4.8 Article

DNA aerogels and DNA-wrapped CNT aerogels for neuromorphic applications

期刊

MATERIALS TODAY BIO
卷 16, 期 -, 页码 -

出版社

ELSEVIER
DOI: 10.1016/j.mtbio.2022.100440

关键词

DNA aerogel; DNA -wrapped CNT aerogel; Resistive switching; Neuromorphic application; Self -assembly

资金

  1. National Science Foundation through award [NSF-CISE-CCF 1748459]
  2. State of North Carolina
  3. National Science Foundation [ECCS-2025064]

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This study presents the successful construction of pure DNA aerogels and DNA-wrapped carbon nanotube (CNT) composite aerogels. These aerogels exhibit highly porous and randomly branched structures with low density. The pure DNA aerogel behaves like a simple capacitor, while the DNA-CNT aerogel demonstrates resistive switching behavior similar to a volatile memristor. These novel aerogels can potentially serve as a platform for developing biomimetic devices for various applications and pave the way for constructing aerogel-based material platforms from DNA-coated or wrapped functional entities.
Nucleic acids are programmable materials that can self-assemble into defined or stochastic three-dimensional network architectures. Various attributes of self-assembled, cross-linked Deoxyribonucleic acid (DNA) hydrogels have recently been investigated, including their mechanical properties and potential biomedical functions. Herein, for the first time, we describe the successful construction of pure DNA aerogels and DNA-wrapped carbon nanotube (CNT) composite (DNA-CNT) aerogels via a single-step freeze-drying of the respective hydrogels. These aerogels reveal highly porous and randomly branched structures with low density. The electrical properties of pure DNA aerogel mimic that of a simple capacitor; in contrast, the DNA-CNT aerogel displays a fascinating resistive switching behavior in response to an applied bias voltage sweep reminiscent of a volatile memristor. We believe these novel aerogels can serve as a platform for developing complex biomimetic devices for a wide range of applications, including real-time computation, neuromorphic computing, biochemical sensing, and biodegradable functional implants. More importantly, insight obtained here on self-assembling DNA to create aerogels will pave the way to construct novel aerogel-based material platforms from DNA coated or wrapped functional entities.

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