Recent advances in carbon nanotube-based biosensors for biomolecular detection

Earlier studies have found a relationship between biomolecules in living organisms and diseases. The monitoring of abnormal physical conditions and the timely detection of diseases can reduce the mortality rate and ensure the physical health of organisms. Traditional laboratory methods for analyzing...

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Bibliographic Details
Published in:TrAC, Trends in analytical chemistry (Regular ed.) Trends in analytical chemistry (Regular ed.), 2022-09, Vol.154, p.116658, Article 116658
Main Authors: Dai, Benhui, Zhou, Ruiyun, Ping, Jianfeng, Ying, Yibin, Xie, Lijuan
Format: Article
Language:English
Subjects:
Biomolecular detection
Biosensors
Carbon nanotubes
DNA
Glucose
Neurotransmitters
Protein
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Summary:Earlier studies have found a relationship between biomolecules in living organisms and diseases. The monitoring of abnormal physical conditions and the timely detection of diseases can reduce the mortality rate and ensure the physical health of organisms. Traditional laboratory methods for analyzing pathogenic factors usually require long time, high cost, and complex process. Biosensors can provide timely and accurate analysis of metabolites in the body to provide support for modern treatment. The unique physico-chemical and photoelectric properties of carbon nanotubes (CNTs) can improve the performance of biosensors, such as the larger surface area for better catalyst fixation and the CNT-modified electrodes for faster electron transfer which provide more sensitive detection of biosensors. Typical applications of CNT-based sensors are described in detail in this article, including detections of glucose detection, DNA, protein, amino acids, and neurotransmitter. The detection performance of sensors can be improved through the continuous improvement of materials and structures. Finally, a summary and future outlook for CNT-based biosensors are provided. •Functional properties of CNTs for constructing biosensors are introduced.•Some progress in the development of CNT-based biosensors is discussed.•Applications to biomolecular detection using CNT-based biosensors are reviewed.•Major challenges and future perspectives are discussed.
ISSN:0165-9936
1879-3142
DOI:10.1016/j.trac.2022.116658