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Solid-State Single-Molecule Sensing with the Electronic Life-Detection Instrument for Enceladus/Europa (ELIE).
Carr, Christopher E; Ramírez-Colón, José L; Duzdevich, Daniel; Lee, Sam; Taniguchi, Masateru; Ohshiro, Takahito; Komoto, Yuki; Soderblom, Jason M; Zuber, M T.
  • Carr CE; Daniel Guggenheim School of Aerospace Engineering, Georgia Institute of Technology, Atlanta, Georgia, USA.
  • Ramírez-Colón JL; School of Earth and Atmospheric Sciences, Georgia Institute of Technology, Atlanta, Georgia, USA.
  • Duzdevich D; School of Earth and Atmospheric Sciences, Georgia Institute of Technology, Atlanta, Georgia, USA.
  • Lee S; Massachusetts General Hospital, Department of Molecular Biology, Boston, Massachusetts, USA.
  • Taniguchi M; Howard Hughes Medical Institute, Boston, Massachusetts, USA.
  • Ohshiro T; Current address: Department of Chemistry, University of Chicago, Chicago, Illinois, USA.
  • Komoto Y; MIT Department of Electrical Engineering and Computer Science, Cambridge, Massachusetts, USA.
  • Soderblom JM; Osaka University, Institute of Scientific and Industrial Research, Osaka, Japan.
  • Zuber MT; Osaka University, Institute of Scientific and Industrial Research, Osaka, Japan.
Astrobiology ; 23(10): 1056-1070, 2023 10.
Article en En | MEDLINE | ID: mdl-37782210
Growing evidence of the potential habitability of Ocean Worlds across our solar system is motivating the advancement of technologies capable of detecting life as we know it-sharing a common ancestry or physicochemical origin with life on Earth-or don't know it, representing a distinct emergence of life different than our one known example. Here, we propose the Electronic Life-detection Instrument for Enceladus/Europa (ELIE), a solid-state single-molecule instrument payload that aims to search for life based on the detection of amino acids and informational polymers (IPs) at the parts per billion to trillion level. As a first proof-of-principle in a laboratory environment, we demonstrate the single-molecule detection of the amino acid L-proline at a 10 µM concentration in a compact system. Based on ELIE's solid-state quantum electronic tunneling sensing mechanism, we further propose the quantum property of the HOMO-LUMO gap (energy difference between a molecule's highest energy-occupied molecular orbital and lowest energy-unoccupied molecular orbital) as a novel metric to assess amino acid complexity. Finally, we assess the potential of ELIE to discriminate between abiotically and biotically derived α-amino acid abundance distributions to reduce the false positive risk for life detection. Nanogap technology can also be applied to the detection of nucleobases and short sequences of IPs such as, but not limited to, RNA and DNA. Future missions may utilize ELIE to target preserved biosignatures on the surface of Mars, extant life in its deep subsurface, or life or its biosignatures in a plume, surface, or subsurface of ice moons such as Enceladus or Europa. One-Sentence Summary: A solid-state nanogap can determine the abundance distribution of amino acids, detect nucleic acids, and shows potential for detecting life as we know it and life as we don't know it.
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Texto completo: 1 Banco de datos: MEDLINE Asunto principal: Ácidos Nucleicos / Júpiter Tipo de estudio: Diagnostic_studies Idioma: En Año: 2023 Tipo del documento: Article

Texto completo: 1 Banco de datos: MEDLINE Asunto principal: Ácidos Nucleicos / Júpiter Tipo de estudio: Diagnostic_studies Idioma: En Año: 2023 Tipo del documento: Article