About

The ABOIL research group at NTU focuses on the development and exploration of non-invasive three-dimensional (3D) optical imaging techniques for biomedical applications. In recent years, we have also extended these technologies to industrial inspection, such as defect detection in (opto)electronic semiconductor chips, wafers, and packaging.

Our research team covers a wide range of topics, including optics and optomechanical design, development of high-performance imaging acquisition/processing engine, graphical user interface design, machine vision image pro cessing and feature enhancement , high-frequency signal analysis, image feature extraction based on machine lear ning or artificial intelligence, embedded processor development, and the development of heterogeneous computing architectures based on edge computing and AI modules

International collaborators:

1. Prof. Yoshiaki Yasuno, Computational Optics Group, University of Tsukuba, Japan.
2. Prof. Bernhard Baumann, Medical University of Innsbr uck/Medical University of Vienna (Adjunct), Austria.
3. Prof. Martin Villiger, Wellman Center for Photomedicine/Harvard Medical School, USA.
4. Prof. Gijs von Soest, Department of Cardiology, Erasmus Medical Center, Netherlands.
5. Dr. Karol Karnowski, Intern ational Centre for Translational Eye Research (ICTER), Polish Academy of Science, Poland

Industrial collaborators:

1. Dr. Cheng-Kuang Lee, NVIDIA AI Technology Center
2. Dr. Jyh-Tsung Hsieh, Bandwidth10 Ltd.

Principal Investigator

Autobiography:

Dr. Hsiang-Chieh Lee is currently an Associate Professor at the Graduate Institute of Photonics and Optoelectronics (GIPO) and the Department of Electrical Engineering at National Taiwan University (NTU). He received his Bachelor's and Master's degrees in Civil Engineering and Electro-Optical Engineering from NTU in 2004 and 2006, respectively. He then pursued a Ph.D. in Electrical Engineering at the Department of Electrical Engineering and Computer Science (EECS) at the Massachusetts Institute of Technology (MIT), focusing on the bioelectronics division, and obtained his doctorate in 2017. Dr. Lee joined NTU as an Assistant Professor in February 2017 and founded the Advanced Biomedical Optical Imaging Laboratory (ABOIL)at GIPO.

Dr. Lee is a member of the Phi Tau Phi Scholastic Honor Society of the Republic of China (R.O.C.) and a recipient of both the Young Scholar Fellowship Program and the Career Development Grant awarded by the Ministry of Science and Technology (MOST, now the National Science and Technology Council, NSTC) and the National Health Research Institutes (NHRI) in Taiwan, respectively. In 2023, he was also honored with the NSTC Ta-You Wu Memorial Award in recognition of his contributions to the field of optics and photonics.

Dr. Lee's current research interests include the development of optical coherence tomography (OCT) and functional OCT imaging technologies for a variety of biomedical applications, such as endoscopy, dentistry, dermatology, oncology, and ophthalmology. In collaboration with the laser industry, he is also working on the development of novel laser light sources for OCT and nondestructive inspection or testing applications. In addition, Dr. Lee has been developing machine learning and artificial intelligence (AI)-based image processing algorithms for biomedical and industrial nondestructive inspection. Recently, his group has focused on creating low-cost yet intelligent imaging instruments that leverage edge computing and heterogeneous computation frameworks.

Dr. Lee has delivered invited talks at various international conferences, including SPIE BISC and OPIC ALPS in Japan. He also serves as a member of the Technical Program Committee (TPC) for SPIE BISC, OPIC ALPS, and OPTICA/SPIE ECBO conferences.

Research

1. non-destructive inspection: line-fielded OCT. ▼

   Traditional time-domain and spectral-domain OCT systems commonly employ galvanometric scanners (Galvos) for point-by-point scanning. While effective, Galvos introduce mechanical complexity, sinusoidal waveform distortion, and motion jitter, all of which limit imaging speed and compromise system stability. To overcome these challenges, line-field OCT (LF-OCT) has emerged as a powerful alternative. LF-OCT utilizes line-shaped illumination in combination with an area-array detector to capture an entire B-scan image within a single camera exposure. This design eliminates the need for mechanical beam scanning across the sample surface during B-scan acquisition, significantly improving image acquisition speed and robustness against motion artifacts. As a result, LF-OCT is particularly well-suited for high-throughput or real-time non-destructive inspection applications.

2. multimodal system: OCT + high-power fs laser light source. ▼

   High-power femtosecond (fs) laser processing has become a powerful tool for material modification, enabling micromachining and functionalization at micro- to nanoscale precision. However, evaluating laser-induced effects within biological or industrial samples remains challenging—conventional inspection techniques are often destructive or lack sufficient resolution to capture subtle internal structural changes. To address this limitation, we aim to develop a multimodal system that integrates femtosecond laser ablation/machining with an optical coherence tomography (OCT) platform for real-time, non-invasive evaluation. This approach enables simultaneous processing and imaging, facilitating precise monitoring of laser–material interactions and structural evolution during fabrication or treatment.

1. Novel optical tomographic technologies for next-generation digital dentistry applications ▼

   Optical coherence tomography (OCT) enables high-resolution, non-invasive imaging of dental tissues; however, its clinical adoption is limited by imaging artifacts such as shadowing and refractive distortions. To address these challenges, we have developed a pipeline image-fusion algorithm that integrates refractive distortion correction with a multi-view registration framework, combining surface contour extraction and Iterative Closest Point (ICP)-based alignment. This approach effectively restores geometric accuracy, enhances visualization of internal tooth structures, and reduces misalignment artifacts. In parallel, we have developed a novel OCT imaging system capable of simultaneous image acquisition from three distinct viewing angles within a single scan, eliminating the need for mechanical sample repositioning.

2. multi-volume registration for enhanced marginal adaption. ▼

   Capturing subgingival finish lines remains a major challenge in digital dentistry, as intraoral scanners often lack sufficient accuracy, compromising the precision of restoration margins. While OCT provides high-resolution, non-invasive imaging, its performance can be degraded by scattering and refractive index variations. To overcome these limitations, we introduce a novel OCT-based method that combines refractive index compensation with an automated Fourier transform–based registration and stitching algorithm. This technique enables accurate alignment and fusion of multiple volumetric OCT datasets into complete 3D reconstructions of dental structures. As a result, it enhances the visualization of subgingival finish lines and offers a promising alternative to conventional intraoral scanners in clinical dentistry.

