the above work are discussed in more detail in articles entitled Transmission of electrical stimuli along many independent channels through a fairly small area of intact skin by G.S. Brindley (J. Physiol. 177, 44-46P), The visual sensations produced by electrical stimulation of the medical occipital cortex" by G.S. Brindley and W.S. Lewin (J. Physiol. 194, 54-55P), and The sensations produced by electrical stimulation of the visual cortex by 0.8. Brindley and W.S.,Lewin (J. Physiol. 196, pp.479493 Clearly a useful endeavor of this kind will involve a large number of stimulating electrodes, and corresponding numbers of receivers and transmitters.
According to the present invention in one aspect, the number of receivers in such a device, and by the same token the number of associated transmitters also, is reduced by employing a selection matrix arrangement for controlling the energization of the electrodes. Thus, a matrix of gate circuits is provided for connection to the stimulating electrodes, each gate being controlled by a unique group of receivers, one each from at least two sets of receivers connected with the matrix of gates in respectively different co-ordinate senses.
Selection matrix arrangements are in fact known in other applications and it is usual to talk of rows and columns in the matrix since the matrix is normally thought of as a two-dimensional, rectangular one with Cartesian coordinates. Reference is accordingly made hereinafter to rows and columns, but it is to be understood that this is for convenience only since the physical lay-out need not be rectangular and there can be more than two dimensions.
In any event, a clearer understanding of this aspect of the invention will be gathered from the following consideration of the accompanying drawings which are given by way of example, and in which:
FIG. 1 illustrates the circuit, partly schematically, of one embodiment of the invention, and
FIG. 2 similarly illustrates a further circuit ancillary to that of FIG. 1.
In FIG. 1, three row conductors R1, R2, R3 and three column conductors CLl, CL2, and CL3 are shown affording control of nine gates by way of six receivers. Three of the receivers RRI, RR2, RR3 are respectively connected to the row conductors R1, R2, R3 and the other three receivers RC1, RC2, RC3 are respectively connected to the column conductors CLl, CL2, and CL3. Gate G11 is connected to row conductor R1 and column conductor CLl, gate G12 is connected to row conductor R1 and column conductor CL2, and so on to gate G33 connected to row conductor R3 and column conductor CL3. Each gate is connected to a different one of nine stimulating electrodes denoted as terminals E11, E12, E33, and each electrode is energized by sending a radio signal to the row and column receivers to which the associated gate is connected. This energization is such that the row receiver connects the base of the gate transistor T1 to earth, while the column receiver lowers the emitter potential of that transistor, and so the gate is rendered conductive against the base electrode bias B which normally holds all of the gates non-conductive.
In operation of the device to produce. a pattern of phosphenes, it is necessary that the gates be controlled by a scanning action. For example, if only gates G11 and G22 are to be activated, receivers RRI and RC1 and, receivers RR2 and RC2 are involved, but simultaneous energization of these four receivers will also activate gates G12 and G21. Accordingly, the row receivers are energized on a sequential basis and the column receivers for any gates to be activated in a given row are selectively energized simultaneously with the receiver for that row. This may appear to be a practical disadvantage consequent upon the use of a selection matrix arrangement, but it is in fact fully compatible with the normal visual processes. Indeed, there is practical advantage in that compensation can be made for the different threshold energization appropriate to stimulation with different ones of the electrodes. Thus, the row receivers can be scanned with energization at a predetermined level, while the column receivers are selectively energized at variable levels. Alternatively, variation of column receiver duration of energization can be employed in place of power level.
This mode of operation is' indicated schematically in the drawing by the row transmitters TRl, TR2, TR3 and column transmitters TCl, TC2, TC3 which are tuned to match their respective receivers RRI, RR2, RR3 and RC1, RC2, RC3, and are respectively energizable from power sources PR and PC by way of selector switches SR and SC. It will be noted that the power source for the column transmitters is denoted as variable by an arrow, this denoting variability of transmitted pulse power level or duration.
In connection .with production of patterns rather than single phosphenes, it is desirable, particularly where different energization levels are to be involved, that adjacent column receivers be tuned to mutually different frequencies to avoid any cross-talk, and these frequencies should also differ from that, or those, of the row receivers.
