A Bio-friendly and Economical Technique for Chronic Implantation of Multiple Microelectrode Arrays

Overview

Journal J Neurosci Methods

Specialty Neurology

Date 2010 Feb 16

PMID 20153370

Citations 14

Authors

Pratik Y Chhatbar

Lee M von Kraus

Mulugeta Semework

Joseph T Francis

Affiliations

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Abstract

Many neurophysiological experiments on rodents and non-human primates involve the implantation of more than one multi-electrode array to record from many regions of the brain. So called 'floating' microelectrode arrays are implanted in cortical regions of interest and are coupled via a flexible cable to their connectors which are fixed to the skull by a cement cap or a titanium pedestal, such as the Cereport system, which has been approved for human use. The use of bone cement has several disadvantages including the creation of infection prone areas at the interface with the skull and surrounding skin. Alternatively, the more biocompatible Cereport has a limited carrying capacity and is far more expensive. In this paper, we describe a new implantation technique, which combines the biocompatibility of titanium, a high carrying capacity with a minimal skull footprint, and a decreased chance of infection, all in a relatively inexpensive package. This technique utilizes an in-house fabricated 'Nesting Platform' (NP), mounted on a titanium headpost to hold multiple connectors above the skin, making the headpost the only transcutaneous object. The use of delrin, a durable, lightweight and easily machinable material, allows easy customization of the NP for a wide variety of floating electrodes and their connectors. The ultimate result is a longer survival time with superior neural recordings that can potentially last longer than with traditional implantation techniques.

Citing Articles

Normalization by valence and motivational intensity in the sensorimotor cortices (PMd, M1, and S1).

Yao Z, Hessburg J, Francis J Sci Rep. 2021; 11(1):24221.

PMID: 34930930 PMC: 8688489. DOI: 10.1038/s41598-021-03200-3.

Mirror neurons are modulated by grip force and reward expectation in the sensorimotor cortices (S1, M1, PMd, PMv).

Atique M, Francis J Sci Rep. 2021; 11(1):15959.

PMID: 34354213 PMC: 8342437. DOI: 10.1038/s41598-021-95536-z.

Noise-Correlation Is Modulated by Reward Expectation in the Primary Motor Cortex Bilaterally During Manual and Observational Tasks in Primates.

Moore B, Khang S, Francis J Front Behav Neurosci. 2020; 14:541920.

PMID: 33343308 PMC: 7739882. DOI: 10.3389/fnbeh.2020.541920.

Reward Expectation Modulates Local Field Potentials, Spiking Activity and Spike-Field Coherence in the Primary Motor Cortex.

An J, Yadav T, Hessburg J, Francis J eNeuro. 2019; 6(3).

PMID: 31171607 PMC: 6595440. DOI: 10.1523/ENEURO.0178-19.2019.

Paradigm Shift in Sensorimotor Control Research and Brain Machine Interface Control: The Influence of Context on Sensorimotor Representations.

Zhao Y, Hessburg J, Kumar J, Francis J Front Neurosci. 2018; 12:579.

PMID: 30250422 PMC: 6139327. DOI: 10.3389/fnins.2018.00579.