1. Ophthalmology OCT imaging with the MEMS-tunable HCG-VCSEL light source. ▼

   Swept-source OCT (SS-OCT), which employs a wavelength-swept light source, enables high-speed, non-invasive, 3D imaging of both the anterior and posterior segments of the human eye. However, the widespread adoption of SS-OCT remains limited by the high cost of the swept source, which significantly contributes to the overall system expense, thereby restricting accessibility in local clinics and under-resourced regions. To address this challenge, we investigate feasibility of HCG-VCSEL as a compact and cost-effective alternative light source for OCT imaging. In this study, we have developed multiple HCG-VCSEL-based SS-OCT systems operating at ~1060 nm to validate its comprehensive imaging capabilities, including retinal and full-eye imaging, long-range centimeter-scale imaging, and polarization-sensitive OCT (PS-OCT) for birefringent tissue characterization.

2. Axial biometry of the mouse eye. ▼

   Accurate ocular biometry is critical for investigating refractive errors and developmental eye conditions in both humans and animal models. Among these, mice have become particularly valuable due to the availability of genetically defined strains with well-characterized genomes. Despite their small eye size, murine eyes share key anatomical and structural features with human eyes, making them an excellent model for translational ocular research. In this study, we developed an accurate and stable protocol for in vivo measurement of axial length in mice, addressing challenges arising from their unpredictable visual fixation. By leveraging a high-speed, high-resolution, extended-depth OCT system, we achieved precise and repeatable axial length measurements from a single cross-sectional image.

1. FPGA OCT system framework ▼

   OCT provides non-invasive, high-resolution imaging of biological tissues and is widely used in ophthalmology and dermatology for early diagnosis and treatment monitoring. However, conventional OCT systems remain costly and bulky, limiting accessibility in resource-constrained settings. Although portable implementations leveraging single-board computers or GPU-based platforms have been explored, their limited processing power and resource competition between image reconstruction and AI workloads constrain clinical utility. To address these challenges, we have developed a compact spectral-domain OCT (SD-OCT) system that integrates FPGA-based real-time signal reconstruction with an NVIDIA Jetson platform dedicated to graphical user interface (GUI) control and AI-driven analytics. This heterogeneous architecture reduces both system cost and physical footprint, while enabling intelligent, portable OCT solutions suitable for broader deployment in point-of-care and telemedicine applications.

1. dynamic OCT imaging of the tumor spheroid. ▼

   Cancer remains one of the leading causes of death worldwide, underscoring the importance of accurately assessing treatment effectiveness. Tumor-cell spheroid models have emerged as a well-established tool for drug discovery and therapeutic screening, offering physiologically relevant insights into tumor microenvironments. However, traditional imaging techniques, such as bright-field and phase-contrast microscopy, are limited to 2D visualization of thin tissue sections or cell cultures and often require staining or fluorescent labeling. In this study, we developed a novel spectral-domain optical coherence microscopy (SD-OCM) system that incorporates custom-designed beam scanning protocols and dynamic imaging analysis algorithms. This dynamic OCM imaging approach enables label-free, three-dimensional visualization of the architectural and functional dynamics of tumor-cell spheroids, providing a powerful tool for non-invasive, longitudinal monitoring of cancer treatment response.

1. Automated classification of active and inactive myopic choroidal neovascularization (mCNV). ▼

   OCT and OCT angiography (OCTA) are indispensable retinal imaging modalities that provide detailed insights into both structural morphology and vascular networks, making them essential tools for the diagnosis and management of ophthalmic diseases. Despite their clinical value, conventional diagnostic approaches remain time-consuming and heavily reliant on expert interpretation, which introduces inter-observer variability and limits the scalability of large-scale screening programs. In this study, we propose an AI-based diagnostic framework that integrates complementary structural and vascular features extracted from OCT and OCTA to automatically classify myopic choroidal neovascularization (mCNV) into active and inactive stages. This approach not only enhances diagnostic accuracy but also demonstrates strong potential for clinical translation, paving the way for automated, objective, and scalable ophthalmic screening systems.

2. terminal defect inspection with edge computing. ▼

   In this study, we aim to develop a terminal defect inspection system optimized for industrial manufacturing environments. Two key design strategies are introduced: (1) A coarse-to-fine bounding box annotation method that reduces the cost of manual labeling and enables the training of object detection models even when only classification datasets are available; and (2) An API-based wireless edge computing framework, where inference is performed on a dedicated edge device, and results are transmitted via network communication. This architecture enables stable, low-latency inspection and embeds the deep learning model within a self-contained edge device, addressing practical challenges of deploying and maintaining intelligent inspection systems in real-world production line environments.

Publications

Patents

1. K. Liang, J. G. Fujimoto, H. Mashimo , O. O. Ahsen, H. C. Lee , M. G. Giacomelli , Z. Wang: Scanning optical probe. Massachusetts Institute of Technology, Dec. 2023: US 11 , 835 , 707 B2
2. H. - C. Lee , T. - H. Chen, T. - Y. Tsai, C. - B. Chueh, Y. - W. Chang, C. - Y., Wang : Signal control module and low coherence interferometry . National Taiwan University, Nov. 2022 : US 11,496,677 B2.
3. C. - H. Chiang , T. - Y . Li , M. - L . Tsai , Y . - J . Lee , H. - C. Lee : Method for synthesizing perovskite quantum dot film . National Taiwan University of Science and Technology, December 2021: US 11 , 193 , 060 B2
4. M. T. Tsai, H. C. Lee , C. K. Lee, Y. M. Wang, C. P. Chiang, H. M. Chen, C. C. Yang: Method for analyzing mucosa samples with optical coherence tomography . National Taiwan University, September 2011: US 8 , 023 , 119
5. 陳庭皓 、 李翔傑 、 王泰昂 , “ 低同調干涉儀成像系統 ( Low coherence interferometer imaging system ),” 中華民國專利第 I876830 號 , Mar. 2025
6. 李翔傑 、 陳庭皓 、 蔡廷彥 、 闕川博 、 張育瑋 、 王璟郁 , “ 訊號控制模組及低同調干涉儀 ( Signal control module and low coherence interferometry ),” 中華 民 國專利第 I752616 號 , Jan. 2022
7. 蔡孟燦 、 李翔傑 、 李正匡 、 王義閔 、 江俊斌 、 陳信銘 、 楊志忠 , “ 以光學同調斷層掃瞄分析黏膜 樣本的方法 ( Method for analyzing a mucosa sample with optical coherence tomography ),” 中 華 民 國專利第 I359007 號 , Mar. 2012

Book Chapters

1. M.-S. Wu, Y.-C. Wu, and H.-C. Lee, Optical Coherence Tomography (OCT): Clinical Applications of Endoscopic Catheter in Gynecology, Instrument Today, 224, pp. 21 - 27, 2020
2. A. D. Aguirre, C. Zhou, H.-C. Lee, O. O. Ahsen, and J. G. Fujimoto, Optical Coherence Microscopy, in Optical Coherence Tomography: Technology and Applications, 2nd Ed., J.G. Fujimoto and W. Drexler, Eds., Springer-Verlag, Berlin, Heidelberg, 2015.

