Glass Capillary-Based Nanopores for Single Molecule/Single Cell Detection.
Xin GuanHaijuan LiLimei ChenGuohua QiYongdong JinPublished in: ACS sensors (2023)
A glass capillary-based nanopore (G-nanopore), due to its tapered tip, easy tunability in orifice size, and especially its flexible surface modifications that can be tailored to effectively capture and enhance the ionic current signal of single entities (single molecules, single cells, and single particles), offers a powerful and nanoconfined sensing platform for diverse biological measurements of single cells and single molecules. Compared with other artificial two-dimensional solid-state nanopores, its conical tip and high spatial and temporal resolution characteristics facilitate noninvasive single molecule and selected area (subcellular) single cell detections (e.g., DNA mutations, highly expressed proteins, and small molecule markers that reflect the change characteristics of the tumor), as a small G-nanopore (≤100 nm) does negligible damage to cell functions and cell membrane integrity when inserted through the cell membrane. In this brief review, we summarize the preparation of G-nanopores and discuss the advantages of them as solid-state sensing platforms for single molecule and single cell detection applications as well as for cancer diagnosis and treatment applications. We also describe the current bottlenecks that limit the widespread use of G-nanopores in clinical applications and provide an outlook on future developments. The brief review will provide the reader with a quick survey of this field and facilitate the rapid development of a G-nanopore sensing platform for future tumor diagnosis and personalized medicine based on single-molecule/single-cell bioassay.
Keyphrases
- single molecule
- single cell
- solid state
- living cells
- atomic force microscopy
- rna seq
- high throughput
- small molecule
- induced apoptosis
- oxidative stress
- signaling pathway
- cell cycle arrest
- mesenchymal stem cells
- cell therapy
- mass spectrometry
- papillary thyroid
- pi k akt
- squamous cell
- sensitive detection
- liquid chromatography