Circuit architecture and system for implantable multi-function and multi-analyte biosensing device
First Claim
1. An implantable bio-sensing platform that enables the wireless selection, calibration and reading of multiple sensors, wherein the bio-sensing platform receives optical power and coded optical instructions from an external control unit located in proximity of the implanted sensor platform chip, the bio-sensing platform comprising:
- sensors,sensor interface circuits,signal processors,electronic multiplexers,solar cells, andoptoelectronic transmitters and receivers that wirelessly communicates with the external control unit, wherein the platform receives from the optical transmitter located in the external control unit coded pulses using at least one photodetector operating at the dedicated wavelength and converting them to electrical pulses, wherein the solar cells are interfaced with at least one voltage regulator circuit whose output provides stable power to the entire platform electronic circuits and optoelectronic transmitters and receivers,wherein the coded electrical pulses are decoded using finite state machine architecture by the mode select unit interfacing with the photodetector receiving the coded pulses,wherein the mode select unit includes logic circuits configurable to perform various functions depending on the coded pulses,wherein the coded pulse sequence in one code enables operation of checking solar power output providing information regarding the level of electrical power generated by the solar cells by sending a dedicated frequency voltage pulse train which drives the optical transmitter with a specific optical wavelength and located on the implanted platform,wherein the coded pulse sequence in one embodiment enables checking of operation of a potentiostat interfacing with a bio-sensing element before bio-sensing element code is sent for taking readings, wherein the output of the optical transmitter is received by a dedicated second photodetector in the external control unit, and wherein the second photodetector located in the external control unit output is processed and displayed,wherein the coded pulse sequence in another coded sequence enables calibration and reading of a designated biosensor, wherein the bio-sensing platform includes analyte sensors, protein sensors, and physiological sensors, the analyte sensors being connected to interface electronics, signal processing unit, and multiplexer, the multiplexer output feeds a driver that in turn feeds the said optical transmitter which converts electrical pulses into optical pulses.
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Accused Products
Abstract
An implantable bio-sensing platform architecture that enables the wireless selection, calibration and reading of multiple sensors, as well as checking the power levels of the solar powering source energizing various electronic and optoelectronic devices and circuits embedded in the platform. It also permits checking the operation of the potentiostats interfacing with each amperometric analyte sensor. The platform is flexible to include FET based sensors for protein sensing as well as other applications including pH sensing. In addition, other physiological sensors can be integrated in the platform.
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Citations
7 Claims
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1. An implantable bio-sensing platform that enables the wireless selection, calibration and reading of multiple sensors, wherein the bio-sensing platform receives optical power and coded optical instructions from an external control unit located in proximity of the implanted sensor platform chip, the bio-sensing platform comprising:
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sensors, sensor interface circuits, signal processors, electronic multiplexers, solar cells, and optoelectronic transmitters and receivers that wirelessly communicates with the external control unit, wherein the platform receives from the optical transmitter located in the external control unit coded pulses using at least one photodetector operating at the dedicated wavelength and converting them to electrical pulses, wherein the solar cells are interfaced with at least one voltage regulator circuit whose output provides stable power to the entire platform electronic circuits and optoelectronic transmitters and receivers, wherein the coded electrical pulses are decoded using finite state machine architecture by the mode select unit interfacing with the photodetector receiving the coded pulses, wherein the mode select unit includes logic circuits configurable to perform various functions depending on the coded pulses, wherein the coded pulse sequence in one code enables operation of checking solar power output providing information regarding the level of electrical power generated by the solar cells by sending a dedicated frequency voltage pulse train which drives the optical transmitter with a specific optical wavelength and located on the implanted platform, wherein the coded pulse sequence in one embodiment enables checking of operation of a potentiostat interfacing with a bio-sensing element before bio-sensing element code is sent for taking readings, wherein the output of the optical transmitter is received by a dedicated second photodetector in the external control unit, and wherein the second photodetector located in the external control unit output is processed and displayed, wherein the coded pulse sequence in another coded sequence enables calibration and reading of a designated biosensor, wherein the bio-sensing platform includes analyte sensors, protein sensors, and physiological sensors, the analyte sensors being connected to interface electronics, signal processing unit, and multiplexer, the multiplexer output feeds a driver that in turn feeds the said optical transmitter which converts electrical pulses into optical pulses. - View Dependent Claims (2, 3, 4, 5, 6)
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7. An implantable bio-sensing platform which is configured to allow the wireless selection, calibration and reading of multiple sensors, wherein the bio-sensing platform receives optical power and coded optical instructions from an external control unit having an ECU optical transmitter, the bio-sensing platform comprising:
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at least one sensor, at least one sensor interface circuit, at least one signal processor, at least one electronic multiplexer, at least one solar cell, and at least one optoelectronic transmitter/receiver configured to wirelessly communicate with the external control unit, wherein the bio-sensing platform is configured to receive coded optical pulses of a first wavelength and convert the coded optical pulses to electrical pulses, wherein the at least one solar cell is associated with a voltage regulator circuit configured to provide stable power to the bio-sensing platform, and wherein the bio-sensor platform includes a mode select unit configured to decode the received coded electrical pulses and operate responsive to the decoded electrical pulses, wherein the received coded electrical pulses include a first coded pulse sequence and a second coded pulse sequence, wherein the first coded pulse sequence includes instructions configured to cause the bio-sensor platform to check the level of electrical power generated by the solar cells, and wherein the second coded pulse sequence includes instructions to cause the bio-sensor platform to perform a calibration operation and a reading of a designated bio-sensor.
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Specification