1. Y. -C. Wu, H. -C. Lee, Y. -T. Ju, S. -C. Huang and C. -W. Chen, "Enabling Robotic Tele-Microsurgery: High-Resolution RGB-D Streaming Based on Swept Source OCT and Data-Driven Galvanometer Control," in IEEE/ASME Transactions on Mechatronics, early access (2025).
2. M. Varaka, C. W. Merkle, L. May, S. Worm, M. Augustin, F. Fanjul-Vélez, H.-C. Lee, A. Wöhrer, M. Glösmann, and B. Baumann, “Polarization-insensitive optical coherence tomography using pseudo-depolarized reference light for mitigating birefringence-related image artifacts,” Journal of Biomedical Optics, 11, 116001 (2024).
3. T.-A. Wang, N. H. Trung, H.-C. Lee, C.-K. Lee, M.-T. Tsai, and Y.-L. Wang, “Quantitative Evaluation of Caries and Calculus with Ultrahigh-Resolution Optical Coherence Tomography,” Bioengineering, 10, 1317 (2023).
4. B.-Y. Lee, C.-H. Cheng, C.-T. Tsai, H.-S. Lin, S.-C. Kao, P. Chiang, H.-C. Lee, T.-T. Shih, H.-C. Kuo, and G.-R. Lin, “Si Mach-Zehnder Modulator for PAM-4, QAM-OFDM, and DMT Transmission at C-Band,” IEEE Journal of Selected Topics in Quantum Electronics, 29, 350012 (2023).
5. Y.-W. Lo, A. Y.-L. Lee, Y.-C. Liu, H.-H. Ko, H.-H. Peng, H.-C. Lee, P.-Y. Pan, C.-H. Chiang, and S.-J. Cheng, “β-glucan therapy converts the inhibition of myeloid-derived suppressor cells in oral cancer patients,” Oral Diseases, 28, 1484 (2022).
6. Y. Luo, M. L. Tseng, S. Vyas, H. Y. Kuo, C. H. Chu, M. K. Chen, H.-C. Lee, W.-P. Chen, V. Su, X. Shi, H. Misawa, D. P. Tsai, and P.-C. Yang, “Metasurface based abrupt autofocusing beam for biomedical applications,” Small Methods, 6, 2101228 (2022).
7. C. Y. Ng, T.-A. Wang, H.-C. Lee, B.-H. Huang, and M.-T. Tsai, “In Vivo Identification of Skin Photodamage Induced by Fractional CO2 and Picosecond Nd:YAG Lasers with Optical Coherence Tomography,” Diagnostics,12, 822 (2022).
8. S.-E. Lin, D.-Y. Jheng, K.-Y. Hsu, Y.-R. Liu, W.-H. Huang, H.-C. Lee, and C.-C. Tsai, “Rapid pseudo-H&E imaging using a fluorescence-inbuilt optical coherence microscopic imaging system,” Biomed. Opt. Express, 12, 5139-5158 (2021).
9. B.-Y. Lee, C.-T. Tsai, H.-S. Lin, S.-C. Kao, C.-H. Cheng, P. Chiang, H.-C. Lee, and G.-R. Lin, “C-Band Silicon Waveguide Modulation with 50-Gbit/s NRZ-OOK over 10-km SMF and DSF,” IEEE J. Quantum Electronics, 57, 8400109 (2021).
10. T.-Y. Tsai, T.-H. Chen, H.-C. Chen, C.-B. Chueh, Y.-P. Huang, Y.-P. Hung, M.-T. Tsai, B. Bauman, C.-H. Wang, and H.-C. Lee*, “Quantitative spectroscopic comparison of the optical properties of mouse cochlea microstructures using optical coherence tomography at 1.06 µm and 1.3 µm wavelengths,” Biomed. Opt. Express, 12, 2339-2352 (2021). (*Corresponding author)
11. T.-H. Chen, Y.-C. Wu, T.-Y. Tsai, C.-B. Chueh, B.-H. Huang, Y.-P. Huang, M.-T. Tsai, Y. Yasuno, and H.-C. Lee*, “Effect of A-scan rate and interscan interval optical coherence angiography,” Biomed. Opt. Express, 12, 722-736 (2021). (*Corresponding author)
12. Y.-P. Huang, T.-Y. Tsai, T.-H. Chen, C.-B. Chueh, Y.-N. Tsai, Y.-W. Chang, Y.-C. Wu, H.-W. Chen, M.-T. Tsai, Y.-P. Hung, and H.-C. Lee*, “A generic framework for Fourier-domain optical coherence tomography imaging: software architecture and hardware implementations,” IEEE Access, 8, 191726-191736 (2020). (*Corresponding author)
13. C.-H. Chiang, T.-Y. Li, H.-S. Wu, K.-Y Li, C.-F. Hsu, L.-F. Tsai, P.-K. Yang, Y.-J. Lee, H.-C. Lee, C.-Y. Wang, M.-L. Tsai, “High stability inorganic perovskite quantum dot-cellulose nanocrystal hybrid films,” Nanotechnology, 31, 324002 (2020).
14. M.-T Tsai, W.-J. Chen, T.-Y. Tsai, H.-C. Lee*, C.-C. Wang, and Y.-J. Lee, “Optical coherence tomography/angiography-guided tumor ablation with a continuous-wave laser diode,” IEEE Access, 8, 43191-43199 (2020). (*Corresponding author)
15. H.-H Peng, H.-H. Kuo, N.-C. Chi, Y.-P. Wang, H.-C. Lee, P.-Y. Pan, M.Y.-P. Kuo and S.-J. Cheng, “Upregulated NPM1 is an independent biomarker to predict progression and prognosis of oral squamous cell carcinomas in Taiwan,” Head & Neck, 42, 5-13 (2020).
16. M.-T Tsai, Y.-L. Wang, T.-W. Yeh, H.-C. Lee, W.-J. Chen, J-L. Ke and Y.-J. Lee, “Early detection of enamel demineralization by optical coherence tomography,” Sci. Report, 9, 17154 (2019).
17. A. Abramson, E. Caffarel-Salvador, V. Soares, D. Minahan, R. Y. Tian, X. Lu, D. Dellal, Y. Gao, S. Kim, J. Wainer, J. Collins, S. Tamang, A. Hayward, T. Yoshitake, H.-C. Lee, J. Fujimoto, J. Fels, M.R. Frederiksen, U. Rahbek, N. Roxhed, R. Langer and G. Traverso, “A luminal unfolding microneedle injector for oral delivery of macromolecules,” Nature Medicine, 25, 1512–1518 (2019).
18. T.-A Wang, M.-C. Chan, H.-C. Lee, C.-Y. Lee and M.-T. Tsai, “Ultrahigh-resolution optical coherence tomography/angiography with an economic and compact supercontinuum laser,” Biomed. Opt. Express, 11, 5687-5702 (2019).
19. O.O. Ahsen, K. Liang, H.-C. Lee, M.G. Giacomelli, Z. Wang, B. Potsaid, M. Figueiredo, Q. Huang, V. Jayaraman, J.G. Fujimoto, and H. Mashimo, “Assesment of Barrett's esophagus and dysplasia with ultrahigh-speed volumetric en face and cross-sectional optical coherence tomography,” Endoscopy, 51, 355-39 (2019).
