AI-Augmented Biophysical Modeling In Thermoplasmonics For Real-Time Monitoring and Diagnosis of Human Tissue Infections
Document Type
Article
Publication Date
2-1-2025
School
Computing Sciences and Computer Engineering
Abstract
Identifying tissue infections from the body still poses an unprecedented challenge in society. Conventional diagnostic procedures are time-consuming and lack a real-time monitoring mode. This study proposes a system with an Artificial Intelligence (AI)-assisted Thermoplasmonics scheme that has a 57.7% shorter detection time than traditional techniques. The proposed system combines AI with Localised Surface Plasmon Resonance (LSPR) technology. Employing 2,333,481 single-cell transcriptomic profiles from 486 people (107 non-affected, 379 affected), an effective circuitry deep learning setup was designed and validated to analyse Thermoplasmonics sensor data in real-time. The system achieved an overall accuracy of 92.3% It achieved a 42.3% reduction in false positives and a 35.6% decrease in cost per healthcare diagnosis. It also achieved a classification accuracy of 1–94.5%, significantly higher than traditional culture methods' accuracies. The mean detection time was brought down to 42.3 min (SD = 12.8), and 99.7% of the time, all the analyses were done in less than 1 s. Clinical implementation in three major medical centres (n = 1655 cases) demonstrated significant improvements: a 31.3% decrease in the proportion of antibiotic cases misuse and a 23% decrease in hospital stays. Cost-benefit studies showed the system's feasibility in saving $2.8 million per hospital annually.
Publication Title
Journal of Thermal Biology
Volume
128
Recommended Citation
Naga Ramesh, J. V.,
Nimma, D.,
Ghodhbani, R.,
Jangir, P.,
Krishna Rao, T. R.,
Pavani, K.
(2025). AI-Augmented Biophysical Modeling In Thermoplasmonics For Real-Time Monitoring and Diagnosis of Human Tissue Infections. Journal of Thermal Biology, 128.
Available at: https://aquila.usm.edu/fac_pubs/21842
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