Litcius/Paper detail

Programming the Dynamic Range of Nanochannel Biosensors for MicroRNA Detection Through Allosteric DNA Probes

Zhiwei Shang, Defang Ding, Zixuan Deng, J. Zhao, Mengyu Yang, Yuling Xiao, Wenjing Chu, Shijun Xu, Zhicheng Zhang, Xiaoqing Yi, Meihua Lin, Fan Xia

2024Angewandte Chemie International Edition11 citationsDOIOpen Access PDF

Abstract

Solid-state nanochannel biosensors are extensively utilized for microRNA (miRNA) detection owing to their high sensitivity and rapid response. However, conventional nanochannel biosensors face limitations in their fixed dynamic range, restricting their versatility and efficacy. Herein, we introduce tunable triblock DNA probes with varying affinities for target miRNA to engineer solid-state nanochannel biosensors capable of customizable dynamic range adjustment. The triblock DNA architecture comprises a poly-adenine (polyA) block for adjustable surface density anchoring, alongside stem and loop blocks for modulating structural stability. Through systematic manipulation of these blocks, we demonstrate the ability to achieve diverse target binding affinities and detection limits, achieving an initial 81-fold dynamic range. By combining probes with various affinities, we extend this dynamic range significantly to 10,900-fold. Furthermore, by implementing a sequestration mechanism, the effective dynamic range of the nanochannel biosensor is narrowed to only a 3-fold span of target concentrations. The customizable dynamic range of these advanced nanochannel biosensors makes them highly promising for a broad spectrum of biomedical and clinical applications.

Topics & Concepts

Allosteric regulationBiosensorNanotechnologyRange (aeronautics)microRNADNAComputational biologyDynamic rangeComputer scienceBiophysicsChemistryBiologyMaterials scienceEngineeringBiochemistryGeneAerospace engineeringEnzymeComputer visionAdvanced biosensing and bioanalysis techniquesNanopore and Nanochannel Transport StudiesRNA Interference and Gene Delivery