20. O.O. Ahsen, K. Liang, H.-C. Lee, M.G. Giacomelli, Z. Wang, J.G. Fujimoto, and H. Mashimo, “Assessment of chronic radiation proctopathy and radiofrequency ablation treatment follow-up with optical coherence tomography angiography: A pilot study,” World Journal of Gastroenterology, 25, 1997 (2019).
21. Z. Wang, H.-C. Lee, O.O. Ahsen, K. Liang, M. Figueiredo, Q. Huang, J.G. Fujimoto, and H. Mashimo, “Computer-Aided Analysis of Gland-Like Subsurface Hyposcattering Structures in Barrett's Esophagus using Optical Coherence Tomography,” Appl. Sci., 8, 2420 (2018).
22. W.-J Chen, Y.-Y. Chang, S.-C. Shen, Y.-L. Tzeng, H.-C. Lee, C.-H. Yang and M.-T. Tsai, “In vivo detection of UV-induced acute skin effects using optical coherence tomography,” Biomed. Opt. Express, 9, 4235-4245 (2018).
23. K. Liang, Z. Wang, O. O. Ahsen, H. C. Lee, B. Potsaid, V. Jayaraman, A. Cable, H. Mashimo, X. Li, and J. G. Fujimoto, “Cycloid scanning for wide field optical coherence tomography endomicroscopy and angiography in vivo,” Optica, 5, 36-43 (2018).
24. O. O. Ahsen, H.-C. Lee, K. Liang, Z. Wang, M. Figueiredo, Q. Huang, B. Potsaid, V. Jayaraman, J. G. Fujimoto, and H. Mashimo, “Ultrahigh-speed endoscopic optical coherence tomography and angiography enables delineation of lateral margins of endoscopic mucosal resection: a case report,” Therap. Adv. Gastroenterol., 10, 931-936 (2017).
25. K. Liang, O. O. Ahsen, Z. Wang, H. C. Lee, W. Liang, B. Potsaid, T.-H. Tsai, M. G. Giacomelli, V. Jayaraman, H. Mashimo, X. Li, and J. G. Fujimoto, “Endoscopic forward-viewing optical coherence tomography and angiography with MHz swept source,” Opt. Lett 42, 3193-3196 (2017).
26. H.-C. Lee, O. O. Ahsen, J. J. Liu, T.-H. Tsai, Q. Huang, H. Mashimo and J. G. Fujimoto, “Assessment of the radiofrequency ablation dynamics of esophageal tissue with optical coherence tomography,” J. Biomed Opt., 22, 076001 (2017).
27. H.-C. Lee, O. O. Ahsen, K. Liang, Z. Wang, M. Figueiredo, M. G. Giacomelli, B. Potsaid, Q. Huang, H. Mashimo, and J. G. Fujimoto, “Endoscopic optical coherence tomography angiography microvascular features associated with dysplasia in Barrett's esophagus (with video),” Gastrointest. Endosc., 86, 476-484 (2017).
28. S. Wan, H. C. Lee, X. Huang, T. Xu, T. Xu, X. Zeng, Z. Zhang, Y. Sheikine, J. L. Connolly, J. G. Fujimoto, and C. Zhou, “Integrated local binary pattern texture features for classification of breast tissue imaged by optical coherence microscopy”, Med. Image Anal., 38, 104-116 (2017).
29. Z. Wang, B. Potsaid, L. Chen, C. Doerr, H. C. Lee, T. Nielsen, V. Jayaraman, A. Cable, E. Swanson, and J. G. Fujimoto, “Cubic meter volume optical coherence tomography,” Optica, 3, 1496-1503 (2016).
30. K. Liang, O. O. Ahsen, H. C. Lee, Z. Wang, B. Potsaid, M. Figueiredo, V. Jayaraman, A. Cable, Q. Huang, H. Mashimo, and J. G. Fujimoto, “Volumetric Mapping of Barrett's Esophagus and Dysplasia With en face Optical Coherence Tomography Tethered Capsule,” Am. J. Gastroenterol, 111, 1664-1666 (2016).
31. H. C. Lee, O. O. Ahsen, K. Liang, Z. Wang, C. Cleveland, L. Booth, B. Potsaid, V. Jayaraman, A. E. Cable, H. Mashimo, R. Langer, G. Traverso, and J. G. Fujimoto, “Circumferential optical coherence tomography angiography imaging of the swine esophagus using a micromotor balloon catheter,” Biomed. Opt. Express, 7, 2927-2942 (2016).
32. Z. Wang*, H. C. Lee*, D. Vermeulen, L. Chen, T. Nielsen, S. Y. Park, A. Ghaemi, E. Swanson, and J. G. Fujimoto, “Silicon Photonic Integrated Circuit Swept-Source Optical Coherence Tomography Receiver with Dual Polarization, Dual Balanced, In-phase and Quadrature Detection,” Biomed. Opt. Express 6, 2562-2574 (2015). (*equal contribution)
33. K. Liang, G. Traverso, H. C. Lee, O. O. Ahsen, Z. Wang, B. Potsaid, M. G. Giacomelli, V. Jayaraman, R. Barman, A. Cable, H. Mashimo, R. Langer, and J. G. Fujimoto, “Ultrahigh speed en face OCT capsule for endoscopic imaging,” Biomed. Opt. Express 6, 1146-1163 (2015).
34. O. O. Ahsen, H. C. Lee, M. G. Giacomelli, Z. Wang, K. Liang, T. H. Tsai, B. Potsaid, H. Mashimo, J. G. Fujimoto, “Correction of rotation distortion for catheter-based en face OCT and OCT angiography,” Opt. Lett 39, 5973-5976 (2014).
35. T. H. Tsai, H. C. Lee, O. O. Ahsen, K. Liang, M. G. Giacomelli, B. Potsaid, Y. K. Tao, V. Jayaraman, M. Figueiredo, Q. Huang, H. Mashimo, A. Cable, and J. G. Fujimoto, “Ultrahigh speed endoscopic optical coherence tomography for gastroenterology,” Biomed. Opt. Express 5, 4387-4404 (2014).
36. T. H. Tsai, O. O. Ahsen, H. C. Lee, K. Liang, M. Figueiredo, Y. K. Tao, M. G. Giacomelli, B. Potsaid, V. Jayaraman, Q. Huang, A. Cable, J. G. Fujimoto, and H. Mashimo, “Endoscopic Optical Coherence Angiography Enables Three Dimensional Visualization of Subsurface Microvasculature,” Gastroenterology, 147, 1219-1221 (2014).
