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Super-small needle technology for the brain

Dissolvable material expands opportunities for flexible microneedles used for brain penetrations

Date:
August 10, 2015
Source:
Toyohashi University of Technology
Summary:
A methodology for brain penetration using diameter flexible needles has been developed by scientists. This should further reduce invasiveness and provide tissue penetrations hardly broken than conventional approaches.
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This image shows flexible high-aspect-ratio microneedles penetrating brain tissue.
Credit: COPYRIGHT(C)TOYOHASHI UNIVERSITY OF TECHNOLOGY. ALL RIGHTS RESERVED

Microscale needle-electrode array technology has enhanced brain science and engineering applications, such as electrophysiological studies, drug and chemical delivery systems, and optogenetics.

However, one challenge is reducing the tissue/neuron damage associated with needle penetration, particularly for chronic insert experiment and future medical applications. A solution strategy is to use microscale-diameter needles (e.g., < 5 μm) with flexible properties. However, such physically limited needles cannot penetrate the brain and other biological tissues because of needle buckling or fracturing on penetration.

A research team in the Department of Electrical and Electronic Information Engineering and the Electronics-Inspired Interdisciplinary Research Institute (EIIRIS) at Toyohashi University of Technology has developed a methodology to temporarily enhance the stiffness of a long, high-aspect-ratio flexible microneedle (e.g., < 5 μm in diameter and > 500 μm in length), without affecting the needle diameter and flexibility in tissue. This has been accomplished by embedding a needle base in a film scaffold, which dissolves upon contact with biological tissue. Silk fibroin is used as the dissolvable film because it has high biocompatibility, and is a known biomaterial used in implantable devices.

"We investigated preparation of a silk base scaffold for a microneedle, quantitatively analyzed needle stiffness, and evaluated the penetration capability by using mouse brains in vitro/in vivo. In addition, as an actual needle application, we demonstrated fluorescenctce particle depth injection into the brain in vivo,and confirm that by observing fluorescenctce confocal microscope" explained the first author, master's degree student Satoshi Yagi, and co-author PhD candidate Shota Yamagiwa.

The leader of the research team, Associate Professor Takeshi Kawano said: "Preparation of the dissolvable base scaffold is very simple, but this methodology promises powerful tissue penetrations using numerous high-aspect-ratio flexible microneedles, including recording/stimulation electrodes, glass pipettes, and optogenetic fibers." He added: "This has the potential to reduce invasiveness drastically and provide safer tissue penetration than conventional approaches."


Story Source:

Materials provided by Toyohashi University of Technology. Note: Content may be edited for style and length.


Journal Reference:

  1. Satoshi Yagi, Shota Yamagiwa, Yoshihiro Kubota, Hirohito Sawahata, Rika Numano, Tatsuya Imashioya, Hideo Oi, Makoto Ishida, Takeshi Kawano. Dissolvable Base Scaffolds Allow Tissue Penetration of High-Aspect-Ratio Flexible Microneedles. Advanced Healthcare Materials, 2015; DOI: 10.1002/adhm.201500305

Cite This Page:

Toyohashi University of Technology. "Super-small needle technology for the brain: Dissolvable material expands opportunities for flexible microneedles used for brain penetrations." ScienceDaily. ScienceDaily, 10 August 2015. <www.sciencedaily.com/releases/2015/08/150810110638.htm>.
Toyohashi University of Technology. (2015, August 10). Super-small needle technology for the brain: Dissolvable material expands opportunities for flexible microneedles used for brain penetrations. ScienceDaily. Retrieved May 26, 2017 from www.sciencedaily.com/releases/2015/08/150810110638.htm
Toyohashi University of Technology. "Super-small needle technology for the brain: Dissolvable material expands opportunities for flexible microneedles used for brain penetrations." ScienceDaily. www.sciencedaily.com/releases/2015/08/150810110638.htm (accessed May 26, 2017).

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