Logic-gated CRISPR-Cas12a assay with engineered signal amplification for sensitive multiplexed detection of HCC miRNAs.

Rapid, sensitive, and accurate multi-target analysis is of great significance in biomedical detection. Traditional methods, however, often function as a mere "one-pot" collection of individual assays, ignoring the intrinsic relationships among biomarkers. To address this, we established a novel biosensing platform that integrates circle-to-circle AND logic gate circuit with an engineered CRISPR-Cas system for the early screening of hepatocellular carcinoma. In this design, the logic gate processes multiple miRNA inputs (e.g., miRNA 122 and miRNA 223), and only upon co-recognition, generates a unified DNA output. This output then directly activates a CRISPR-Cas12a system, which has been enhanced by a multi-legged crRNA assembled on a DNA tetrahedra and a cube-based framework probe to enhance the trans-cleavage activity and reaction kinetics. This integration converts complex multi-target recognition into a single, amplified detection signal, minimizing systemic interference. Under optimal conditions, the method achieved detection limits as low as 78.88 fM for miRNA 122 and 65.26 fM for miRNA 223, with serum recovery rates of 89.66 %-108.08 %. Clinical validation using 36 samples showed that excellent correlation with RT-qPCR (all R > 0.98) and areas under the ROC curves of 0.8514 and 0.9244, effectively distinguishing liver cancer patients from healthy individuals. Combining high sensitivity, specificity, and clinical applicability, this strategy provides a universal platform for logic-operated multiple biomarkers analysis. Looking forward, integration with microfluidic systems could enable automated, high-throughput testing, further enhancing its utility in point-of-care diagnostics. This approach holds great promise not only for early hepatocellular carcinoma screening but also, with adaptation of the input logic, for the detection of a broad spectrum of cancers and other diseases.