Journal Article10.1038/S41551-020-0518-9
A wireless millimetre-scale implantable neural stimulator with ultrasonically powered bidirectional communication.
David K. Piech,David K. Piech,Benjamin C. Johnson,Benjamin C. Johnson,Konlin Shen,Konlin Shen,Mohammad Meraj Ghanbari,Ka Yiu Li,Ryan Neely,Kay Joshua,Jose M. Carmena,Michel M. Maharbiz,Rikky Muller +12 more
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TL;DR: A wireless, leadless and battery-free implantable neural stimulator that is 1.7-mm 3 and that incorporates a piezoceramic transducer, an energy-storage capacitor and an integrated circuit that allows for repeatable stimulation across a range of physiological responses is described.
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Abstract: Clinically approved neural stimulators are limited by battery requirements, as well as by their large size compared with the stimulation targets. Here, we describe a wireless, leadless and battery-free implantable neural stimulator that is 1.7 mm3 and that incorporates a piezoceramic transducer, an energy-storage capacitor and an integrated circuit. An ultrasonic link and a hand-held external transceiver provide the stimulator with power and bidirectional communication. The stimulation protocols were wirelessly encoded on the fly, reducing power consumption and on-chip memory, and enabling protocol complexity with a high temporal resolution and low-latency feedback. Uplink data indicating whether stimulation occurs are encoded by the stimulator through backscatter modulation and are demodulated at the external transceiver. When embedded in ex vivo porcine tissue, the integrated circuit efficiently harvested ultrasonic power, decoded downlink data for the stimulation parameters and generated current-controlled stimulation pulses. When cuff-mounted and acutely implanted onto the sciatic nerve of anaesthetized rats, the device conferred repeatable stimulation across a range of physiological responses. The miniaturized neural stimulator may facilitate closed-loop neurostimulation for therapeutic interventions. A wireless and battery-free 1.7-mm3 neural stimulator implanted onto the sciatic nerve of rats allows for repeatable stimulation across a range of physiological responses.
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A Biomimetic, SoC-Based Neural Stimulator for Novel Arbitrary-Waveform Stimulation Protocols.
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A Wireless Network of 8.8-mm3 Bio-Implants Featuring Adaptive Magnetoelectric Power and Multi-Access Bidirectional Telemetry
Zhanghao Yu,Wei Wang,Joshua C. Chen,Zhiyu Chen,Yan He,Amanda Singer,Jacob T. Robinson,Kaiyuan Yang +7 more
- 19 Jun 2022
TL;DR: This paper presents a hardware platform for wireless mm-sized bio-implant networks, exploiting adaptive magnetoelectric power transfer and novel schemes for efficient bidirectional multi-access communication.
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TL;DR: Reversibility and adaptability, allowing control of side-effects, make thalamic stimulation preferable to thalamotomy, especially when treatment of both sides of the brain is needed.
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脳卒中の回復期から慢性期治療 2. 危険因子の管理と再発予防
野村栄一
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Ultrasound-enhanced systemic thrombolysis for acute ischemic stroke.
Andrei V. Alexandrov,Andrei V. Alexandrov,Carlos A. Molina,James C. Grotta,Zsolt Garami,Shiela R. Ford,José Alvarez-Sabín,Joan Montaner,Maher Saqqur,Andrew M. Demchuk,Lemuel A. Moyé,Michael D. Hill,Anne W. Wojner +12 more
TL;DR: In patients with acute ischemic stroke, continuous transcranial Doppler augments t-PA-induced arterial recanalization, with a nonsignificant trend toward an increased rate of recovery from stroke, as compared with placebo.
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Vagus nerve stimulation inhibits cytokine production and attenuates disease severity in rheumatoid arthritis
F. A. Koopman,Sangeeta S. Chavan,Sanda Miljko,Simeon Grazio,Sekib Sokolovic,P. Richard Schuurman,Ashesh D. Mehta,Yaakov A. Levine,Michael A. Faltys,Ralph Zitnik,Kevin J. Tracey,Paul P. Tak +11 more
TL;DR: Vagus nerve stimulation targeting the inflammatory reflex modulates TNF production and reduces inflammation in humans is established, suggesting that it is possible to use mechanism-based neuromodulating devices in the experimental therapy of RA and possibly other autoimmune and autoinflammatory diseases.
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