In this same connection, it is to be understood that the primary input pattern can be derived from a television camera tube or other suitable form of sensor, the output of which is translated to appropriate signal form for energization of the transmitters to stimulate a corresponding pattern in the recipient. In general, the transmitters will normally energize the row receivers in sequence, each for a period during which any relevant associated column receivers are also energized, so giving a column scanning action within each phase of a row scanning action.
While various circuit arrangements may be employed for the receivers of the presently proposed device, and also for the associated receivers, the illustrated common emitter configuration is preferred for the gates.
For completeness, the component values of the illustrated example are as follows:
Transistors T1 currently have Vceo 60V.
Diodes D1 are currently chosen with p.i.v. 2 60V.
Zener diodes Z are 55V, that is, less than Vceo of T1.
The tunedcircuit coils are all wound from common material to 1 cm. diameter. Coils II for the rows are each wound to twelve turns and tapped at two turns for a frequency of Mc/s. Coils I2 and I3 are used in alternating sequence along the columns, I2 being wound to thirteen turns and-tapped at ten turns for a frequency of 8 Mc/s, and I3 being wound to seventeen turns and tapped at ten turns for a frequency of 6 Mc/s.
Turning to another aspect of the present invention: difficulty may arise in attaining the desired location of the transmitters relative to the receivers since the latter are implanted while the former are employed externally of the subject. The difficulty is not exclusive to the above-proposed visual prosthetic device, but it clearly becomes more significant when a number of inductive links are to be established within a small area. It might also be mentioned that this difficulty is not readily resolved by attempting to mark on a patients exteri or the locations of the implanted receivers.
A technique for obviating this difficulty has been evolved in. the course of the present work, which technique derives from the fact that the implant or implant item to be located in the present instance includes a tuned circuit, and there is a corresponding external tuned circuit in the associated transmitter. Location is achieved by connecting the external tuned circuit in a bridge circuit including a meter and arranged for balance when a corresponding tuned circuit is immediately adjacent that of the bridge. Thus, the bridge is balanced for maximum absorption from its tuned circuit and it can be used to locate the corresponding tuned circuit of an implant by watching the meter while scanning the patient with the tuned circuit.
This technique is naturally suitable when, as here, the tuned circuits are to be provided anyway, and this is indicated in FIG. 2 by the bridge circuit B in which the voltage to one side of the meter M is derived from the tuned circuit of the relevant transmitter.
The results with this technique have been found so satisfactory that tuned circuits, or an adjustable tuned circuit, might be provided specifically for the purposes of receiver location. Indeed the technique can be employed more generally in the location of implanted devices, and an absorption or rejection mode may be employed.
Accordingly, the present invention provides, in a second aspect, apparatus for locating an implant including a tuned circuit, the apparatus comprising a bridge circuit including a corresponding tuned circuit as one arm of the bridge, and means for indicating the degree of balance of the bridge. The indicating means need not necessarily be of visual form, such as a meter, but may alternatively, or in addition, be of audible form whereby a variable tone is generated in dependence upon the degree of bridge balance.
Yet'another aspect of the present invention involves the manufacture, and in particular the molding and encapsulation of implantable prosthetic devices. It is usual to encapsulate such devices with a silicone rubber material which is conventionally available as a paste in a tube. However, this form of material has not been found fully satisfactory in a situation such as that for the above form of device where the encapsulating material can also serve as a mold material to be formed to a required shape in which other components are carried. The necessary molding will often, as here, be best carried out by casting and a paste is clearly not suitable. Also, the usual paste material is only self-adhesive and not suitable for encapsulating complex physical shapes, such as an array of electrodes. Lastly, the usual paste material is somewhat hard when cured for the present purpose.
These difficulties have been reduced in accordance with the invention in its'last-mentioned aspect, by mixing a medical silicone rubber adhesive of paste form with a solvent to form a liquid adhesive, and adding an inert filler. Initially, the adhesive paste was simply mixed with the solvent, but this was found to be too thin and to leave cavities and voids after pouring and curing with consequent trapping of air and water. This is undesirable as a cause of electrical failure, and the filler is included to reduce this problem. As to the constituent proportions: these can be varied dependent on the hardness or softness of cured rubber required. However, it is useful to specify the constituents of the product found. generally satisfactory for the above purposes, namely Dow Corning Medical Adhesive Type A, Dow Corning Medical Fluid 360 and xylene in the respective proportions of nine inches, 5 c.c. and 10'c.c. This resultant adhesive does not shrink, distort, or absorb water.
