Gravity-Driven Formation of Water-in-Wax Spheres for Efficient One-Pot CRISPR Diagnostics
Yixuan Cai, Liang Zhuang, Zhijie Wang, Liang He, Xi Li, Bi-Feng Liu, Tao Li, Guojun Zhang, Hu Zhou, Xiaoyuan Huang, Ying Li
Journal:ACS Nano
IF:17.3
DOI:10.1021/acsnano.6c01232
PMID:
Published:2026-02-26
research field:微流控传染病检测即时检测生物医学工程CRISPR技术分子诊断
Abstract
Rapid, decentralized molecular diagnostics are urgently needed for effective infectious disease control. Here, we present “Wax-Sphere CRISPR” (WS-CRISPR), a paradigm-shifting platform for CRISPR-based diagnostics centered on a gravity-driven, interfacial phase-change self-encapsulation mechanism. This system fundamentally decouples bioreagent engineering from specific reaction vessels, transforming conventional, labor-intensive manual encapsulation into a standardized, physics-driven assembly process that generates discrete wax microspheres. Guided by fluid mechanics and interfacial thermodynamics, aqueous CRISPR droplets spontaneously traverse air/molten wax/ethanol to self-encapsulate and solidify, enabling standardized, high-throughput fabrication without manual wax handling. Upon temperature modulation, the wax phase change triggers sequential recombinase polymerase amplification (RPA) and CRISPR detection within a sealed, one-pot vessel. As a clinically oriented demonstration, WS-CRISPR enables multiplexed detection and risk stratification of all 14 high-risk HPV genotypes (HPV16/18 vs others) with a detection limit of 1 × 10–18 M in under 30 min. Integrated with widely accessible devices─including a thermocycler, hand-held fluorescence reader, and microfluidic platform─the system demonstrated 97.4% sensitivity and 100% specificity across 70 clinical samples. By solving the engineering bottlenecks of scalability and universality, WS-CRISPR offers a robust tool for decentralized, large-scale pathogen surveillance.
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