Thesis defence: Mahbub Ul Alam

Thesis defence

Date: Thursday 28 March 2024

Time: 13.00 – 17.00

Location: Room Lilla hörsalen, DSV, Borgarfjordsgatan 12, Kista

Welcome to a thesis defence at DSV! Mahbub Ul Alam presents his thesis which explores how machine learning and the Internet of Medical Things can be used to create more effective healthcare. His studies involve COVID-19 and sepsis.

On March 28, 2024, Mahbub Ul Alam will present his PhD thesis at the Department of Computer and Systems Sciences (DSV), Stockholm University. The title of the thesis is “Advancing Clinical Decision Support Using Machine Learning & the Internet of Medical Things: Enhancing COVID-19 & Early Sepsis Detection”.

Mahbub Ul Alam and supervisor Rahim Rahmani at the "nailing" ceremony at DSV.
Mahbub Ul Alam and supervisor Rahim Rahmani at the "nailing" ceremony. Photo: Riyaj Isamiya Shaikh.

PhD student: Mahbub Ul Alam, DSV
Opponent: Sadok Ben Yahia, University of Southern Denmark
Main supervisor: Rahim Rahmani, DSV
Supervisor: Jaakko Hollmén, DSV

Download the PhD thesis from Diva

Contact Mahbub Ul Alam

The defence takes place at DSV in Kista, starting at 13:00 am.
Find your way to DSV

 

Abstract

This thesis presents a critical examination of the positive impact of Machine Learning (ML) and the Internet of Medical Things (IoMT) for advancing the Clinical Decision Support System (CDSS) in the context of COVID-19 and early sepsis detection.

It emphasizes the transition towards patient-centric healthcare systems, which necessitate personalized and participatory care—a transition that could be facilitated by these emerging fields. The thesis accentuates how IoMT could serve as a robust platform for data aggregation, analysis, and transmission, which could empower healthcare providers to deliver more effective care. The COVID-19 pandemic has particularly stressed the importance of such patient-centric systems for remote patient monitoring and disease management.

The integration of ML-driven CDSSs with IoMT is viewed as an extremely important step in healthcare systems that could offer real-time decision-making support and enhance patient health outcomes. The thesis investigates ML's capability to analyze complex medical datasets, identify patterns and correlations, and adapt to changing conditions, thereby enhancing its predictive capabilities. It specifically focuses on the development of IoMT-based CDSSs for COVID-19 and early sepsis detection, using advanced ML methods and medical data.

Key issues addressed cover data annotation scarcity, data sparsity, and data heterogeneity, along with the aspects of security, privacy, and accessibility. The thesis also intends to enhance the interpretability of ML prediction model-based CDSSs. Ethical considerations are prioritized to ensure adherence to the highest standards.

The thesis demonstrates the potential and efficacy of combining ML with IoMT to enhance CDSSs by emphasizing the importance of model interpretability, system compatibility, and the integration of multimodal medical data for an effective CDSS.

Overall, this thesis makes a significant contribution to the fields of ML and IoMT in healthcare, featuring their combined potential to enhance CDSSs, particularly in the areas of COVID-19 and early sepsis detection.

The thesis hopes to enhance understanding among medical stakeholders and acknowledges the need for continuous development in this sector.

 

Keywords

Internet of Medical Things, Patient-Centric Healthcare, Clinical Decision Support System, Predictive Modeling in Healthcare, Health Informatics, Healthcare analytics, COVID-19, Sepsis, COVID-19 Detection, Early Sepsis Detection, Lung Segmentation Detection, Medical Data Annotation Scarcity, Medical Data Sparsity, Medical Data Heterogeneity, Medical Data Security & Privacy, Practical Usability Enhancement, Low-End Device Adaptability, Medical Significance, Interpretability, Visualization, LIME, SHAP, Grad-CAM, LRP, Electronic Health Records, Thermal Image, Tabular Medical Data, Chest X-ray, Machine Learning, Deep Learning, Federated Learning, Semi-Supervised Machine Learning, Multi-Task Learning, Transfer Learning, Multi-Modality, Natural Language Processing, ClinicalBERT, GAN