Insertion Mechanics of Amorphous SiC Ultra-micro Scale Neural Probes

Overview

Journal J Neural Eng

Specialties Biomedical Engineering
Neurology

Date 2022 Mar 9

PMID 35263724

Authors

Negar Geramifard

Behnoush Dousti

Christopher Nguyen

Justin Abbott

Stuart F Cogan

Victor D Varner

Affiliations

Soon will be listed here.

Abstract

. Trauma induced by the insertion of microelectrodes into cortical neural tissue is a significant problem. Further, micromotion and mechanical mismatch between microelectrode probes and neural tissue is implicated in an adverse foreign body response (FBR). Hence, intracortical ultra-microelectrode probes have been proposed as alternatives that minimize this FBR. However, significant challenges in implanting these flexible probes remain. We investigated the insertion mechanics of amorphous silicon carbide (a-SiC) probes with a view to defining probe geometries that can be inserted into cortex without buckling.. We determined the critical buckling force of a-SiC probes as a function of probe geometry and then characterized the buckling behavior of these probes by measuring force-displacement responses during insertion into agarose gel and rat cortex.Insertion forces for a range of probe geometries were determined and compared with critical buckling forces to establish geometries that should avoid buckling during implantation into brain. The studies show that slower insertion speeds reduce the maximum insertion force for single-shank probes but increase cortical dimpling during insertion of multi-shank probes.Our results provide a guide for selecting probe geometries and insertion speeds that allow unaided implantation of probes into rat cortex. The design approach is applicable to other animal models where insertion of intracortical probes to a depth of 2 mm is required.

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References

Patel P, Zhang H, Robbins M, Nofar J, Marshall S, Kobylarek M . Chronic in vivo stability assessment of carbon fiber microelectrode arrays. J Neural Eng. 2016; 13(6):066002. PMC: 5118062. DOI: 10.1088/1741-2560/13/6/066002. View

Deku F, Cohen Y, Joshi-Imre A, Kanneganti A, Gardner T, Cogan S . Amorphous silicon carbide ultramicroelectrode arrays for neural stimulation and recording. J Neural Eng. 2017; 15(1):016007. PMC: 5786446. DOI: 10.1088/1741-2552/aa8f8b. View

Kozai T, Gugel Z, Li X, Gilgunn P, Khilwani R, Ozdoganlar O . Chronic tissue response to carboxymethyl cellulose based dissolvable insertion needle for ultra-small neural probes. Biomaterials. 2014; 35(34):9255-68. DOI: 10.1016/j.biomaterials.2014.07.039. View

Kozai T, Langhals N, Patel P, Deng X, Zhang H, Smith K . Ultrasmall implantable composite microelectrodes with bioactive surfaces for chronic neural interfaces. Nat Mater. 2012; 11(12):1065-73. PMC: 3524530. DOI: 10.1038/nmat3468. View

Casanova F, Carney P, Sarntinoranont M . In vivo evaluation of needle force and friction stress during insertion at varying insertion speed into the brain. J Neurosci Methods. 2014; 237:79-89. PMC: 8011429. DOI: 10.1016/j.jneumeth.2014.08.012. View

McConnell G, Rees H, Levey A, Gutekunst C, Gross R, Bellamkonda R . Implanted neural electrodes cause chronic, local inflammation that is correlated with local neurodegeneration. J Neural Eng. 2009; 6(5):056003. DOI: 10.1088/1741-2560/6/5/056003. View

Sridharan A, Rajan S, Muthuswamy J . Long-term changes in the material properties of brain tissue at the implant-tissue interface. J Neural Eng. 2013; 10(6):066001. PMC: 3888957. DOI: 10.1088/1741-2560/10/6/066001. View

Roberts J, Earnshaw A, Ferguson V, Bryant S . Comparative study of the viscoelastic mechanical behavior of agarose and poly(ethylene glycol) hydrogels. J Biomed Mater Res B Appl Biomater. 2011; 99(1):158-69. DOI: 10.1002/jbm.b.31883. View

Woolley A, Desai H, Otto K . Chronic intracortical microelectrode arrays induce non-uniform, depth-related tissue responses. J Neural Eng. 2013; 10(2):026007. PMC: 4096286. DOI: 10.1088/1741-2560/10/2/026007. View

10.

Polikov V, Tresco P, Reichert W . Response of brain tissue to chronically implanted neural electrodes. J Neurosci Methods. 2005; 148(1):1-18. DOI: 10.1016/j.jneumeth.2005.08.015. View

11.

McCreery D, Cogan S, Kane S, Pikov V . Correlations between histology and neuronal activity recorded by microelectrodes implanted chronically in the cerebral cortex. J Neural Eng. 2016; 13(3):036012. PMC: 7479968. DOI: 10.1088/1741-2560/13/3/036012. View

12.

Joo H, Fan J, Chen S, Pebbles J, Liang H, Chung J . A microfabricated, 3D-sharpened silicon shuttle for insertion of flexible electrode arrays through dura mater into brain. J Neural Eng. 2019; 16(6):066021. PMC: 7036288. DOI: 10.1088/1741-2552/ab2b2e. View

13.

Guitchounts G, Markowitz J, Liberti W, Gardner T . A carbon-fiber electrode array for long-term neural recording. J Neural Eng. 2013; 10(4):046016. PMC: 3875136. DOI: 10.1088/1741-2560/10/4/046016. View

14.

Stiller A, Black B, Kung C, Ashok A, Cogan S, Varner V . A Meta-Analysis of Intracortical Device Stiffness and Its Correlation with Histological Outcomes. Micromachines (Basel). 2018; 9(9). PMC: 6187651. DOI: 10.3390/mi9090443. View

15.

Apollo N, Murphy B, Prezelski K, Driscoll N, Richardson A, Lucas T . Gels, jets, mosquitoes, and magnets: a review of implantation strategies for soft neural probes. J Neural Eng. 2020; 17(4):041002. PMC: 8152109. DOI: 10.1088/1741-2552/abacd7. View

16.

McIlvain G, Ganji E, Cooper C, Killian M, Ogunnaike B, Johnson C . Reliable preparation of agarose phantoms for use in quantitative magnetic resonance elastography. J Mech Behav Biomed Mater. 2019; 97:65-73. PMC: 6699912. DOI: 10.1016/j.jmbbm.2019.05.001. View

17.

Deku F, Frewin C, Stiller A, Cohen Y, Aqeel S, Joshi-Imre A . Amorphous Silicon Carbide Platform for Next Generation Penetrating Neural Interface Designs. Micromachines (Basel). 2018; 9(10). PMC: 6215182. DOI: 10.3390/mi9100480. View

18.

Shoffstall A, Srinivasan S, Willis M, Stiller A, Ecker M, Voit W . A Mosquito Inspired Strategy to Implant Microprobes into the Brain. Sci Rep. 2018; 8(1):122. PMC: 5760625. DOI: 10.1038/s41598-017-18522-4. View

19.

Ghazavi A, Gonzalez-Gonzalez M, Romero-Ortega M, Cogan S . Intraneural ultramicroelectrode arrays for function-specific interfacing to the vagus nerve. Biosens Bioelectron. 2020; 170:112608. PMC: 7654841. DOI: 10.1016/j.bios.2020.112608. View

20.

Sridharan A, Nguyen J, Capadona J, Muthuswamy J . Compliant intracortical implants reduce strains and strain rates in brain tissue in vivo. J Neural Eng. 2015; 12(3):036002. PMC: 4460006. DOI: 10.1088/1741-2560/12/3/036002. View