Functional nucleic acid engineered double‐barreled nanopores for measuring sodium to potassium ratio at single‐cell level

The use of double‐barreled nanopipette (θ‐nanopipette) to electrically sample, manipulate, or detect biomaterials has recently seen strong growth in single‐cell studies, driven by the potential of the nanodevices and applications that they may enable. Considering the pivotal roles of Na/K ratio (RNa...

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Bibliographic Details
Published in:Exploration (Beijing, China) China), 2022-10, Vol.2 (5), p.20220025-n/a
Main Authors: Shi, Xiao‐Mei, Liu, Fang‐Qing, Wang, Bing, Yu, Si‐Yuan, Xu, Yi‐Tong, Zhao, Wei‐Wei, Jiang, Dechen, Chen, Hong‐Yuan, Xu, Jing‐Juan
Format: Article
Language:English
Subjects:
Apoptosis
Biomaterials
Biomedical materials
Cell lines
ionic current rectification
Metastases
Metastasis
Nanotechnology devices
nucleic acid
Nucleic acids
Physiology
Potassium
Prostate
Ratios
Ribonucleic acid
RNA
single cell
Sodium
sodium to potassium ratio
θ‐nanopipette
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Summary:The use of double‐barreled nanopipette (θ‐nanopipette) to electrically sample, manipulate, or detect biomaterials has recently seen strong growth in single‐cell studies, driven by the potential of the nanodevices and applications that they may enable. Considering the pivotal roles of Na/K ratio (RNa/K) at cellular level, herein we describe an engineered θ‐nanopipette for measuring single‐cell RNa/K. The two independently addressable nanopores, located within one nanotip, allow respective customization of functional nucleic acids but simultaneous deciphering of Na and K levels inside a single cell of a non‐Faradic manner. Two ionic current rectification signals, corresponding to the Na‐ and K‐specific smart DNA responses, could be easily used to derive the RNa/K. The applicability of this nanotool is validated by practical probing intracellular RNa/K during the drug‐induced primary stage of apoptotic volume decrease. Especially, the RNa/K has been shown by our nanotool to be different in cell lines with different metastatic potential. This work is expected to contribute to futuristic study of single‐cell RNa/K in various physiological and pathological processes. Functional nucleic acid engineered double‐barreled nanopores were designed and applied for measuring Na/K ratio (RNa/K) at single‐cell level. The applicability of this nanotool is validated by practical probing intracellular RNa/K during the drug‐induced primary stage of apoptotic volume decrease. Especially, the RNa/K has been shown by our nanotool to be different in cell lines with different metastatic potential.
ISSN:2766-8509
2766-2098
2766-2098
DOI:10.1002/EXP.20220025