[1] Julian Armstrong, Matthew Leigh, Ian Walton, et al. In vivo size and shape measurement of the human upper airway using endoscopic longrange optical coherence tomography. Optics Express, 11, 1817-1826(2003).

[2] Woo June Choi, Ruikang K Wang. In vivo imaging of functional microvasculature within tissue beds of oral and nasal cavities by swept-source optical coherence tomography with a forward/side-viewing probe. Biomed Opt Express, 5, 2620-2634(2014).

[3] Kushal Wijesundara, Carlton Zdanski, Julia Kimbell, et al. Quantitative upper airway imaging with anatomic optical coherence tomography. Am J Respir Crit Care Med, 173, 226-233(2006).

[4] Bahar Davoudi, Andras Lindenmaier, Beau A Standish, et al. Noninvasive in vivo structural and vascular imaging of human oral tissues with spectral domain optical coherence tomography. Biomed Opt Express, 3, 826-839(2012).

[5] Adam M Zysk, Freddy T Nguyen, Amy L Oldenburg, et al. Optical coherence tomography: A review of clinical development from bench to bedside. Journal of Biomedical Optics, 12, 21-30(2007).

[6] Robert A McLaughlin, Jonathan P Williamson, Martin J Phillips, et al. Applying anatomical optical coherence tomography to quantitative 3 D imaging of the lower airway. Opt Express, 16, 17521-17529(2008).

[7] Yeh-Chan Ahn, Sung Won Kim, Sang Seok Hwang, et al. Optical imaging of subacute airway remodeling and adipose stem cell engraftment after airway injury. Biomed Opt Express, 5, 312-321(2013).

[8] S Han, N H El-Abbadi, N Hanna, et al. Evaluation of tracheal imaging by optical coherence tomography. Respiration, 72, 537-541(2005).

[9] Ridgway, M. J., Matthew Ridgway James, Ahuja Gurpreet, et al. Imaging of the pediatric airway using optical coherence tomography. Laryngoscope, 117, 2206-2212(2007).

[10] J Jing, J Zhang, A C Loy, et al. High-speed upper-airway imaging using full-range optical coherence tomography. Journal of Biomedical Optics, 17, 110507(2012).

[11] A D Lucey, A J C King, G A Tetlow, et al. Measurement, reconstruction, and flow-field computation of the human pharynx with application to sleep apnea. IEEE Trans Biomed Eng, 57, 2535-2548(2010).

[12] B Ruofei, B Santosh, I Nicusor, et al. Airway compliance measured by anatomic optical coherence tomography. Biomed Opt Express, 8, 2195-2209(2017).

[13] C J Joseph, Chou Lidek, Su Erica, et al. Anatomically correct visualization of the human upper airway using a high-speed long range optical coherence tomography system with an integrated positioning sensor. Sci Rep, 6, 39443(2016).

[14] G K Sharma, G S Ahuja, M Wiedmann, et al. Long-range optical coherence tomography of the neonatal upper airway for early diagnosis of intubation-related subglottic injury. American Journal of Respiratory and Critical Care Medicine, 192, 1504-1513(2015).

[15] Frances B Lazarow, Gurpreet S Ahuja, Loy Anthony Chin, et al. Intraoperative long range optical coherence tomography as a novel method of imaging the pediatric upper airway before and after adenotonsillectomy. Int J Pediatr Otorhinolaryngol, 79, 63-70(2015).

[16] J H Walsh, M S Leigh, A Paduch, et al. Evaluation of pharyngeal shape and size using anatomical optical coherence tomography in individuals with and without obstructive sleep apnoea. J Sleep Res, 17, 230-238(2008).

[17] Matthew S Leigh, Julian J Armstrong, Alexandre Paduch, et al. Anatomical optical coherence tomography for long-term, portable, quantitative endoscopy. IEEE Trans Biomed Eng, 55, 1438-1446(2008).

[18] Kushal Wijesundara, Carlton Zdanski, Julia Kimbell, et al. Quantitative upper airway endoscopy with swept-source anatomical optical coherence tomography. Biomed Opt Express, 5, 788-799(2014).

[19] Veronika Volgger, Giriraj K Sharma, Joseph C Jing, et al. Long-range Fourier domain optical coherence tomography of the pediatric subglottis. Int J Pediatr Otorhinolaryngol, 79, 119-126(2015).

[20] Miranda Kirby, Keishi Ohtani, Taylor Nickens, et al. Reproducibility of optical coherence tomography airway imaging. Biomed Opt Express, 6, 4365-4377(2015).

[21] D C Adams, L P Hariri, A J Miller, et al. Birefringence microscopy platform for assessing airway smooth muscle structure and function in vivo. Science Translational Medicine, 8, 359ra131(2016).

[22] L Chou, A Batchinsky, S Belenkiy, et al. In vivo detection of inhalation injury in large airway using three-dimensional long-range swept-source optical coherence tomography. Journal of Biomedical Optics, 19, 036018(2014).

