I work at the intersection of technology and daily life, designing the next generation of health monitors. My focus is on creating wearable devices that are comfortable enough to forget you’re wearing them, and smart software that helps turn complex data from scans and sensors into clear, actionable information for patients and clinicians.
This selection of projects showcases my approach to research: asking how we can make essential healthcare tools more comfortable, accessible, and insightful. It’s about applying engineering principles to solve real-world problems faced in clinics and at home.
Co-authored a comprehensive review on AI-integrated wearable sensors in the post-COVID era, highlighting how smart wearables enable continuous, remote monitoring and data-driven clinical decision-making.
Explored hybrid sensor integration in wearable devices to enhance cardiovascular health monitoring, combining multiple sensing modalities for more robust detection and tracking of cardiac conditions.
Analyzed next-generation wearable ECG systems that combine soft, skin-conformal materials with AI algorithms to provide personalized, continuous cardiac monitoring and early risk detection.
Investigated electrospun nanofibers as flexible, high-sensitivity platforms for wearable cardiovascular health monitoring, supporting the design of comfortable, next-generation medical textiles.
Developed a semi-automated framework for standardized vertebral measurement in lumbar spine MRI, improving reproducibility and reliability for spinal diagnostics and follow-up studies.
Reviewed advances in PVDF-based materials and device architectures that enable self-powered wearables capable of simultaneous physiological sensing and energy harvesting from human motion.