1. An implantable device comprising a plurality of electrodes for stimulating the striate cortex, a matrix of normally closed gates connected in one-to-one relationship with said electrodes, and a plurality of radio receivers tuned to predetermined frequencies and constituting at least two distinctive sets, each gate being connected for switching to. an open state to' energize the respective one of said electrodes by a unique group of at least two of said receivers from respectively different sets thereof.
2. A device according to claim 1 wherein adjacent receivers in at least one set thereof are tuned to respectively different frequencies.
3. A device according to claim 1 wherein each of said gates comprises a semi-conductor switching device connected in the common emitter configuration.
4. A device according to claim 1 in combination with a plurality of radio transmitters respectively associated vbridge circuit.
6. A device according to claim 1 wherein said gates and said receivers are encapsulated'in an anatomically shaped mold of silicone rubber. I
7. In combination,
an implantable device including a plurality of electrodes for stimulating the striate cortex, a matrix of normally closed gates connected in one-to-one relationship with said electrodes, and a plurality of radio receivers-tuned to predetermined frequencies and constituting at least two distinctive sets, each gate being connected for' switching to an open state to energize the respective one of said electrodes by a unique group of at least two of said receivers from respectively different sets thereof, and
an exterior mounted device including a plurality of radio transmitters respectively associated with and tuned to common frequencies with said receivers in a one-to-one relationship, at least one set of said transmitters being energizable at a predetermined constant level, and the transmitters of at least one other set thereof being energizable at adjustable power levels, and means for mounting said exterior device on a body adjacent said implantable device.
8. In combination, an implantable device comprising a plurality of elecan exterior device including a bridge circuit having a tuned circuit in one arm thereof for matching one of said receivers, and means for indicating the degree of balance of said bridge circuit.
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US3848608 *||23 Jul 1973||19 Nov 1974||Gen Electric||Subject integument spatial stimulator|
|US3850161 *||9 Apr 1973||26 Nov 1974||Liss S||Method and apparatus for monitoring and counteracting excess brain electrical energy to prevent epileptic seizures and the like|
|US3918461 *||31 Jan 1974||11 Nov 1975||Cooper Irving S||Method for electrically stimulating the human brain|
|US4018218 *||12 Mar 1975||19 Apr 1977||Carlson James E||Method and apparatus for sleep induction|
|US4250637 *||13 Jun 1979||17 Feb 1981||Scott Instruments Company||Tactile aid to speech reception|
|US4354064 *||19 Feb 1980||12 Oct 1982||Scott Instruments Company||Vibratory aid for presbycusis|
|US4554928 *||16 Sep 1983||26 Nov 1985||Webster Wilton W Jr||Electrophysiological switching unit|
|US4603697 *||7 Jan 1985||5 Aug 1986||William Kamerling||System for preventing or treating open angle glaucoma and presbyopia|
|US4979508 *||11 Apr 1987||25 Dec 1990||Beck Stephen C||Apparatus for generating phosphenes|
|US6658299||4 Jan 2000||2 Dec 2003||William H. Dobelle||Artificial system for vision and the like|
|US7054689 *||13 Aug 2001||30 May 2006||Advanced Bionics Corporation||Fully implantable neurostimulator for autonomic nerve fiber stimulation as a therapy for urinary and bowel dysfunction|
|US7142909||6 Sep 2002||28 Nov 2006||Second Sight Medical Products, Inc.||Biocompatible bonding method and electronics package suitable for implantation|
