Coupling CRISPR-Cas and a personal glucose meter with an enzymatic reporter for portable detection of human papillomavirus in biological samples.

Significant efforts and resources have been dedicated to developing CRISPR-Cas based point-of-care testing (POCT) and self-diagnosis methods for nucleic acid pathogens, aiming to complement the gold standard quantitative PCR tests, particularly in settings where centralized facilities, trained personnel, or resource-intensive equipment are unavailable. However, the reliance on stationary, high-cost readout machinery hinders their full deployment at the point of care. We aimed to develop a solid-phase invertase-labeled reporter (ILR) system that enables convenient readout of CRISPR-Cas reactions, facilitate HPV detection in a POCT-compatible manner. Through multiple chemical couplings, invertase is immobilized onto magnetic microbeads via a nucleic acid linker that responds to target nucleic acid-induced CRISPR-Cas activation. This activation releases active invertase, which then converts sucrose to glucose in proportion to the target's abundance. Enzymatic signal amplification by Cas12a/Cas13a and invertase compensates for the moderate sensitivity of personal glucose meters (PGMs). When applied to human papillomavirus detection, the HPV18-targeted LAMP-Cas12a/ILR/PGM system can detect as few as 7 HPV18-positive HeLa cells out of 7,000, achieving 95.8% sensitivity and 100% specificity in cervical cell samples. Furthermore, minimal reagent adjustments allow for the rapid establishment of HPV16 and HPV52-targeted LAMP-Cas12a/ILR/PGM systems, offering satisfactory sensitivity, specificity, and cross-species detection. These findings demonstrate a highly efficient testing platform for a range of nucleic acid pathogens, suitable for both point-of-care and household use.