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The emerging field of bioelectronic medicine seeks methods for deciphering and modulating electrophysiological activity in the body to attain therapeutic effects at target organs. Current approaches to interfacing with peripheral nerves and muscles rely heavily on wires, creating problems for chronic use, while emerging wireless approaches lack the size scalability necessary to interrogate small-diameter nerves. Furthermore, conventional electrode-based technologies lack the capability to record from nerves with high spatial resolution or to record independently from many discrete sites within a nerve bundle. Here, we demonstrate neural dust, a wireless and scalable ultrasonic backscatter system for powering and communicating with implanted bioelectronics. We show that ultrasound is effective at delivering power to mm-scale devices in tissue; likewise, passive, battery-less communication using backscatter enables high-fidelity transmission of electromyogram (EMG) and electroneurogram (ENG) signals from anesthetized rats. These results highlight the potential for an ultrasound-based neural interface system for advancing future bioelectronics-based therapies.

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Physical principles for scalable neural recording

Marblestone

Zamft

Maguire

et al. 2013

Front. Comput. Neurosci.

221

223

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Simultaneously measuring the activities of all neurons in a mammalian brain at millisecond resolution is a challenge beyond the limits of existing techniques in neuroscience. Entirely new approaches may be required, motivating an analysis of the fundamental physical constraints on the problem. We outline the physical principles governing brain activity mapping using optical, electrical, magnetic resonance, and molecular modalities of neural recording. Focusing on the mouse brain, we analyze the scalability of each method, concentrating on the limitations imposed by spatiotemporal resolution, energy dissipation, and volume displacement. Based on this analysis, all existing approaches require orders of magnitude improvement in key parameters. Electrical recording is limited by the low multiplexing capacity of electrodes and their lack of intrinsic spatial resolution, optical methods are constrained by the scattering of visible light in brain tissue, magnetic resonance is hindered by the diffusion and relaxation timescales of water protons, and the implementation of molecular recording is complicated by the stochastic kinetics of enzymes. Understanding the physical limits of brain activity mapping may provide insight into opportunities for novel solutions. For example, unconventional methods for delivering electrodes may enable unprecedented numbers of recording sites, embedded optical devices could allow optical detectors to be placed within a few scattering lengths of the measured neurons, and new classes of molecularly engineered sensors might obviate cumbersome hardware architectures. We also study the physics of powering and communicating with microscale devices embedded in brain tissue and find that, while radio-frequency electromagnetic data transmission suffers from a severe power–bandwidth tradeoff, communication via infrared light or ultrasound may allow high data rates due to the possibility of spatial multiplexing. The use of embedded local recording and wireless data transmission would only be viable, however, given major improvements to the power efficiency of microelectronic devices.

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Design Techniques for Fully Integrated Switched-Capacitor DC-DC Converters

Sanders

Alon

2011

IEEE J. Solid-State Circuits

373

221

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A Minimally Invasive 64-Channel Wireless μECoG Implant

Muller

et al. 2015

IEEE J. Solid-State Circuits

314

154

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Emerging applications in brain-machine interface systems require high-resolution, chronic multisite cortical recordings, which cannot be obtained with existing technologies due to high power consumption, high invasiveness, or inability to transmit data wirelessly. In this paper, we describe a microsystem based on electrocorticography (ECoG) that overcomes these difficulties, enabling chronic recording and wireless transmission of neural signals from the surface of the cerebral cortex. The device is comprised of a highly flexible, high-density, polymer-based 64-channel electrode array and a flexible antenna, bonded to 2.4 mm × 2.4 mm CMOS integrated circuit (IC) that performs 64-channel acquisition, wireless power and data transmission. The IC digitizes the signal from each electrode at 1 kS/s with 1.2 μV input referred noise, and transmits the serialized data using a 1 Mb/s backscattering modulator. A dual-mode power-receiving rectifier reduces data-dependent supply ripple, enabling the integration of small decoupling capacitors on chip and eliminating the need for external components. Design techniques in the wireless and baseband circuits result in over 16× reduction in die area with a simultaneous 3× improvement in power efficiency over the state of the art. The IC consumes 225 μW and can be powered by an external reader transmitting 12 mW at 300 MHz, which is over 3× lower than IEEE and FCC regulations.

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Demonstration of Integrated Micro-Electro-Mechanical Relay Circuits for VLSI Applications

Spencer

Chen

Wang

et al. 2011

IEEE J. Solid-State Circuits

162

115

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A 90 nm CMOS Low-Power 60 GHz Transceiver With Integrated Baseband Circuitry

Marcu

Chowdhury

Thakkar

et al. 2009

IEEE J. Solid-State Circuits

291

112

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Integrated circuit design with NEM relays

et al. 2008

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Model validation of untethered, ultrasonic neural dust motes for cortical recording

Seo

Carmena

Rabaey

et al. 2015

Journal of Neuroscience Methods

146

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Elad Alon

Wireless Recording in the Peripheral Nervous System with Ultrasonic Neural Dust

Physical principles for scalable neural recording

Design Techniques for Fully Integrated Switched-Capacitor DC-DC Converters

A Minimally Invasive 64-Channel Wireless μECoG Implant

Demonstration of Integrated Micro-Electro-Mechanical Relay Circuits for VLSI Applications

A 90 nm CMOS Low-Power 60 GHz Transceiver With Integrated Baseband Circuitry

Integrated circuit design with NEM relays

Model validation of untethered, ultrasonic neural dust motes for cortical recording

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