|US7149586||28 Mar 2002||12 Dec 2006||Second Sight Medical Products, Inc.||Variable pitch electrode array|
|US7211103||17 Jun 2002||1 May 2007||Second Sight Medical Products, Inc.||Biocompatible bonding method and electronics package suitable for implantation|
|US7228181||6 Apr 2004||5 Jun 2007||Second Sight Medical Products, Inc.||Retinal prosthesis with side mounted inductive coil|
|US7257446||12 Oct 2001||14 Aug 2007||Second Sight Medical Products, Inc.||Package for an implantable medical device|
|US7645262||7 Sep 2006||12 Jan 2010||Second Sight Medical Products, Inc.||Biocompatible bonding method and electronics package suitable for implantation|
|US7725191||28 Oct 2007||25 May 2010||Second Sight Medical Products, Inc.||Package for an implantable device|
|US7794499||8 Jun 2004||14 Sep 2010||Theken Disc, L.L.C.||Prosthetic intervertebral spinal disc with integral microprocessor|
|US7813796||24 Jul 2006||12 Oct 2010||Second Sight Medical Products, Inc.||Biocompatible bonding method and electronics package suitable for implantation|
|US7835794||30 Oct 2007||16 Nov 2010||Second Sight Medical Products, Inc.||Electronics package suitable for implantation|
|US7835798||28 Oct 2007||16 Nov 2010||Second Sight Medical Products, Inc.||Electrode array for visual stimulation|
|US7840274||28 Oct 2007||23 Nov 2010||Second Sight Medical Products, Inc.||Visual color prosthesis|
|US7846285||26 Oct 2007||7 Dec 2010||Second Sight Medical Products, Inc.||Biocompatible electroplated interconnection bonding method and electronics package suitable for implantation|
|US7894911||17 Aug 2005||22 Feb 2011||Second Sight Medical Products, Inc.||Electrode array for neural stimulation|
|US7904148||7 Sep 2006||8 Mar 2011||Second Sight Medical Products, Inc.||Biocompatible bonding method and electronics package suitable for implantation|
|US7904164||23 Oct 2007||8 Mar 2011||Second Sight Medical Products, Inc.||Retinal prosthesis with side mounted inductive coil|
|US7908010||16 Oct 2007||15 Mar 2011||Second Sight Medical Products, Inc.||Retinal prosthesis with side mounted inductive coil|
|US7957810||28 Oct 2007||7 Jun 2011||Second Sight Medical Products, Inc.||Motion compensation for a visual prosthesis|
|US7981062||9 Oct 2009||19 Jul 2011||Imi Intelligent Medical Implants Ag||Mechanically activated objects for treatment of degenerative retinal disease|
|US8036751||2 Aug 2006||11 Oct 2011||Second Sight Medical Producers, Inc.||Retinal prosthesis with side mounted inductive coil|
|US8068913||1 Dec 2005||29 Nov 2011||Second Sight Medical Products, Inc.||Visual prosthesis for improved circadian rhythms and method of improving the circadian rhythms|
|US8090448||5 Sep 2008||3 Jan 2012||Second Sight Medical Products, Inc.||Low profile package for an implantable device|
|US8121697||23 Aug 2010||21 Feb 2012||Second Sight Medical Products, Inc.||Biocompatible bonding method and electronics package suitable for implantation|
|US8131378||28 Oct 2007||6 Mar 2012||Second Sight Medical Products, Inc.||Inductive repeater coil for an implantable device|
|US8165680||6 Oct 2010||24 Apr 2012||Second Sight Medical Products, Inc.||Electronics package suitable form implantation|
|US8170676||28 Oct 2007||1 May 2012||Second Sight Medical Products, Inc.||Electrode array|
|US8180453||9 Nov 2001||15 May 2012||Second Sight Medical Products, Inc.||Electrode array for neural stimulation|
|US8200338||13 Jan 2006||12 Jun 2012||Second Sight Medical Products, Inc.||Flexible circuit electrode array for improved layer adhesion|
|US8285380||23 Mar 2012||9 Oct 2012||Second Sight Medical Products, Inc.||Electronics package suitable for implantation|
|US8355800||28 Oct 2007||15 Jan 2013||Second Sight Medical Products, Inc.||Coating package for an implantable device|
|US8374698||18 Aug 2007||12 Feb 2013||Second Sight Medical Products, Inc.||Package for an implantable neural stimulation device|
