Frontiers in Neuroscience (Nov 2017)

A Sub-millimeter, Inductively Powered Neural Stimulator

  • Daniel K. Freeman,
  • Jonathan M. O'Brien,
  • Parshant Kumar,
  • Brian Daniels,
  • Reed A. Irion,
  • Louis Shraytah,
  • Brett K. Ingersoll,
  • Andrew P. Magyar,
  • Andrew Czarnecki,
  • Jesse Wheeler,
  • Jonathan R. Coppeta,
  • Michael P. Abban,
  • Ronald Gatzke,
  • Shelley I. Fried,
  • Seung Woo Lee,
  • Amy E. Duwel,
  • Jonathan J. Bernstein,
  • Alik S. Widge,
  • Alik S. Widge,
  • Ana Hernandez-Reynoso,
  • Aswini Kanneganti,
  • Mario I. Romero-Ortega,
  • Stuart F. Cogan

DOI
https://doi.org/10.3389/fnins.2017.00659
Journal volume & issue
Vol. 11

Abstract

Read online

Wireless neural stimulators are being developed to address problems associated with traditional lead-based implants. However, designing wireless stimulators on the sub-millimeter scale (<1 mm3) is challenging. As device size shrinks, it becomes difficult to deliver sufficient wireless power to operate the device. Here, we present a sub-millimeter, inductively powered neural stimulator consisting only of a coil to receive power, a capacitor to tune the resonant frequency of the receiver, and a diode to rectify the radio-frequency signal to produce neural excitation. By replacing any complex receiver circuitry with a simple rectifier, we have reduced the required voltage levels that are needed to operate the device from 0.5 to 1 V (e.g., for CMOS) to ~0.25–0.5 V. This reduced voltage allows the use of smaller receive antennas for power, resulting in a device volume of 0.3–0.5 mm3. The device was encapsulated in epoxy, and successfully passed accelerated lifetime tests in 80°C saline for 2 weeks. We demonstrate a basic proof-of-concept using stimulation with tens of microamps of current delivered to the sciatic nerve in rat to produce a motor response.

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