Collaborative Internal Cavity Effect and Interfacial Modulation Mechanism for Boosting Deep Learning-Powered Immunochromatographic Pathogen Detection
Yuechun Li, Chunyan Ji, Zhaowen Cui, Longhua Shi, Yuanyuan Cheng, Liang Zhang, Wentao Zhang, Guangjun Huang, Jianlong Wang
Abstract
Nanoenabled immunochromatographic assay (ICA) emerges as a powerful tool for pathogen diagnosis, yet current nanotechnologies are still constrained by inadequate light-matter interaction efficiency, sluggish nanomaterial flow dynamics, and inefficient immunorecognition. Herein, we present a deep learning-enhanced immunoassay synergistically leveraging the internal cavity effect of hollow carbon nanospheres (h-CNSs) and interfacial antibody orientation modulation for the ultrasensitive detection of S. typhimurium . The h-CNSs exhibit significantly enhanced light absorption (molar extinction coefficients 5.4 × 10 11 vs. 3.7 × 10 11 L mol –1 cm –1 for counterpart) and photothermal conversion efficiency (66.78% vs. 43.37%) due to internal light reflection within the hollow cavity, while the reduced density (0.05 g mL –1 ) optimizes lateral flow kinetics. Further interfacial modification with 3,5-dicarboxybenzeneboronic acid enables directional antibody immobilization through boronate affinity, improving antibody binding affinity by 83-fold ( K a = 2.95 × 10 9 vs. 3.55 × 10 7 M –1 ). Integrated into an ICA, D-h-CNSs achieve visual detection limits of 500 CFU mL –1 (colorimetric) and 100 CFU mL –1 (photothermal), surpassing conventional ICA (10 4 CFU mL –1 ) and demonstrating high specificity, robust stability, and reliable performance in spiked milk and lettuce. By integration with a convolutional neural network (CNN), the developed nanoplatform achieves 100% accuracy for S. typhimurium detection with augmented training, providing a paradigm for amplifying biosensing signals through nanomaterial design and intelligent data analysis.