Scaling up of a Self‐Confined Catalytic Hybridization Circuit for Robust microRNA Imaging

Abstract The precise regulation of cellular behaviors within a confined, crowded intracellular environment is highly amenable in diagnostics and therapeutics. While synthetic circuitry system through a concatenated chemical reaction network has rarely been reported to mimic dynamic self‐assembly system. Herein, a catalytic self‐defined circuit (CSC) for the hierarchically concatenated assembly of DNA domino nanostructures is engineered. By incorporating pre‐sealed symmetrical fragments into the preying hairpin reactants, the CSC system allows the hierarchical DNA self‐assembly via a microRNA (miRNA)‐powered self‐sorting catalytic hybridization reaction. With minimal strand complexity, this self‐sustainable CSC system streamlined the circuit component and achieved localization‐intensified cascaded signal amplification. Profiting from the self‐adaptively concatenated hybridization reaction, a reliable and robust method has been achieved for discriminating carcinoma tissues from the corresponding para‐carcinoma tissues. The CSC‐sustained self‐assembly strategy provides a comprehensive and smart toolbox for organizing various hierarchical DNA nanostructures, which may facilitate more insights for clinical diagnosis and therapeutic assessment.