|US8380326||11 Aug 2003||19 Feb 2013||Second Sight Medical Products, Inc.||Insulated implantable electrical circuit|
|US8406887||1 Sep 2011||26 Mar 2013||Second Sight Medical Products, Inc.||Package for an implantable neural stimulation device|
|US8412339||26 Oct 2007||2 Apr 2013||Second Sight Medical Products, Inc.||Package for an implantable neural stimulation device|
|US8538540||7 Sep 2011||17 Sep 2013||Second Sight Medical Products, Inc.||Retinal prosthesis with side mounted inductive coil|
|US8551271||25 Oct 2007||8 Oct 2013||Second Sight Medical Products, Inc.||Method for providing hermetic electrical feedthrough|
|US8571672||1 Mar 2013||29 Oct 2013||Second Sight Medical Products, Inc.||Package for a neural stimulation device|
|US8588917||11 Jun 2012||19 Nov 2013||Boston Scientific Neuromodulation Corporation||Fully implantable neurostimulator for autonomic nerve fiber stimulation as a therapy for urinary and bowel dysfunction|
|US8644937||11 Sep 2012||4 Feb 2014||Second Sight Medical Products, Inc.||Electronics package suitable for implantation|
|US8874224||8 May 2012||28 Oct 2014||Second Sight Medical Products, Inc.||Flexible circuit electrode array for improved layer adhesion|
|US8880165||19 Jan 2011||4 Nov 2014||Robert J. Greenberg||Biocompatible bonding method and electronics package suitable for implantation|
|US8996118||8 Oct 2013||31 Mar 2015||Second Sight Products, Inc.||Package for an implantable neural stimulation device|
|US9089690||11 Jul 2006||28 Jul 2015||Second Sight Medical Products, Inc.||Variable pitch electrode array|
|US9131863||26 May 2006||15 Sep 2015||Second Sight Medical Products, Inc.||Insulated implantable electrical circuit|
|US9161704||18 Feb 2015||20 Oct 2015||Second Sight Medical Products, Inc.||Insulated implantable electrical curcuit|
|US9220169||21 Jun 2007||22 Dec 2015||Second Sight Medical Products, Inc.||Biocompatible electroplated interconnection electronics package suitable for implantation|
|US9258902||16 Oct 2014||9 Feb 2016||Second Sight Medical Products, Inc.||Biocompatible bonding method suitable for implantation|
|US9387321||2 Jun 2015||12 Jul 2016||Second Sight Medical Products, Inc.||Stimulation patterns for a visual prosthesis|
|US9532451||4 Jan 2016||27 Dec 2016||Second Sight Medical Products, Inc.||Biocompatible bonding method and electronics package suitable for implantation|
|US9545517||8 Aug 2013||17 Jan 2017||Second Sight Medical Products, Inc.||Video device to be worn on the head|
|US9592396||17 Jan 2012||14 Mar 2017||Second Sight Medical Products, Inc.||Biocompatible bonding method and electronics package suitable for implantation|
|US9713716||30 Mar 2015||25 Jul 2017||Second Sight Medical Products, Inc.||Package for an implantable neural stimulation device|
|US9717150||14 Nov 2013||25 Jul 2017||Second Sight Medical Products, Inc.||Method for making a biocompatible hermetic housing including hermetic electrical feedthroughs|
|US20030187491 *||28 Mar 2002||2 Oct 2003||Robert Greenberg||Variable pitch electrode array|
|US20030233133 *||17 Jun 2002||18 Dec 2003||Greenberg Robert J.||Biocompatible bonding method and electronics package suitable for implantation|
|US20030233134 *||6 Sep 2002||18 Dec 2003||Greenberg Robert J.||Biocompatible bonding method and electronics package suitable for implantation|
|US20050004625 *||9 Jun 2004||6 Jan 2005||Chow Alan Y.||Treatment of degenerative retinal disease via electrical stimulation of surface structures|
|US20050033202 *||12 Apr 2004||10 Feb 2005||Chow Alan Y.||Mechanically activated objects for treatment of degenerative retinal disease|
|US20050222624 *||6 Apr 2004||6 Oct 2005||Robert Greenberg||Retinal prosthesis with side mounted inductive coil|
|US20060036296 *||17 Aug 2005||16 Feb 2006||Greenberg Robert J||Electrode array for neural stimulation|
