Spectroscopic Intravascular OCT for Quantitative Tissue Characterization in Coronary Arteries
Biomedical Optics Express, 17(3), 1245–1263
Research Engineer · Boston, MA
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Building at the intersection of [field 1], [field 2], and [field 3]. Replace this bio with a concise description of your research focus and institutional affiliation.
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>_ About
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My research focuses on developing next-generation optical imaging and sensing technologies. I work on inverse algorithms for spectroscopic tissue characterization, computational modeling of light-tissue interaction, and emerging photoacoustic methods in the near-infrared II window.
Your Research Area 1 Your Research Area 2 Your Research Area 3
>_ Recent Publications
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Real-Time Confocal Gate Optimization for Intravascular OCT Catheters Using Adaptive Optics
Conference on Lasers and Electro-Optics (CLEO), ATh4B.3
>_ Current Research
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Spectroscopic Intravascular OCT
spectroscopyExample Research Lab, Example University
MATLAB Python COMSOL Zemax SolidWorks
NIR-II Photoacoustic Imaging
photoacousticExample Research Lab, Example University
Python PyTorch COMSOL LabVIEW
>_ Recent Writing
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Inverse Methods for Spectroscopic OCT: A Practical Guide
February 15, 2026 Technical Note · 4 min read
An overview of inverse algorithm design for extracting tissue optical properties from spectroscopic OCT data, with emphasis on regularization strategies.
Building a Jones Matrix Polarization Simulator
January 20, 2026 Build Log · 6 min read
A walkthrough of designing a Jones matrix simulation framework for modeling polarization-sensitive OCT, from fiber components to round-trip catheter models.
Why Physicists Should Build Medical Instruments
November 8, 2025 Essay · 3 min read
The case for physics-trained researchers in biomedical optics — and why the best instruments come from people who understand the light, not just the disease.