Health Tech
I design and build AI and backend systems that power the future of healthcare—from quantum blood cell classification and predictive cardiology to AR/VR memory tools and wearable nanotech. My projects span cardiology, oncology, neurology, and biomedical devices, all driven by one mission: creating technology that meaningfully improves patient outcomes.
My Work
CureBytes
AI-powered clinical workflows
Natural Language Processing (NLP) & Large Language Models (LLMs)
Named Entity Recognition (NER) & Clinical Data Structuring
My Work
Cardiosense
Developed CardioSense, a machine learning tool that predicts heart disease risk with balanced data, model comparisons, and clear clinical insights.
Scikit-learn, XGBoost, LightGBM. Metrics: precision, recall, F1 score, and ROC AUC
importance plots, ROC curves for clinical decision-making
My Work
Designed Variational Quantum Circuits (VQCs) and implemented equilibrium propagation within a quantum Ising model for blood cell classification
Quantum Blood Cell Classification
Quantum Machine Learning & Variational Quantum Circuits
Artificial Intelligence
Full-Stack
My Work
Elysian
Cutting-edge clothing with embedded nanotech sensors, turning skin health data into real-time answers and next-level care.
Rutgers Innovation Awards Nominee, Top 20% of Rutgers ScarletPitch
Wearable Tech & Embedded Systems
Biomedical Data Analytics
My Work
The Reverie Family Portal lets caregivers and loved ones upload meaningful media — like photos and videos — and tag them with relevant context. These memories are then rendered as interactive memory bubbles inside the HoloLens experience, creating immersive reminiscence therapy.
Cloud-Integrated Backend Development
AR/VR Data Streaming & Unity Integration
React/TypeScript
My Work
Biomedical Heart Stent
Designed a next-generation self-expanding nitinol stent to address limitations in modern cardiovascular stents, focusing on flexibility, biocompatibility, and reduced need for invasive surgeries. Built a full CAD prototype in Onshape, incorporating structural grooves to improve blood flow, reduce clotting risk, and adapt to natural heart tissue dynamics.
Computer-Aided Design (CAD)
Bioengineering & Materials Research
Engineering Design Process