Nicholas F Nolta1, Pejman Ghelich1, Alpaslan Ersöz1, Martin Han1,2. 1. Department of Biomedical Engineering, University of Connecticut, Storrs, CT, United States of America. 2. Institute of Materials Science, University of Connecticut, Storrs, CT, United States of America.
Abstract
OBJECTIVE: Chronically-implanted neural microelectrodes are powerful tools for neuroscience research and emerging clinical applications, but their usefulness is limited by their tendency to fail after months in vivo. One failure mode is the degradation of insulation materials that protect the conductive traces from the saline environment. APPROACH: Studies have shown that material degradation is accelerated by mechanical stresses, which tend to concentrate on raised topographies such as conducting traces. Therefore, to avoid raised topographies, we developed a fabrication technique that recesses (buries) the traces in dry-etched, self-aligned trenches. MAIN RESULTS: The fabrication technique produced flatness within approximately 15 nm. Finite element modeling showed that the recessed geometry would be expected to reduce intrinsic stress concentrations in the insulation layers. Finally, in vitro electrochemical tests confirmed that recessed traces had robust recording and stimulation capabilities that were comparable to an established non-recessed device design. SIGNIFICANCE: Our recessed trace fabrication technique requires no extra masks, is easy to integrate with existing processes, and is likely to improve the long-term performance of implantable neural devices.
OBJECTIVE: Chronically-implanted neural microelectrodes are powerful tools for neuroscience research and emerging clinical applications, but their usefulness is limited by their tendency to fail after months in vivo. One failure mode is the degradation of insulation materials that protect the conductive traces from the saline environment. APPROACH: Studies have shown that material degradation is accelerated by mechanical stresses, which tend to concentrate on raised topographies such as conducting traces. Therefore, to avoid raised topographies, we developed a fabrication technique that recesses (buries) the traces in dry-etched, self-aligned trenches. MAIN RESULTS: The fabrication technique produced flatness within approximately 15 nm. Finite element modeling showed that the recessed geometry would be expected to reduce intrinsic stress concentrations in the insulation layers. Finally, in vitro electrochemical tests confirmed that recessed traces had robust recording and stimulation capabilities that were comparable to an established non-recessed device design. SIGNIFICANCE: Our recessed trace fabrication technique requires no extra masks, is easy to integrate with existing processes, and is likely to improve the long-term performance of implantable neural devices.
Authors: Ryan Caldwell; Matthew G Street; Rohit Sharma; Pavel Takmakov; Brian Baker; Loren Rieth Journal: Biomaterials Date: 2019-12-28 Impact factor: 12.479
Authors: Adrien A Eshraghi; Ronen Nazarian; Fred F Telischi; Suhrud M Rajguru; Eric Truy; Chhavi Gupta Journal: Anat Rec (Hoboken) Date: 2012-10-08 Impact factor: 2.064
Authors: Abhishek Prasad; Qing-Shan Xue; Robert Dieme; Viswanath Sankar; Roxanne C Mayrand; Toshikazu Nishida; Wolfgang J Streit; Justin C Sanchez Journal: Front Neuroeng Date: 2014-02-04
Authors: Tian-Ming Fu; Guosong Hong; Robert D Viveros; Tao Zhou; Charles M Lieber Journal: Proc Natl Acad Sci U S A Date: 2017-11-06 Impact factor: 11.205