Journal
ACS NANO
Volume 16, Issue 7, Pages 10692-10700Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acsnano.2c02399
Keywords
nanoelectrode; MOSFETs; extracellular recording; neuron; electrophysiology
Categories
Funding
- Japan Society for the Promotion of Science (JSPS) [17H03250, 26709024, 20H00244]
- Strategic Advancement of Multi-Purpose Ultra-Human Robot and Artificial Intelligence Technologies program from the New Energy and Industrial Technology Development Organization (NEDO)
- Adaptable and Seamless Technology transfer Program through Target-driven R&D (A-STEP) from Japan Science and Technology Agency (JST)
- Nagai Foundation for Science Technology
- Takeda Science Foundation
- JSPS KAKENHI [15H05917, 20H00614]
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Microscale needle-like electrodes offer high spatiotemporal resolution for in vivo extracellular recording. However, reducing the size to the nanoscale increases electrical impedance. By stacking a nanoelectrode on an amplifier module, the quality of neuronal signal recording can be improved. In experiments conducted on the mouse cortex, the nanoelectrode with amplifier could record a wider range of neural signals compared to the electrode without the amplifier.
ABSTRACT: Microscale needle-like electrode technologies offer in vivo extracellular recording with a high spatiotemporal resolution. Further miniaturization of needles to nanoscale minimizes tissue injuries; however, a reduced electrode area increases electrical impedance that degrades the quality of neuronal signal recording. We overcome this limitation by fabricating a 300 nm tip diameter and 200 mu m long needle electrode where the amplitude gain with a high-impedance electrode (>15 M omega, 1 kHz) was improved from 0.54 (-5.4 dB) to 0.89 (-1.0 dB) by stacking it on an amplifier module of source follower. The nanoelectrode provided the recording of both local field potential (<300 Hz) and action potential (>500 Hz) in the mouse cortex, in contrast to the electrode without the amplifier. These results suggest that microelectrodes can be further minimized by the proposed amplifier configuration for low-invasive recording and electrophysiological studies in submicron areas in tissues, such as dendrites and axons.
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