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Probe-antenna and multifunctional switch for biomedical neural implants.

Chi-Sing Yuen1, Hsiao-Chin Chen2

  • 1National Taiwan University of Science and Technology, Taipei, Taiwan.

Biomedical Microdevices
|October 9, 2020
PubMed
Summary
This summary is machine-generated.

This study introduces a novel probe-antenna and a single-pole-four-throw switch for neural implants. These components demonstrate high performance at 60 GHz, enabling advanced wireless communication for biomedical applications.

Keywords:
AntennaBiomedical implantsElectrochemical impedance spectroscopyImpedance measurementNeural recordingProbeSwitch

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Area of Science:

  • Biomedical Engineering
  • Electrical Engineering
  • Microwave Engineering

Background:

  • Biomedical neural implants require efficient wireless communication systems.
  • Existing technologies face challenges in miniaturization and performance at high frequencies.

Purpose of the Study:

  • To propose and characterize a probe-antenna and a multifunctional switch for biomedical neural implants.
  • To evaluate the performance of these components at 60 GHz for potential implantable applications.

Main Methods:

  • Fabrication of a multifunctional single-pole-four-throw switch using TSMC 90-nm CMOS process.
  • Design and fabrication of a probe-antenna on a Roger 4003C printed circuit board.
  • Performance evaluation including insertion loss, return loss, isolation, P1dB, input matching, radiation efficiency, and gain.
  • Impedance measurements for probe/electrode function verification in various solutions.

Main Results:

  • The switch achieved insertion loss of 4.5/4.8 dB, return loss of 16.7/15.4 dB, isolation of 19.2/20.3 dB, and P1dB of 4/5 dBm at 60 GHz.
  • The probe-antenna achieved input matching over 59.35-65 GHz, with simulated radiation efficiency of 69.8/34.4% and gain of 3.88/5.47 dBi.
  • Probe/electrode function was verified through impedance measurements in deionized water, PBS, and a conductive solution.

Conclusions:

  • The developed probe-antenna and switch are suitable for high-frequency operation in biomedical neural implants.
  • The components demonstrate promising performance metrics for wireless data transmission and sensing in implantable devices.
  • The successful verification of probe/electrode function highlights the potential for integrated sensing capabilities.