A portable multifunctional biosensor based on a newly screened endogenous reference gene for pork adulteration detection

Abstract

The adulteration of animal-derived food is a widespread problem with meat adulteration emerging as a global concern. To address the need for on-site rapid detection and visual analysis, a portable multifunction biosensor (PMB) was developed. This device integrates Recombinase Polymerase Amplification (RPA), CRISPR/Cas12a assay, and a custom-designed 3D-printed multifunction device, specifically for the visual and rapid detection of pork in food. Initially, a screening model was constructed using Perl bioinformatics based on chromosomal gene information, and the LOC110262058 gene was selected as a reliable endogenous reference gene for pigs. Subsequently, a one-tube RPA-CRISPR/Cas12a system was established to simplify the procedures, converting pork-specific signals into fluorescence while preventing cross-contamination. In addition, an independently designed 3D-printed multifunction device was developed to support the RPA-CRISPR/Cas12a system for one-tube detection, incorporating functions such as heating, centrifugation, and imaging. The reaction conditions of the PMB were optimized to reduce the reaction time to 20–30 min with a sensitivity of 0.01 g/100 g. The analysis of actual samples indicated that the PMB has high selectivity and practical effectiveness for pork detection. The proposed biosensor offers several detection advantages, including output, ease of use, stability, and independence from complex equipment, making it a powerful method for rapid pork detection in food.