|US20060142818 *||12 Dec 2005||29 Jun 2006||Optobionics||Methods for improving damaged retinal cell function|
|US20060173511 *||1 Dec 2005||3 Aug 2006||Greenberg Robert J||Visual prosthesis for improved circadian rhythms and method of improving the circadian rhythms|
|US20060190058 *||13 Jan 2006||24 Aug 2006||Greenberg Robert J||Visual prosthesis for improved circadian rhythms and method of improving the circadian rhythms|
|US20060225274 *||26 May 2006||12 Oct 2006||Robert Greenberg||Insulated implantable electrical circuit|
|US20060239482 *||13 Apr 2006||26 Oct 2006||Nagi Hatoum||System and method for providing a waveform for stimulating biological tissue|
|US20060271189 *||2 Aug 2006||30 Nov 2006||Robert Greenberg||Retinal prosthesis with side mounted inductive coil|
|US20070005112 *||7 Sep 2006||4 Jan 2007||Greenberg Robert J||Biocompatible bonding method and electronics package suitable for implantation|
|US20070158100 *||11 Aug 2003||12 Jul 2007||Robert Greenberg||Insulated implantable electrical circuit|
|US20080039936 *||16 Oct 2007||14 Feb 2008||Robert Greenberg||Retinal prosthesis with side mounted inductive coil|
|US20080039938 *||23 Oct 2007||14 Feb 2008||Robert Greenberg||Retinal Prosthesis with Side Mounted Inductive Coil|
|US20080051848 *||30 Oct 2007||28 Feb 2008||Greenberg Robert J||Electronics Package Suitable for Implantation|
|US20080058895 *||18 Aug 2007||6 Mar 2008||Jerry Ok||Package for an implantable neural stimulation device|
|US20080077195 *||28 Oct 2007||27 Mar 2008||Greenberg Robert J||Package for an Implantable Device|
|US20080077196 *||28 Oct 2007||27 Mar 2008||Greenberg Robert J||Motion Compensation for a Visual Prosthesis|
|US20080086173 *||26 Oct 2007||10 Apr 2008||Jerry Ok||Package for an Implantable Neural Stimulation Device|
|US20080097555 *||28 Oct 2007||24 Apr 2008||Greenberg Robert J||Inductive Repeater Coil for an Implantable Device|
|US20080249588 *||28 Oct 2007||9 Oct 2008||Greenberg Robert J||Electrode Array|
|US20080275528 *||28 Oct 2007||6 Nov 2008||Greenberg Robert J||Electrode Array for Visual Stimulation|
|US20080314502 *||19 Oct 2007||25 Dec 2008||Jerry Ok||Method for providing hermetic electrical feedthrough|
|US20080314506 *||26 Oct 2007||25 Dec 2008||Dao Min Zhou||Biocompatible Electroplated Interconnection Bonding Method and Electronics Package Suitable for Implantation|
|US20080314865 *||25 Oct 2007||25 Dec 2008||Jerry Ok||Method for Providing Hermetic Electrical Feedthrough|
|US20080319493 *||21 Jun 2007||25 Dec 2008||Dao Min Zhou||Biocompatible electroplated interconnection bonding method and electronics package suitable for implantation|
|US20090005835 *||5 Sep 2008||1 Jan 2009||Greenberg Robert J||Low Profile Package for an Implantable Device|
|US20090326623 *||11 Jul 2006||31 Dec 2009||Robert Greenberg||Variable pitch electrode array|
|US20100121231 *||9 Oct 2009||13 May 2010||Chow Alan Y||Mechanically activated objects for treatment of degenerative retinal disease|
|US20100228319 *||8 Mar 2010||9 Sep 2010||National Chiao Tung University||Electrical stimulation system and method using multi-group electrode array|
|US20110213443 *||23 Aug 2010||1 Sep 2011||Greenberg Robert J||Biocompatible Bonding Method and Electronics Package Suitable for Implantation|
|EP2477467A1||14 Jan 2011||18 Jul 2012||Second Sight Medical Products||Flexible Circuit Electrode Array and Method of Manufacturing the Same|
|EP2839858A1||28 Jul 2003||25 Feb 2015||Second Sight Medical Products, Inc.||Field focusing and mapping in an electrode array|
|WO1985001214A1 *||14 Sep 1984||28 Mar 1985||Webster Wilton W Jr||Electrophysiological switching unit|
|WO2004011080A1||28 Jul 2003||5 Feb 2004||Second Sight, Llc||Field focusing and mapping in an electrode array|
|U.S. Classification||607/54, 607/60, 324/692, 607/66, 607/61, 324/636, 324/652|