Electronic stimulation has been shown to be a valuable approach to controlling the structure and function of tissues and organs. Micro-electrical-mechanical systems (MEMS) have been utilized extensively in biomedical engineering including applications in biosensors and drug delivery systems. However, the lack of reportable electronic systems has limited the potential impact of MEMS for tissue engineering applications. This limitation primarily arises due to the use of unsuitable materials. MEMS designed for biomedical applications have been fabricated using traditional inorganic materials such as silicon and silicon dioxide. Non-degradable polymers such as polyethylene, silicone, and polytetrafluoroethylene have also been used. Although these materials are amenable to facile fabrication techniques and exhibit in vivo biocompatibility, they are not biodegradable. The fabrication of biodegradable, electronically active tissue engineering scaffolds for in vivo tissue engineering and organ regeneration applications has the potential for significant impact, especially in the treatment of neurological-based traumas and diseases. Toward this end, this proposal aims to utilize novel biomaterials for the fabrication of resorbable field-effect transistor, which is to serve as the building block of more complex electronic devices including electronically active tissue engineering scaffolds. The current library of available biomaterials, both natural and synthetic, provides an adequate spectrum of physical properties that would allow for the fabrication of biodegradable electronic components. This technological advance will enable the use resorbable electronic components for a variety of in vivo biomedical applications including tissue engineering scaffolds. These scaffolds could be seeded with cells, implanted into the host, and electrically stimulated externally via radiofrequency signalling. These scaffolds would then resorb within the host within the desired timeframe. PUBLIC HEALTH REVELANCE - Electronically active tissue engineering scaffolds can provide a method to promote tissue regeneration through electronic stimulation. Biodegradable electronic devices with embedded logic could lead to temporary implantable devices that can provide electronic stimulation to cells seeded on the scaffold as well as surrounding tissue via external triggering. The scaffolds could be implanted, serve their specified function over a pre-programmed time scale, and would then eventually become resorbed within the body.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Postdoctoral Individual National Research Service Award (F32)
Project #
1F32NS064771-01
Application #
7611447
Study Section
Special Emphasis Panel (ZRG1-F14-G (20))
Program Officer
Kleitman, Naomi
Project Start
2009-01-01
Project End
2010-12-31
Budget Start
2009-01-01
Budget End
2009-12-31
Support Year
1
Fiscal Year
2009
Total Cost
$45,218
Indirect Cost
Name
Stanford University
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
009214214
City
Stanford
State
CA
Country
United States
Zip Code
94305
Kustra, Stephen; Wu, Haosheng; Basu, Saurav et al. (2012) High-throughput arrays for rapid characterization of solution-processable transparent conducting electrodes. Small 8:3746-51
Muskovich, Meredith; Bettinger, Christopher J (2012) Biomaterials-based electronics: polymers and interfaces for biology and medicine. Adv Healthc Mater 1:248-66
Lin, Debora W; Bettinger, Christopher J; Ferreira, Joshua P et al. (2011) A cell-compatible conductive film from a carbon nanotube network adsorbed on poly-L-lysine. ACS Nano 5:10026-32
Bettinger, Christopher J; Becerril, Hector A; Kim, Do Hwan et al. (2011) Microfluidic arrays for rapid characterization of organic thin-film transistor performance. Adv Mater 23:1257-61
Bettinger, Christopher J; Bao, Zhenan (2010) Biomaterials-Based Organic Electronic Devices. Polym Int 59:563-567
Bettinger, Christopher J; Bao, Zhenan (2010) Organic thin-film transistors fabricated on resorbable biomaterial substrates. Adv Mater 22:651-5
Bettinger, Christopher J; Kulig, Katherine M; Vacanti, Joseph P et al. (2009) Nanofabricated collagen-inspired synthetic elastomers for primary rat hepatocyte culture. Tissue Eng Part A 15:1321-9