Department of Chemistry, Taizhou University, Jiaojiang, 318000, China.
Nanoscale. 2019 Mar 14;11(11):5048-5057. doi: 10.1039/c8nr10103e.
The integration of multi-level DNA logic gates for biological diagnosis is far from being fully realized. In particular, the simplification of logical analysis to implement advanced logic diagnoses is still a critical challenge for DNA computing and bioelectronics. Here, we developed a magnetic bead/DNA system to construct a library of logic gates, enabling the sensing of multiplex target miRNAs. In this assay, the miRNA-catalyzed hairpin assembly (CHA) was successfully applied to construct two/three-input concatenated logic circuits with excellent specificity extended to design a highly sensitive multiplex detection system. Significantly, the CHA-based multiplex detection system can distinguish individual target miRNAs (such as miR-21, miR-155, and miR let-7a) under a logic function control, which presents great applications in the development of rapid and intelligent detection. Another novel feature is that the multiplex detection system can be reset by heating the output system and the magnetic separation of the computing modules. Overall, the proposed logic diagnostics with high amplification efficiency is simple, fast, low-cost, and resettable, and holds great promise in the development of biocomputing, multiparameter sensing, and intelligent disease diagnostics.
用于生物诊断的多层次 DNA 逻辑门的集成远未完全实现。特别是,简化逻辑分析以实现高级逻辑诊断仍然是 DNA 计算和生物电子学的一个关键挑战。在这里,我们开发了一个磁珠/DNA 系统来构建一个逻辑门库,实现对多种靶标 miRNA 的传感。在该测定中,miRNA 催化的发夹组装 (CHA) 成功地应用于构建具有优异特异性的两个/三个输入级联逻辑电路,进一步扩展到设计高灵敏度的多重检测系统。重要的是,基于 CHA 的多重检测系统可以在逻辑功能控制下区分单个靶标 miRNA(如 miR-21、miR-155 和 miR let-7a),这在快速和智能检测的发展中具有很大的应用价值。另一个新颖的特点是,多重检测系统可以通过加热输出系统和计算模块的磁分离进行重置。总的来说,所提出的具有高放大效率的逻辑诊断具有简单、快速、低成本和可重置的特点,在生物计算、多参数传感和智能疾病诊断的发展中具有广阔的应用前景。