37. Z. Wang, H. C. Lee, O. O. Ahsen, B. Lee, W. Choi, B. Potsaid, J. J. Liu, V. Jayaraman, A. Cable, M. F. Kraus, K. Liang, J. Hornegger, and J. G. Fujimoto, “Depth-encoded all fiber swept source polarization sensitive OCT,” Biomed. Opt. Express 5, 2931-2949 (2014).
38. N. Zhang, T. H. Tsai, O. O. Ahsen, K. Liang, H. C. Lee, P. Xue, X. Li, and J. G. Fujimoto, "Compact piezoelectric transducer fiber scanning probe for optical coherence tomography," Opt. Lett 39, 186-188 (2014).
39. H.-C. Lee, J. J. Liu, Y. Sheikine, A. D. Aguirre, J. L. Connolly, and J. G. Fujimoto, "Ultrahigh-speed spectral domain optical coherence microscopy," Biomed. Opt. Express 4, 1236-1254 (2013).
40. C. Zhou, T. H. Tsai, H. C. Lee, T. Kirtane, M. Figueiredo, Y. K. Tao, O. O. Ahsen, D. C. Adler, J. M. Schmitt, Q. Huang, J. G. Fujimoto, and H. Mashimo, "Characterization of buried glands before and after radiofrequency ablation by using 3-dimensional optical coherence tomography (with videos)," Gastrointest Endosc 76, 32-40 (2012).
41. C. Zhou, T. Kirtane, T. H. Tsai, H. C. Lee, D. C. Adler, J. M. Schmitt, Q. Huang, J. G. Fujimoto, and H. Mashimo, "Cervical inlet patch-optical coherence tomography imaging and clinical significance," World J Gastroenterol 18, 2502-2510 (2012).
42. C. Zhou, T. Kirtane, T. H. Tsai, H. C. Lee, D. C. Adler, J. Schmitt, Q. Huang, J. G. Fujimoto, and H. Mashimo, "Three-dimensional endoscopic optical coherence tomography imaging of cervical inlet patch," Gastrointest Endosc 75, 675-677 (2012).
43. T. H. Tsai, C. Zhou, Y. K. Tao, H. C. Lee, O. O. Ahsen, M. Figueiredo, T. Kirtane, D. C. Adler, J. M. Schmitt, Q. Huang, J. G. Fujimoto, and H. Mashimo, "Structural markers observed with endoscopic 3-dimensional optical coherence tomography correlating with Barrett's esophagus radiofrequency ablation treatment response (with videos)," Gastrointest Endosc 76, 1104-1112 (2012).
44. T. H. Tsai, C. Zhou, H. C. Lee, Y. K. Tao, O. O. Ahsen, M. Figueiredo, D. C. Adler, J. M. Schmitt, Q. Huang, J. G. Fujimoto, and H. Mashimo, "Comparison of Tissue Architectural Changes between Radiofrequency Ablation and Cryospray Ablation in Barrett's Esophagus Using Endoscopic Three-Dimensional Optical Coherence Tomography," Gastroenterol Res Pract, 684832 (2012).
45. H. C. Lee, C. Zhou, D. W. Cohen, A. E. Mondelblatt, Y. Wang, A. D. Aguirre, D. Shen, Y. Sheikine, J. G. Fujimoto, and J. L. Connolly, "Integrated optical coherence tomography and optical coherence microscopy imaging of ex vivo human renal tissues," J Urol 187, 691-699 (2012).
46. A. Li, C. Zhou, J. Moore, P. Zhang, T.-H. Tsai, H.-C. Lee, D.M. Romano, M.L. McKee, D.A. Schoenfeld, M.J. Serra, K. Raygor, H.F. Cantiello, J.G. Fujimoto, and R.E. Tanzi, “Changes in the Expression of the Alzheimer’s Disease-Associated Presenilin Gene in Drosophila Heart Leads to Cardiac Dysfunction,” Curr. Alzheimer Res., 8, 313-322 (2011).
47. C. Zhou, D.W. Cohen, Y. Wang, H.-C. Lee, A.E. Mondelblatt, T.-H. Tsai, A.D. Aguirre, J.G. Fujimoto, and J.L. Connolly, “Integrated optical coherence tomography and microscopy for ex vivo multiscale evaluation of human breast tissues,” Cancer Res. 70, 10071-10079 (2010).
48. C. Zhou, T.-H. Tsai, D.C. Adler, H.-C. Lee, D. Cohen, A. Mondelblatt, Y. Wang, J.L. Connolly, and J.G. Fujimoto, “Photothermal optical coherence tomography in ex vivo human breast tissue using gold nanoshells,” Opt. Lett 35, 700-702 (2010).
49. D.C. Adler, C. Zhou, T.-H. Tsai, H.-C. Lee, L. Becker, J.M. Schmitt, Q. Huang, J.G. Fujimoto, and H. Mashimo, “Three-dimensional optical coherence tomography of Barrett’s esophagus and buried glands beneath neosquamous epithelium following radiofrequency ablation,” Endoscopy 41, 773-776 (2009).
50. C.-K. Lee, M.-T. Tsai, H.-C. Lee, H.-M. Chen, C.-P. Chiang, Y.-M. Wang, and C. C. Yang, “Diagnosis of oral submucous fibrosis with optical coherence tomography,” J. Biomedical Optics 14, 054008 (2009).
51. M.-T. Tsai, C.-K. Lee, H.-C. Lee, H.-M. Chen, C.-P. Chiang, Y.-M. Wang, and C. C. Yang, “Differentiating oral lesions in different carcinogenesis stages with optical coherence tomography,” J. Biomedical Optics 14, 044028 (2009).
52. M.-T. Tsai, H.-C. Lee, C.-K. Lee, C.-H. Yu, H.-M. Chen, C.-P. Chiang, C.-C. Chang, Y.-M. Wang, and C. C. Yang, "Effective indicators for diagnosis of oral cancer using optical coherence tomography," Opt. Express 16, 15847-15862 (2008).
53. M.-T. Tsai, H.-C. Lee, C.-W. Lu, Y.-M. Wang, C.-K. Lee, C. C. Yang, and C.-P. Chiang, “Delineation with an Oral Cancer Lesion with Swept-source Optical Coherence Tomography,” J. Biomedical Optics 13, 044012 (2008).
54. C.-K. Lee, C.-W. Sun, P.-L. Lee, H.-C. Lee, C. C. Yang, C.-P. Jiang, Y.-P. Tong, T.-C. Yeh, and J.-C. Hsieh, “Study of photon migration with various source-detector separations in near-infrared spectroscopic brain imaging based on three-dimensional Monte Carlo modeling,” Optics Express 13, 8339-8348 (2005).

