One-Pot CRISPR-Based Isothermal Amplification for Nucleic Acid Detection: A Comparative Review of Different Strategies
Cong Shi, Yu Zhou, Huimin Tan, Weilin Li, Yingjun Wang, Yingjun Wang, Yun Wang, Yun Wang, Qinghai Zhang, Yan Man
Abstract
Nucleic acid detection plays an important role in pathogen monitoring and disease diagnosis. CRISPR one-pot assays combined with isothermal amplification are emerging as promising point-of-care technologies that simplify workflows while increasing sensitivity and specificity. However, the incompatibility inherent in the one-pot reaction of isothermal amplification and CRISPR detection limits their practical application. This review comprehensively analyzes diverse advanced one-pot CRISPR-based isothermal amplification strategies developed to overcome this fundamental challenge. These strategies primarily encompass physical separation strategies (utilizing lid-bottom, internal ledge, nested tube, and membrane approaches), phase separation strategies (employing glycerol, sucrose, and gel matrices), reaction system optimization strategies (fine-tuning reaction parameters and incorporating specialized additives), non-PAM and suboptimal PAM strategies, improved Cas enzyme strategies (enhanced Cas12 and Cas13 variants), light-controlled approaches (PC-oligonucleotides, NPOM-dt modification, and acylation modification), and microfluidic chip integration strategies (centrifugal microfluidic chips, droplet microfluidic chips, and microarray chips). These methodological approaches have achieved important advances in simplifying operational processes, enhancing sensitivity, shortening detection cycles, and minimizing cross-contamination risks. The review further synthesizes critical insights regarding current opportunities, technical challenges, and future directions for one-pot CRISPR-based isothermal amplification technologies in nucleic acid detection, providing valuable guidance for researchers and practitioners in this evolving field.