An Explainable Hybrid AI Framework for Enhanced Tuberculosis and Symptom Detection
- URL: http://arxiv.org/abs/2510.18819v1
- Date: Tue, 21 Oct 2025 17:18:55 GMT
- Title: An Explainable Hybrid AI Framework for Enhanced Tuberculosis and Symptom Detection
- Authors: Neel Patel, Alexander Wong, Ashkan Ebadi,
- Abstract summary: Tuberculosis remains a critical global health issue, particularly in resource-limited and remote areas.<n>We propose a framework which enhances disease and symptom detection on chest X-rays by integrating two supervised heads and a self-supervised head.<n>Our model achieves an accuracy of 98.85% for distinguishing between COVID-19, tuberculosis, and normal cases, and a macro-F1 score of 90.09% for multilabel symptom detection.
- Score: 55.35661671061754
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Tuberculosis remains a critical global health issue, particularly in resource-limited and remote areas. Early detection is vital for treatment, yet the lack of skilled radiologists underscores the need for artificial intelligence (AI)-driven screening tools. Developing reliable AI models is challenging due to the necessity for large, high-quality datasets, which are costly to obtain. To tackle this, we propose a teacher--student framework which enhances both disease and symptom detection on chest X-rays by integrating two supervised heads and a self-supervised head. Our model achieves an accuracy of 98.85% for distinguishing between COVID-19, tuberculosis, and normal cases, and a macro-F1 score of 90.09% for multilabel symptom detection, significantly outperforming baselines. The explainability assessments also show the model bases its predictions on relevant anatomical features, demonstrating promise for deployment in clinical screening and triage settings.
Related papers
- Efficient endometrial carcinoma screening via cross-modal synthesis and gradient distillation [15.277910275783187]
Early detection of myometrial invasion is critical for the staging and life-saving management of endometrial carcinoma (EC)<n>Here we present an automated, highly efficient two-stage deep learning framework that resolves both data and computational bottlenecks in EC screening.<n>Our model achieves a sensitivity of 99.5%, a specificity of 97.2%, and an area under the curve of 0.987 at a minimal computational cost.
arXiv Detail & Related papers (2026-02-23T13:22:25Z) - A Disease-Centric Vision-Language Foundation Model for Precision Oncology in Kidney Cancer [54.58205672910646]
RenalCLIP is a visual-language foundation model for characterization, diagnosis and prognosis of renal mass.<n>It achieved better performance and superior generalizability across 10 core tasks spanning the full clinical workflow of kidney cancer.
arXiv Detail & Related papers (2025-08-22T17:48:19Z) - An Explainable AI-Enhanced Machine Learning Approach for Cardiovascular Disease Detection and Risk Assessment [0.0]
Heart disease remains a major global health concern.<n>Traditional diagnostic methods fail to accurately identify and manage heart disease risks.<n>Machine learning has the potential to significantly enhance the accuracy, efficiency, and speed of heart disease diagnosis.
arXiv Detail & Related papers (2025-07-15T10:38:38Z) - RadFabric: Agentic AI System with Reasoning Capability for Radiology [61.25593938175618]
RadFabric is a multi agent, multimodal reasoning framework that unifies visual and textual analysis for comprehensive CXR interpretation.<n>System employs specialized CXR agents for pathology detection, an Anatomical Interpretation Agent to map visual findings to precise anatomical structures, and a Reasoning Agent powered by large multimodal reasoning models to synthesize visual, anatomical, and clinical data into transparent and evidence based diagnoses.
arXiv Detail & Related papers (2025-06-17T03:10:33Z) - Artificial Intelligence-Driven Prognostic Classification of COVID-19 Using Chest X-rays: A Deep Learning Approach [0.0]
This study presents a high-accuracy deep learning model for classifying COVID-19 severity (Mild, Moderate, and Severe) using Chest X-ray images.<n>Our model achieved an average accuracy of 97%, with specificity of 99%, sensitivity of 87%, and an F1-score of 93.11%.<n>These results demonstrate the model's potential for real-world clinical applications.
arXiv Detail & Related papers (2025-03-17T15:27:21Z) - DCAT: Dual Cross-Attention Fusion for Disease Classification in Radiological Images with Uncertainty Estimation [0.0]
This paper proposes a novel dual cross-attention fusion model for medical image analysis.<n>It addresses key challenges in feature integration and interpretability.<n>The proposed model achieved AUC of 99.75%, 100%, 99.93% and 98.69% and AUPR of 99.81%, 100%, 99.97%, and 96.36% on Covid-19, Tuberculosis, Pneumonia Chest X-ray images and Retinal OCT images respectively.
arXiv Detail & Related papers (2025-03-14T20:28:20Z) - Fast-staged CNN Model for Accurate pulmonary diseases and Lung cancer detection [0.0]
This research evaluates a deep learning model designed to detect lung cancer, specifically pulmonary nodules, along with eight other lung pathologies, using chest radiographs.<n>A two-stage classification system, utilizing ensemble methods and transfer learning, is employed to first triage images into Normal or Abnormal.<n>The model achieves notable results in classification, with a top-performing accuracy of 77%, a sensitivity of 0.713, a specificity of 0.776 during external validation, and an AUC score of 0.888.
arXiv Detail & Related papers (2024-12-16T11:47:07Z) - Empowering Tuberculosis Screening with Explainable Self-Supervised Deep Neural Networks [66.59360534642579]
Tuberculosis persists as a global health crisis, especially in resource-limited populations and remote regions.
In this work, we introduce an explainable self-supervised self-train learning network tailored for tuberculosis case screening.
The network achieves an outstanding overall accuracy of 98.14% and demonstrates high recall and precision rates of 95.72% and 99.44%, respectively.
arXiv Detail & Related papers (2024-06-19T18:10:06Z) - Reconstruction of Patient-Specific Confounders in AI-based Radiologic
Image Interpretation using Generative Pretraining [12.656718786788758]
We propose a self-conditioned diffusion model termed DiffChest and train it on a dataset of chest radiographs.
DiffChest explains classifications on a patient-specific level and visualizes the confounding factors that may mislead the model.
Our findings highlight the potential of pretraining based on diffusion models in medical image classification.
arXiv Detail & Related papers (2023-09-29T10:38:08Z) - Revisiting Computer-Aided Tuberculosis Diagnosis [56.80999479735375]
Tuberculosis (TB) is a major global health threat, causing millions of deaths annually.
Computer-aided tuberculosis diagnosis (CTD) using deep learning has shown promise, but progress is hindered by limited training data.
We establish a large-scale dataset, namely the Tuberculosis X-ray (TBX11K) dataset, which contains 11,200 chest X-ray (CXR) images with corresponding bounding box annotations for TB areas.
This dataset enables the training of sophisticated detectors for high-quality CTD.
arXiv Detail & Related papers (2023-07-06T08:27:48Z) - Many-to-One Distribution Learning and K-Nearest Neighbor Smoothing for
Thoracic Disease Identification [83.6017225363714]
deep learning has become the most powerful computer-aided diagnosis technology for improving disease identification performance.
For chest X-ray imaging, annotating large-scale data requires professional domain knowledge and is time-consuming.
In this paper, we propose many-to-one distribution learning (MODL) and K-nearest neighbor smoothing (KNNS) methods to improve a single model's disease identification performance.
arXiv Detail & Related papers (2021-02-26T02:29:30Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.