Interpretating SPR-Derived Reaction Kinetics via Self-Organizing Maps for Diagnostic Applications.

Abstract

Biosensors emerge as promising, cost-effective infectious disease diagnostics in resource-limited settings, requiring neither laboratory infrastructure nor specialized personnel. Surface plasmon resonance (SPR)-based biosensors remain preeminent for label-free, real-time analysis of biological interactions and kinetic parameter determination. Integrating Artificial Intelligence (AI), particularly self-organizing maps (SOMs), automates infection screening by projecting high-dimensional data onto topology-preserving 2D maps, offering advantages in diagnostic strategies by enabling efficient classification of infected vs healthy patients. This study presents an SPR biosensor with SOM analysis to enhance serodiagnosis of canine visceral leishmaniasis (CVL), a neglected tropical disease, whose delayed and inadequate detection in human and canine populations compromises effective disease control. The reaction kinetics of PQ20, a multiepitope chimeric protein with 20 B- and T-cell epitopes, with anti-PQ20 was evaluated. The proposed mechanism suggests two immunodominant epitopes of PQ20 through its reaction with polyclonal antibodies of, presenting high initial association rates (= 2.4 × 10L mols;= 5.5 × 10L mols). The biosensor's diagnostic performance was evaluated, achieving a 5.1 nmol Ldetection limit. SOM clustering indicated a higher specificity at shorter reaction times, supporting reduced diagnostic timelines (100 s) in accordance with kinetic evaluation. Finally, SOM-based data interpretation improved sensitivity and specificity compared to univariate analysis in raw serum, enhancing the assay's ability to classify samples in more complex media, in less than 15 min analysis time. Integrating multiepitope bioreceptors with AI-driven analysis offers rapid and label-free CVL surveillance, with broader applications for the management of this infectious disease.