Liquid crystal elastomers as substrates for 3D, robust, implantable electronics

New device architectures favorable for interaction with the soft and dynamic biological tissue are critical for the design of indwelling biosensors and neural interfaces. For the long-term use of such devices within the body, it is also critical that the component materials resist the physiological...

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Bibliographic Details
Published in:Journal of materials chemistry. B, Materials for biology and medicine Materials for biology and medicine, 2020-08, Vol.8 (29), p.6286-6295
Main Authors: Maeng, Jimin, Rihani, Rashed T, Javed, Mahjabeen, Rajput, Jai Singh, Kim, Hyun, Bouton, Ian G, Criss, Tyler A, Pancrazio, Joseph J, Black, Bryan J, Ware, Taylor H
Format: Article
Language:English
Subjects:
Biosensing Techniques - instrumentation
Biosensors
Cables
Computer architecture
Durability
Elastomers
Elastomers - chemistry
Electrical Equipment and Supplies
Electronics
Equipment Design
Fabrication
Interfaces
Liquid crystals
Liquid Crystals - chemistry
Mechanical properties
Photolithography
Physiology
Prostheses and Implants
Robustness
Substrates
Surgical implants
Tissues
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Summary:New device architectures favorable for interaction with the soft and dynamic biological tissue are critical for the design of indwelling biosensors and neural interfaces. For the long-term use of such devices within the body, it is also critical that the component materials resist the physiological harsh mechanical and chemical conditions. Here, we describe the design and fabrication of mechanically and chemically robust 3D implantable electronics. This is achieved by using traditional photolithography to pattern electronics on liquid crystal elastomers (LCEs), a class of shape programmable materials. The chemical durability of LCE is evaluated under accelerated in vitro conditions simulating the physiological environment; for example, LCE exhibits less than 1% mass change under a hydrolytic medium simulating >1 year in vivo . By employing twisted nematic LCEs as dynamic substrates, we demonstrate electronics that are fabricated on planar substrates but upon release morph into programmed 3D shapes. These shapes are designed to enable intrinsically low failure strain materials to be extrinsically stretchable. For example, helical multichannel cables for electrode arrays withstand cyclic stretching and buckling over 10 000 cycles at 60% strain while being soaked in phosphate-buffered saline. We envision that these LCE-based electronics can be used for applications in implantable neural interfaces and biosensors. Liquid crystal elastomers are used as substrates for robust, implantable electronics that are planar processed then morph into 3D shapes.
ISSN:2050-750X
2050-7518
DOI:10.1039/d0tb00471e