Refereed Conference Presentations

1. Y.-S. Cheng, P.-C. Sung, Z.-W. Kao, F.-Y. Hua, T.-H. Chen, C.-B. Chueh, Y.-L. Wang, and H.-C. Lee*, “Development of multi-view optical coherence tomography (OCT) with a registration algorithm combining refractive index correction for tooth imaging,” European Conferences on Biomedical Optics (ECBO), M1C.5, Munich, German, June, 2025.
2. C.-H. Peng, K.-L. Huang, J.-Z. Wang, H.-H. Chung, J.-T. Hsieh, and H.-C. Lee*, “High-speed, long-range SS-OCT imaging based on HCG-VCSEL and real-time calibration framework,” European Conferences on Biomedical Optics (ECBO), W5D.3, Munich, German, June, 2025.
3. Y.-S. Cheng, P.-C. Sung, Z.-W. Kao, F.-Y. Hua, T.-H. Chen, C.-B. Chueh, Y.-L. Wang, and H.-C. Lee*, “Development of refractive index correction based image registration with multi-view optical coherence tomography (OCT) for tooth imaging,” Advanced Lasers and Photon Sources Conference (ALPS), OPIC, ALPS-H2-05, Yokohama, Japan, Apr. 2025.
4. C.-H. Peng, J.-Z. Wang, K.-L. Huang, H.-H. Chung, J.-T. Hsieh, and H.-C. Lee*, “Long-range swept-source OCT imaging with real-time calibration using HCG-VCSEL laser,” Advanced Lasers and Photon Sources Conference (ALPS), OPIC, ALPS-H2-04, Yokohama, Japan, Apr. 2025.
5. H.-C. Lee*, “Long-range imaging using swept-source OCT based on HCG-VCSEL,” Advanced Lasers and Photon Sources Conference (ALPS), OPIC, ALPS4-01 (Invited), Yokohama, Japan, April, 2024.
6. P.-C. Sung, Z.-W. Kao, F.-Y. Hua, T.-H. Chen, H.-Y. Li, C.-B. Chueh, Y.-L. Wang, and H.-C. Lee*, “Development of a multi-view OCT system based depth-encoded multiplexing,” Advanced Lasers and Photon Sources Conference (ALPS), OPIC, ALPS4-02, Yokohama, Japan, April, 2024.
7. Z.-W. Kao, P.-C. Sung, F.-Y. Hua, C.-B. Chueh, H.-Y. Li, T.-H. Chen, Y.-L. Wang, and H.-C. Lee*, “Development of Multi-view Optical Coherence Tomography (OCT)and Image Registration Algorithm for Tooth Imaging,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC7-01, Yokohama, Japan, April, 2024.
8. C.-H. Peng, J.-Z. Wang, K.-L. Huang, T.-H. Chen, J.-T. Hsieh, and H.-C. Lee*, “Full-eye imaging using swept-source OCT based on HCG-VCSEL,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC7-02, Yokohama, Japan, April, 2024.
9. P.-C. Huang, Y.-N. Tsai, Y.-S. Cheng, Y.-C. Lin, Y. Yasuno, and H.-C. Lee*, “Dynamic imaging of the lung carcinoma (CA) cell spheroid with optical coherence microscopy (OCM) technology,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC7-03, Yokohama, Japan, April, 2024.
10. C.-B. Chueh, Z.-C. Liu, T.-H. Chen, Y.-Y. Li, M.-C, Tu, S.-J. Cheng, C.-K. Lee, S. See, and H.-C. Lee*, “Using generative adversarial network and multi-scale optical coherence tomography to reconstruct high-resolution volumetric images,” Photonics Europe, 13011-26, Strasbourg, France, April, 2024.
11. M.-S. Wu, C.-B. Chueh, T.-A. Wang, T.-H. Chen, T.-Y. Tsai, B. E. Bouma, M. Villiger, and H.-C. Lee*, “Multifunctional catheter-based optical coherence tomography system for oral cavity and endocervical canal imaging (Invited Paper),” European Conferences on Biomedical Optics (ECBO), 12632-7, Munich, German, June, 2023.
12. T.-H. Chang, F.-Y. Hua, H.-Y. Li, Y.-L. Wang, Y.-R. Chou, and H.-C. Lee*, “Using a multi-angle optical coherence tomography (OCT) system for the suppression of artifacts in the dental OCT images,” European Conferences on Biomedical Optics (ECBO), 12632-20, Munich, German, June, 2023.
13. C.-B. Chueh, T.-H. Chen, Y.-Y. Li, M.-C. Tu, S.-J. Cheng, C.-K. Lee, S. See, H.-C. Lee*, “Synthetic high-resolution, volumetric and wide field-of-view optical coherence tomography images with generative adversarial networks,” European Conferences on Biomedical Optics (ECBO), 12632-65, Munich, German, June, 2023.
14. Y.-C. Wu, H.-F. Chen, T.-H. Chen, T.-Y. Tsai, C.-B. Chueh, J.-C. Tsai, and H.-C. Lee*, “Comparison of scanning stability analysis with the dual-axis MEMS scanner based on switchable driving mode in optical coherence tomography imaging technology,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC2-02, Yokohama, Japan, April, 2023.
15. C.-H. Peng, Y.-C. Mei, H.-K. Chen, T.-Y. Tsai, T.-H. Chen, C.-B. Chueh, D. Ellafi, C. Chase, H.-C. Kuo, M. C. Y. Huang, and H.-C. Lee*, “Polarization-sensitive imaging using optical coherence tomography and a HCG-VCSEL laser,” OPTO, Photonics West, 12439-22, San Francisco, USA, Feb, 2023.
16. T.-H. Chen, Y.-H. Lee, C. Y. Ng, M.-T. Tsai, C.-K. Lee, and H.-C. Lee*, “Development of an automatic algorithm enabling layer segmentation and optical characteristic analysis in skin optical coherence tomography imaging”, BiOS, Photonics West, 12352-14, San Francisco, USA, Jan, 2023.
17. T.-Y. Tsai, T.-H. Chen, H.-K. Chen, C.-B. Chueh, D. Ellafi, C. Chase, H.-C. Kuo, M.-T. Tsai, M. C. Y. Huang, and H.-C. Lee*, “High-speed optical coherence tomography imaging with a tunable HCG-VCSEL light source at the 1060 nm wavelength window,” OPTO, Photonics West, 12020-18, San Francisco, USA, Jan, 2022.
18. T.-H. Chen, Y.-C. Wu, C.-C. Li, M.-A. Chen, T.-Y. Tsai, C.-B. Chueh, M.-T. Tsai, Y. Yasuno, M.-K. Pan, and H.-C. Lee*, “Identification of Changes in the Microvasculature in Mouse Brain Among Different Physiological States Using Optical Coherence Tomography Angiography,” European Conferences on Biomedical Optics (ECBO), OSA, Virtual Meeting, June, 2021.
