Abstract
Persistent infection with high-risk human papillomavirus (HR-HPV) is the leading cause of cervical cancer, highlighting the critical need for early detection to improve prevention. Although real-time quantitative polymerase chain reaction (RT-qPCR) remains the gold standard for HR-HPV detection, its dependence on sophisticated equipment, complex procedures, and trained personnel limits accessibility. Here, we developed a simplified assay for 14 HR-HPV types by integrating direct lysis, enzyme-mediated isothermal rapid amplification (ERA), and CRISPR-Cas12a-mediated cleavage into a streamlined workflow that requires only a basic isothermal heating device. The optimized system achieved a sensitivity of 50 copies per reaction with no cross-reactivity, while a refined lysis buffer containing 20% Chelex-100 minimized inhibition from vaginal swab samples, thereby enhancing detection performance. Validation with 152 clinical samples demonstrated 97.62% sensitivity and 100% specificity, confirming the reliability of the method. This user-friendly and cost-effective assay requires minimal equipment, enabling rapid and field-deployable HR-HPV detection, and offers a practical alternative to conventional laboratory-based approaches, particularly in resource-limited settings. IMPORTANCE: High-risk human papillomavirus (HR-HPV) is the principal etiological agent of cervical cancer, and early detection remains central to effective disease prevention. Current PCR-based assays, however, rely on specialized laboratories and trained personnel, limiting their deployment in many settings. Here, we report a streamlined CRISPR-Cas12a assay that integrates direct sample lysis, ERA, and CRISPR-based detection into a single workflow operable with only a simple heating device to determine the presence of 14 HR-HPV types. The assay achieves high analytical sensitivity, strong specificity, and robust clinical performance while maintaining low cost and ease of use. This platform enables rapid HR-HPV detection and scalable screening, particularly in resource-constrained environments, with the potential to facilitate earlier intervention and reduce cervical cancer incidence.