纳米孔
外体
纳米技术
DNA
微泡
分析物
纳米孔测序
细胞生物学
生物物理学
计算生物学
DNA纳米技术
化学
材料科学
生物
纳米生物技术
纳米医学
分子识别
DNA测序
纳米传感器
氮化硅
内体
A-DNA
核糖核酸
染色体易位
分子生物物理学
纳米颗粒
核酸
分子诊断学
纳米尺度
作者
Ke Jiao,G P Wang,Tao Cheng,Heng Zhou,Zhan Wang,刘业翔,Yanrong Chen,Yingzhuang Ma,Jin Jiao,Qing Zhao
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-06-19
卷期号:20 (25): 18479-18490
标识
DOI:10.1021/acsnano.6c06233
摘要
Solid-state nanopores are powerful single-molecule sensing tools, but their reliance on direct translocation requires high analyte concentrations and complicates biochemical specificity. We propose a DNA nanotransduction strategy featuring target-specific molecular recognition and standardized electrical readout, converting complex vesicular information into uniform reporter signals. Glioma-derived exosomes are selectively captured by a dual-aptamer DNA scaffold, which disassembles to release tetrahedral DNA nanostructures (TDNs) as reporter molecules. Since each type of protein on the exosome surface is expressed in multiple copies, each exosome recognition event is translated into multiple translocation signals, shifting from a one-to-one to a one-to-many amplification process. This strategy reduces concentration dependence and relocates specificity to a programmable DNA system, avoiding instability from pore functionalization. Using ∼10 nm silicon nitride nanopores, we demonstrate highly sensitive and specific detection of glioma-derived exosomes and accurate classification in clinical samples. This work establishes a DNA-based nanotransduction system that enhances the versatility of solid-state nanopores for detecting low-abundance biomarkers in complex biological environments, advancing clinical applications.
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