Improved Charge Pump Design and Ex Vivo Experimental Validation of CMOS 256-Pixel Photovoltaic-Powered Subretinal Prosthetic Chip

An improved design of CMOS 256-pixel photovoltaic-powered implantable chip for subretinal prostheses is presented. In the proposed subretinal chip, a high-efficiency fully-integrated 4× charge pump is designed and integrated with on-chip photovoltaic (PV) cells and a 256-pixel array with active pixel sensors (APS) for image light sensing, biphasic constant current stimulators, and electrodes. Thus the PV voltage generated by infrared (IR) light can be boosted to above 1V so that the charge injection is increased. The proposed chip adopts the 32-phase divisional power supply scheme (DPSS) to reduce the required supply current and thus the required area of the PV cells. The proposed chip is designed and fabricated in 180-nm CMOS image sensor (CIS) technology and post-processed with biocompatible IrOx electrodes and silicone packaging. From the electrical measurement results, the measured stimulation frequency is 28.3 Hz under the equivalent electrode impedance load. The measured maximum output stimulation current is 7.1 μA and the amount of injected charges per pixel is 7.36 nC under image light intensity of 3200 lux and IR light intensity of 100 mW/cm2. The function of the proposed chip has been further validated successfully with the ex vivo experimental results by recording the electrophysiological responses of retinal ganglion cells (RGCs) of retinas from retinal degeneration (rd1) mice with a multi-electrode array (MEA). The measured average threshold injected charge is about 3.97 nC which is consistent with that obtained from the patch clamp recording on retinas from wild type (C57BL/6) mice with a single electrode pair.

[1]  G. Zeck,et al.  Electrode-size dependent thresholds in subretinal neuroprosthetic stimulation , 2018, Journal of neural engineering.

[2]  J. Ohta,et al.  A CMOS 256-pixel photovoltaics-powered implantable chip with active pixel sensors and iridium-oxide electrodes for subretinal prostheses , 2018 .

[3]  S.R. Sanders,et al.  Analysis and Optimization of Switched-Capacitor DC–DC Converters , 2008, IEEE Transactions on Power Electronics.

[4]  Angelika Braun,et al.  Artificial vision with wirelessly powered subretinal electronic implant alpha-IMS , 2013, Proceedings of the Royal Society B: Biological Sciences.

[5]  Sylvie Renaud,et al.  An Embedded Deep Brain Stimulator for Biphasic Chronic Experiments in Freely Moving Rodents , 2016, IEEE Transactions on Biomedical Circuits and Systems.

[6]  Shmuel Ben-Yaakov On the Influence of Switch Resistances on Switched-Capacitor Converter Losses , 2012, IEEE Transactions on Industrial Electronics.

[7]  S. Gregori Voltage doubler with improved driving capability and no short-circuit losses , 2010 .

[8]  Xin Lei,et al.  Photovoltaic Pixels for Neural Stimulation: Circuit Models and Performance , 2016, IEEE Transactions on Biomedical Circuits and Systems.

[9]  Timothy G. Constandinou,et al.  A Partial-Current-Steering Biphasic Stimulation Driver for Vestibular Prostheses , 2008, IEEE Transactions on Biomedical Circuits and Systems.

[10]  Stuart F. Cogan,et al.  Photodiode Circuits for Retinal Prostheses , 2011, IEEE Transactions on Biomedical Circuits and Systems.

[11]  Linh Hoang,et al.  An Integrated 256-Channel Epiretinal Prosthesis , 2010, IEEE Journal of Solid-State Circuits.

[12]  Torsten Lehmann,et al.  Safety Ensuring Retinal Prosthesis With Precise Charge Balance and Low Power Consumption , 2014, IEEE Transactions on Biomedical Circuits and Systems.

[13]  Chung-Yu Wu,et al.  Responses of rabbit retinal ganglion cells to subretinal electrical stimulation using a silicon-based microphotodiode array. , 2011, Investigative ophthalmology & visual science.

[14]  Chris E. Williams,et al.  Visual cortex responses to suprachoroidal electrical stimulation of the retina: effects of electrode return configuration. , 2012, Journal of neural engineering.

[15]  Chris E. Williams,et al.  Evaluation of stimulus parameters and electrode geometry for an effective suprachoroidal retinal prosthesis , 2010, Journal of neural engineering.