19. H.-C. Lee*, T.-H. Chen, Y.-C. Wu, C.-C. Li, Y.-W. Chang, M.-A. Chen, T.-Y. Tsai, C.-B. Chueh, M.-T. Tsai, Y. Yasuno, and M.-K. Pan, “A pilot study of developing a small footprint imaging platform with optical coherence tomography (OCT) and OCT angiography for mouse brain imaging in vivo,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC Satellite in Taiwan-06, April, 2021.
20. T.-Y. Tsai, C.-B. Chueh, T.-H. Chen, M.-S. Wu, M.-T. Tsai, and H.-C. Lee*, “High-speed and wide-field endoscopic optical coherence tomography imaging of the oral mucosa with a micromotor imaging catheter and polarization diversity detection,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-P-08, Yokohama, Japan (virtual meeting in parallel), April, 2021.
21. Y.-L. Chen, T.-H. Chen, T.-Y. Tsai, C.-B. Chueh, Y.-C. Wu, M.-T. Tsai, C.-K. Lee, and H.-C. Lee*, “Graphics processing unit (GPU) accelerated microvascular imaging framework with optical coherence tomography (OCT) and OCT angiography techniques,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-P-09, Yokohama, Japan (virtual meeting in parallel), April, 2021.
22. Z.-J. Wu, T.-Y. Tsai, M.-S. Wu, C.-W. Chen, and H.-C. Lee*, “Development of a miniature imaging head combing wide-angle camera and optical coherence tomography for the semiautonomous laparoscope surgery procedure,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-P-15, Yokohama, Japan (virtual meeting in parallel), April, 2021.
23. H.-C. Lee*, “Real-time functional optical coherence tomography (即時多功能性光學同調斷層掃描術),” NVidia GPU Technology Conference (GTC), A21483, Oct. 2020.
24. T.-C. Chang, T.-H. Chen, T.-Y. Tsai, C.-B. Chueh, Y.-P. Huang, M.-T. Tsai, C.-K. Lee, and H.-C. Lee*, “Real time functional optical coherence tomography imaging,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-7-01(invited), Yokohama, Japan, April, 2020.
25. M.-S. Wu, Y.-C. Wu, C.-Y. Wang, T.-Y. Tsai, T.-H. Chen, Y.-N. Tsai, M.-T. Tsai, C.-C. Wang and H.-C. Lee*, “Development of a catheter-based optical coherence tomography system for the early detection of cervical precancerous lesions,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-2-03, Yokohama, Japan, April, 2020.
26. C.-Y. Wang, C.-B. Chueh, T.-Y. Tsai, J.-C. Lee, T.-C. Chang, T.-H. Chen, Y.-P. Hung, M.-K. Pang and H.-C. Lee*, “Investigation of tissue architectures with a long-wavelength and multiscale optical coherence tomography imaging system,” Biomedical Imaging and Sensing Conference (BISC), BISC-2-04, Yokohama, Japan, April, 2020.
27. Y.-C. Wu, T.-H. Chen, T.-Y. Tsai, T.-C. Chang, C.-B. Chueh, C.-Y. Wang, Y.-P. Huang, M.-T. Tsai, and H.-C. Lee*, “Comparison of vascular image quality with different sweep rate laser light source based on variable interscan time analysis in optical coherence tomography angiography skin imaging,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-7-04, Yokohama, Japan, April, 2020.
28. T.-Y. Tsai, T.-H. Chen, H.-C. Chen, H. Wang, Y.-P. Huang, T.-C. Chang, Y.-W Chang, Y.-P. Hung, M.-T. Tsai, C.-H. Wang, and H.-C. Lee*, “Quantitative spectroscopic comparison of the optical properties of the mouse cochlear microstructures using optical coherence tomography at 1.3 µm and 1 µm wavelength regimes,” BiOS, Photoniscs West, 11213-5, San Francisco, USA, Feb, 2020.
29. C.-B. Chueh, C.-Y. Wang, T.-Y. Tsai, Y.-P. Huang, T.-C. Chang, T.-H. Chen, Y.-N. Tsai, Y.-P. Hung and H.-C. Lee*, “Multiscale imaging of the ex vivo oral precancerous lesions with a custom developed swept-source optical coherence tomography/microscopy platform and a 1.7 μm wavelength-swept laser,” BiOS, Photonics West, 11217-12, San Francisco, USA, Feb, 2020.
30. T.-H. Chen, T.-Y. Tsai, Y.-P. Huang, C.-B. Chueh, M.-S. Wu, Y.-C Wu, Y.-P. Hung, M.-T. Tsai and H.-C. Lee*, “Quantitative analysis of the microvasculature flow speed using optical coherence tomography angiography technique and variable interscan time algorithm,” BiOS, Photonics West, 11251-88, San Francisco, USA, Feb, 2020.
31. Y.-N. Tsai, Y.-W. Chang, C.-C. Ni, T.-H. Chen, T.-Y. Tsai, Y.-P. Huang, C.-C. Yang and H.-C. Lee*, “Development of a time lapse tumor cell spheroid imaging system with a high-resolution spectral-domain optical coherence microscopy system,” BiOS, Photonics West, 11243-13, San Francisco, USA, Feb, 2020.
32. H.-C. Lee*, “Recent advances in the development and applications of endoscopic optical coherence tomography,” The 4th International Conference on Biophotonics, T4.1, Taipei, Taiwan, Sep. 2019.
33. Y.-P. Huang, T.-Y. Tsai, T.-H. Chen, C.-B. Chueh, Y.-P. Hung and H.-C. Lee*, “The single software architecture supporting Fourier domain optical coherence tomography system,” The 4th International Conference on Biophotonics, T4.2, Taipei, Taiwan, Sep. 2019.
34. T.-H. Chen, T.-Y. Tsai, H.-C. Chen, C.-B. Chueh, B.-H. Huang, Y.-N. Tsai, M.-T. Tsai, C.-H. Wang and H.-C. Lee*, “Swept-Source Optical Coherence Tomography Imaging of the Guinea Pig Cochlea,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-2-03, Yokohama, Japan, April, 2019.
