Multi‐Body Biomarker Entrapment System: An All‐Encompassing Tool for Ultrasensitive Disease Diagnosis and Epidemic Screening

Ultrasensitive identification of biomarkers in biofluids is essential for the precise diagnosis of diseases. For the gold standard approaches, polymerase chain reaction and enzyme‐linked immunosorbent assay, cumbersome operational steps hinder their point‐of‐care applications. Here, a bionic biomark...

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Bibliographic Details
Published in:Advanced materials (Weinheim) 2023-11, Vol.35 (46), p.e2304119-n/a
Main Authors: Ren, Qinqi, Jiang, Leying, Ma, Shenhui, Li, Tong, Zhu, Yang, Qiu, Rui, Xing, Yun, Yin, Feng, Li, Zigang, Ye, Xiyang, Zhang, Yaping, Zhang, Min
Format: Article
Language:English
Subjects:
Antigens
Biomarkers
Bionics
breast cancer
Carbon nanotubes
Diagnosis
Endometriosis
Entrapment
Epidemics
Estrogens
Materials science
Medical diagnosis
monkeypox virus
Nucleic acids
Polymerase chain reaction
Proteins
tetrahedral DNA nanostructure
transistor‐based biosensors
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Summary:Ultrasensitive identification of biomarkers in biofluids is essential for the precise diagnosis of diseases. For the gold standard approaches, polymerase chain reaction and enzyme‐linked immunosorbent assay, cumbersome operational steps hinder their point‐of‐care applications. Here, a bionic biomarker entrapment system (BioES) is implemented, which employs a multi‐body Y‐shaped tetrahedral DNA probe immobilized on carbon nanotube transistors. Clinical identification of endometriosis is successfully realized by detecting an estrogen receptor, ERβ, from the lesion tissue of endometriosis patients and establishing a standard diagnosis procedure. The multi‐body Y‐shaped BioES achieves a theoretical limit of detection (LoD) of 6.74 aM and a limit of quantification of 141 aM in a complex protein milieu. Furthermore, the BioES is optimized into a multi‐site recognition module for enhanced binding efficiency, realizing the first identification of monkeypox virus antigen A35R and unamplified detection of circulating tumor DNA of breast cancer in serum. The rigid and compact probe framework with synergy effect enables the BioES to target A35R and DNA with a LoD down to 991 and 0.21 aM, respectively. Owing to its versatility for proteins and nucleic acids as well as ease of manipulation and ultra‐sensitivity, the BioES can be leveraged as an all‐encompassing tool for population‐wide screening of epidemics and clinical disease diagnosis. A novel multi‐body biomarker entrapment system based on a carbon nanotube liquid‐gate field‐effect transistor and DNA framework engineering is proposed. This versatile platform enables clinical diagnosis of endometriosis, specific recognition of monkeypox virus antigen protein, and non‐amplification identification of circulating tumor DNA in triple‐negative breast cancer.
ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202304119