Your search keyword '"Silicon electrode"' showing total 2 results

1. Effect of Insertion Speed on Tissue Response and Insertion Mechanics of a Chronically Implanted Silicon-Based Neural Probe.

Author

Welkenhuysen, M., Andrei, A., Ameye, L., Eberle, W., and Nuttin, B.

Subjects

*IMMUNOHISTOCHEMISTRY, *SILICON, *BRAIN models, *TISSUE wounds, *ELECTRONIC probes, *ARTIFICIAL implants, *BRAIN chemistry

Abstract

In this study, the effect of insertion speed on long-term tissue response and insertion mechanics was investigated. A dummy silicon parylene-coated probe was used in this context and implanted in the rat brain at 10 μm/s (n = 6) or 100 μm/s ( n = 6) to a depth of 9 mm. The insertion mechanics were assessed by the dimpling distance, and the force at the point of penetration, at the end of the insertion phase, and after a 3-min rest period in the brain. After 6 weeks, the tissue response was evaluated by estimating the amount of gliosis, inflammation, and neuronal cell loss with immunohistochemistry. No difference in dimpling, penetration force, or the force after a 3-min rest period in the brain was observed. However, the force at the end of the insertion phase was significantly higher when inserting the probes at 100 μm/s compared to 10 μm/s. Furthermore, an expected tissue response was seen with an increase of glial and microglial reactivity around the probe. This reaction was similar along the entire length of the probe. However, evidence for a neuronal kill zone was observed only in the most superficial part of the implant. In this region, the lesion size was also greatest. Comparison of the tissue response between insertion speeds showed no differences. [ABSTRACT FROM PUBLISHER]

Published

2011

2. In-Vivo Implant Mechanics of Flexible, Silicon-Based ACREO Microelectrode Arrays in Rat Cerebral Cortex.

Author

Jensen, Winnie, Yoshida, Ken, and Hofmann, Ulrich G.

Subjects

*DIAGNOSIS of brain diseases, *BRAIN, *RADIOGRAPHY, *ELECTRODES, *CEREBRAL cortex, *MICROELECTRODES, *NEURAL stimulation

Abstract

The mechanical behavior of an electrode during implantation into neural tissue can have a profound effect on the neural connections and signaling that takes place within the tissue. The objective of the present work was to investigate the in vivo implant mechanics of flexible, silicon-based ACREO microelectrode arrays recently developed by the VSAMUEL consortium (European Union, grant #IST-1999-10073). We have previously reported on both the electrical [1]-[3] and mechanical [4], [5] properties of the ACREO electrodes. In this paper, the tensile and compression forces were measured during a series of in vivo electrode insertions into the cerebral cortex of rats (7 acute experiments, 2-mm implant depth, 2-mm/s insertion velocity). We compared the ACREO silicon electrodes (40 opening angle, 1-8 shafts) to single-shaft tungsten electrodes (3° and 100 opening angles). The penetration force and dimpling increased with the cross-sectional area (statistical difference between the largest and the smallest electrode) and with the number of shafts (no statistical difference). We consistently observed tensile (drag) forces during the retraction phase, which indicates the brain tissue sticks to the electrode within a short time period. Treating the electrodes prior to insertion with silane (hydrophobic) or piranha (hydrophilic) significantly decreased the penetration force. In conclusion, our findings suggest that reusable electrodes for acute animal experiments must not only be strong enough to survive a maximal force that exceeded the penetration force, but must also be able to withstand high tension forces during retraction. Careful cleaning is not only important to avoid foreign body response, but can also reduce the stress applied to the electrode while penetrating the brain tissue. [ABSTRACT FROM AUTHOR]

Published

2006