35. C.-B. Chueh, T.-Y. Tsai, Y.-P. Huang, T.-H. Chen, Y.-N. Tsai, C.-Y. Wang, T.-C. Chang, Y.-P. Hung and H.-C. Lee*, “Development of a Long-Wavelength Swept-Source Optical Coherence Tomography System for High-Content Ex Vivo Tissue Imaging,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-P-04, Yokohama, Japan, April, 2019.
36. T.-Y. Tsai, Y.-P. Huang, T.-H. Chen, C.-B. Chueh, H.-Y. Peng, M.-S. Wu, Y.-C. Wu, Y.-P. Hung, M.-T. Tsai and H.-C. Lee*, “Differentiation of the microvasculature with different blood flow speed based on variable interscan time analysis in OCT angiography skin imaging,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-P-17, Yokohama, Japan, April, 2019.
37. M.-T. Tsai, Y.-L. Wang, C.-Y. Ke, H.-C. Lee, and Y.-J. Lee, “Early diagnosis of teeth caries with non-invasive optical coherence tomography,” Biomedical Imaging and Sensing Conference (BISC), SPIE, BISC-P-25, Yokohama, Japan, April, 2019.
38. Y.-N. Tsai, Y.-P. Huang, T.-H. Chen, C.-B. Chueh, T.-Y. Tsai, C.-C. Hsieh, X.-Y. Luo, Y.-P. Hung, C.-C. Yang and H.-C. Lee*, “Investigation of the architectural changes of the tumor cell spheroid with the interaction of gold nanoparticles using a high-resolution inverted optical coherence microscopy system,” BiOS, Photonics West, 10876-41, San Francisco, USA, Feb, 2019.
39. H.-C. Lee*, K. Liang, O.O. Ahsen, Z. Wang, M. Figueiredo, B.M. Potsaid, V. Jayaraman, Q. Huang, H. Mashimo, J.G. Fujimoto, “(Invited) Endoscopic optical coherence tomography and angiography for gastroenterology applications,” Biomedical Imaging and Sensing Conference (BISC), SPIE, 10711-6, Yokohama, Japan, April, 2018.
40. H.-C. Lee, and M.-T. Tsai, “Texture analysis of optical coherence tomography images obtained during tumor development,” OSJ-OSA-OSK Joint Symposia on Optics (Optics and Photonics Japan 2018), 31Ppj2, Tokyo, Japan, November, 2018.
41. H.-C. Lee, O. Fass, O.O. Ahsen, K. Liang, Z. Wang, M. Figueiredo, B. Potsaid, V. Jayaraman, Q. Huang, J.G. Fujimoto, H. Mashimo, "Endoscopic Optical Coherence Tomography Microangiography Identifies the Altered Microvasculature of the Terminal Ileum in Crohn’s Disease," Digestive Disease Week, Chicago, IL, USA, May, 2017.
42. H.-C. Lee, O.O. Ahsen, K. Liang, Z. Wang, M. Figueiredo, B. Potsaid, V. Jayaraman, Q. Huang, H. Mashimo, J.G. Fujimoto, "Novel Ultrahigh Speed Endoscopic OCT Angiography Identifies Both Architectural and Microvascular Changes in Patients With Gastric Antral Vascular Ectasia (GAVE) Undergoing Radiofrequency Ablation (RFA) Treatment," Digestive Disease Week, San Diego, CA, USA, May, 2016.
43. H.-C. Lee, O.O. Ahsen, K. Liang, Z. Wang, M.G. Giacomelli, M. Figueiredo, Q. Huang, B. Potsaid, V. Jayaraman, H. Mashimo, J.G. Fujimoto, "Ultrahigh Speed Endoscopic Optical Coherence Tomography Angiography for Visualization of Subsurface Vasculature in Barrett's Esophagus and Dysplasia," Digestive Disease Week, Washington, D.C., USA, May, 2015.
44. H.-C. Lee, K. Liang, O.O. Ahsen, M.G. Giacomelli, Z. Wang, M. Figueiredo, Q. Wang, B. Potsaid, V. Jayaraman, J.G. Fujimoto, H. Mashimo, "Ultrahigh Speed Endoscopic Optical Coherence Tomography and Angiography for Investigating Terminal Ileum With Chronic Inflammation," Digestive Disease Week, Washington, D.C., USA, May, 2015.
45. H.-C. Lee, O. O. Ahsen, K. Liang, M. G. Giacomelli, Z. Wang, B. Potsaid, V. Jayaraman, M. Figueiredo, Q. Huang, A. E. Cable, H. Mashimo, and J. G. Fujimoto, “Ultrahigh speed endoscopic structural and angiographic OCT imaging,” BiOS, Photonics West, San Francisco, USA, Feb, 2015.
46. H.-C. Lee, O. O. Ahsen, T.-H. Tsai, M. G. Giacomelli, Z. Wang, K. Liang, M. Figueiredo, Q. Huang, B. Potsaid, J. G. Fujimoto, and H. Mashimo, “Novel Ultrahigh Speed Optical Coherence Tomography and Micromotor Imaging Probe for Investigating Microvasculature in the Gastrointestinal Tract,” Digestive Disease Week, Chicago, USA, May, 2014.
47. H.-C. Lee, J. J. Liu, T.-H. Tsai, B. Potsaid, M. Kraus, M. Giacomelli, Y. K. Tao, J. G. Fujimoto, and H. Mashimo, “Imaging the Dynamics of Radiofrequency Ablation using Ultrahigh-Speed Three-Dimensional Optical Coherence Tomography,” Digestive Disease Week, Orlando, USA, May, 2013.
48. H.-C. Lee, C. Zhou, T.-H. Tsai, T. Kirtane, Y. K. Tao, O. O. Ahsen, D. C. Adler, J. M. Schmitt, Q. Huang, J. G. Fujimoto, and H. Mashimo, “Three-dimensional Optical Coherence Tomography on Endoscopic Mucosal Resection Specimens Confirms Identification of Malignant from Metaplastic Lesions in Patients with Barrett’s Esophagus,” Digestive Disease Week, Chicago, USA, May, 2011.
49. H.-C. Lee, C. Zhou, Y. Wang, A. D. Aquirre, T.-H. Tsai, D. W. Cohen, J. L. Connolly, and J. G. Fujimoto, “Integrated Optical Coherence Tomography and Optical Coherence Microscopy Imaging of Human Pathology,” BiOS, Photonics West, San Francisco, USA, Jan. 2010.
50. H.-C. Lee, M.-T. Tsai, C.-K. Lee, C.-H. Yu, H.-M. Chen, C.-P. Chiang, Y.-M. Wang, and C. C. Yang, “Tracking the Regression of Oral Cancer after Photodynamic Therapy with Optical Coherence Tomography,” BiOS, Photonics West, San Jose, USA, Jan. 2009.
51. H.-C. Lee, C.-K. Lee, Y.-W. Kiang, C. C. Yang, C.-W. Sun, and Y.-P. Tong, “Monte Carlo Simulations on Transmitted Signals through Biological Tissues with Aperture, Angle, Time, and Polarization Gating,” BiOS, Photonics West, San Jose, USA, Jan. 2005.

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