[16]  Chung-Yu Wu,et al.  The design of CMOS self-powered 256-pixel implantable chip with on-chip photovoltaic cells and active pixel sensors for subretinal prostheses , 2015, 2015 IEEE Biomedical Circuits and Systems Conference (BioCAS).

[17]  Hei Wong,et al.  On the design of power- and area-efficient Dickson charge pump circuits , 2014 .

[18]  T Fujikado,et al.  Laboratory investigation of microelectronics-based stimulators for large-scale suprachoroidal transretinal stimulation (STS) , 2007, Journal of neural engineering.

[19]  Man-Kay Law,et al.  A Single-Chip Solar Energy Harvesting IC Using Integrated Photodiodes for Biomedical Implant Applications , 2017, IEEE Transactions on Biomedical Circuits and Systems.

[20]  A. Sher,et al.  Photovoltaic Retinal Prosthesis with High Pixel Density , 2012, Nature Photonics.

[21]  Maurits Ortmanns,et al.  A Neural Stimulator Frontend With High-Voltage Compliance and Programmable Pulse Shape for Epiretinal Implants , 2012, IEEE Journal of Solid-State Circuits.

[22]  G. Palumbo,et al.  Charge-pump circuits: power-consumption optimization , 2002 .

[23]  Wentai Liu,et al.  A Fully-Integrated High-Compliance Voltage SoC for Epi-Retinal and Neural Prostheses , 2013, IEEE Transactions on Biomedical Circuits and Systems.

[24]  Joseph F. Rizzo,et al.  Developments on the Boston 256-channel retinal implant , 2013, 2013 IEEE International Conference on Multimedia and Expo Workshops (ICMEW).

[25]  W. Liu,et al.  A neuro-stimulus chip with telemetry unit for retinal prosthetic device , 2000, IEEE Journal of Solid-State Circuits.

[26]  Azita Emami-Neyestanak,et al.  A Fully Intraocular High-Density Self-Calibrating Epiretinal Prosthesis , 2013, IEEE Transactions on Biomedical Circuits and Systems.

[27]  Robert K. Shepherd,et al.  Stimulus Induced pH Changes in Cochlear Implants: An In Vitro and In Vivo Study , 2001, Annals of Biomedical Engineering.

[28]  L.S. Theogarajan A Low-Power Fully Implantable 15-Channel Retinal Stimulator Chip , 2008, IEEE Journal of Solid-State Circuits.

[29]  Chih-Cheng Hsieh,et al.  A 0.8-V 4096-Pixel CMOS Sense-and-Stimulus Imager for Retinal Prosthesis , 2013, IEEE Transactions on Electron Devices.

[30]  Daniel Palanker,et al.  Optimization of return electrodes in neurostimulating arrays , 2016, Journal of neural engineering.

[31]  R. Shepherd,et al.  Electrical stimulation of the auditory nerve: direct current measurement in vivo , 1999, IEEE Transactions on Biomedical Engineering.

[32]  Alfred Stett,et al.  Subretinal electronic chips allow blind patients to read letters and combine them to words , 2010, Proceedings of the Royal Society B: Biological Sciences.

[33]  Hei Wong,et al.  A comparative study of charge pumping circuits for flash memory applications , 2012, Microelectron. Reliab..

[34]  Michael P. Andrews,et al.  Developmental time course distinguishes changes in spontaneous and light-evoked retinal ganglion cell activity in rd1 and rd10 mice. , 2011, Journal of neurophysiology.

[35]  Jong-Mo Seo,et al.  Light-Controlled Biphasic Current Stimulator IC Using CMOS Image Sensors for High-Resolution Retinal Prosthesis and In Vitro Experimental Results With rd1 Mouse , 2015, IEEE Transactions on Biomedical Engineering.

[36]  G. Suaning,et al.  Multipolar Field Shaping in a Suprachoroidal Visual Prosthesis , 2017, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[37]  M. Ortmanns,et al.  A 232-Channel Epiretinal Stimulator ASIC , 2007, IEEE Journal of Solid-State Circuits.

[38]  Chung-Yu Wu,et al.  A fully-integrated charge pump for self-powered implantable retinal prostheses , 2016, 2016 IEEE International Symposium on Radio-Frequency Integration Technology (RFIT).