[23] Li Qi, Shenghai Huang, Andrew E Heidari, et al. Automatic airway wall segmentation and thickness measurement for long-range optical coherence tomography images. Opt Express, 23, 33992-34006(2015).

[24] Sang-Won Lee, Andrew E Heidary, David Yoon, et al. Quantification of airway thickness changes in smoke-inhalation injury using in-vivo 3-D endoscopic frequency-domain optical coherence tomography. Biomed Opt Express, 2, 243-254(2011).

[25] McNichols R J, Ashok Gowda, Brent A. Development of an endoscopic fluescence imageguided OCT probe f al cancer detection[C]Proceedings of SPIE The International Society f Optical Engineering, 2001, 6(4): 2330.

[26] Suzanne C Whiteman, Ying Yang, van Pittius Daniel Gey, et al. Optical coherence tomography: real-time imaging of bronchial airways microstructure and detection of inflammatory/neoplastic morphologic changes. Clin Cancer Res, 12, 813-818(2006).

[27] S D Murgu, H G Colt. Combined optical coherence tomography and endobronchial ultrasonography for laser-assisted treatment of postintubation laryngotracheal stenosis. Ann Otol Rhinol Laryngol, 122, 299-307(2013).

[28] E Shostak, L P Hariri, G Z Cheng, et al. Needle-based optical coherence tomography to guide transbronchial lymph node biopsy. Journal of Bronchology & Interventional Pulmonology, 25, 189-197(2018).

[29] L P Hariri, D C Adams, J C Wain, et al. Endobronchial optical coherence tomography for low-risk microscopic assessment and diagnosis of idiopathic pulmonary fibrosis in vivo. American Journal of Respiratory & Critical Care Medicine, 197, 949-952(2017).

[30] Y Miao, J H Choi, L D Chou, et al. Automatic proximal airway volume segmentation using optical coherence tomography for assessment of inhalation injury. Journal of Trauma and Acute Care Surgery, 87, S132-S137(2019).

[31] J H Choi, L D Chou, T R Roberts, et al. Point-of-care endoscopic optical coherence tomography detects changes in mucosal thickness in ARDS due to smoke inhalation and burns. Burns, 45, S89-S97(2019).

[32] Sheet D, Banerjee S, Phani S, et al. Transfer learning of tissue photon interaction in optical coherence tomography towardsin vivo histology of the al mucosa[C]2014 IEEE 11th International Symposium on Biomedical Imaging (ISBI), 2014:13891392.

[33] Heidari Ae, S P Sunny, B James, et al. Optical coherence tomography as an oral cancer screening adjunct in a low resource settings. IEEE Journal of Selected Topics in Quantum Electronics, 25, 7202008(2019).

[34] A Sergeev, V Gelikonov, G Gelikonov, et al. In vivo endoscopic OCT imaging of precancer and cancer states of human mucos. Optics Express, 1, 432-440(1997).

[35] Lee Cheng-Kuang, Chi Ting-Ta, Wu Chiung-Ting, et al. Diagnosis of oral precancer with optical coherence tompgraphy. Biomed Opt Express, 3, 1632-1646(2012).

[36] Nagarajan N, Vasantha J R, Raj J G, et al. A novel design of PCF f supercontinuum source to detect al cancer using OCT[C]2015 International Conference on Microwave Photonics (ICMAP), 2015.

[37] Lee Amd, L Cahill, K Liu, et al. Wide-field in vivo oral OCT imaging. Biomed Opt Express, 6, 2664-2674(2015).

[38] Sinescu C, Duma V F, Canjau S, et al. Dentistry investigations of teeth dental prostheses using OCT[C]SPIE Photonics Europe, 2016.

[39] P M Andrews, H W Wang, J Wierwille, et al. Optical coherence tomography of the living human kidney. Journal of Innovative Optical Health Sciences, 7, 1350064(2014).

[40] Li Qian, Onozato Maristela, rews Peter M, et al. Threedimensional highresolution optical coherence tomography (OCT) imaging of human kidney[C]International Conference of the IEEE Engineering in Medicine & Biology Society, 2009: 57415743.

[41] Mara Buijs, Peter G K Wagstaff, Bruin Daniel M de, et al. An in-vivo prospective study of the diagnostic yield and accuracy of optical biopsy compared with conventional renal mass biopsy for the diagnosis of renal cell carcinoma: The interim analysis. Eur Urol Focus, 4, 978-985(2018).

[42] Chihhao Liu, Yong Du, Manmohan Singh, et al. Combined optical coherence tomography optical coherence elastography f glomerulonephritis classification[C]SPIE BiOS, 2016.

[43] Zhenhe Ma, Ning Ding, Yao Yu, et al. Quantification of cerebral vascular perfusion density via optical coherence tomography based on locally adaptive regional growth. Appl Opt, 57, 10117-10124(2018).

[44] S Glaßer, T Hoffmann, A Boese, et al. Virtual inflation of the cerebral artery wall for the integrated exploration of OCT and histology data. Computer Graphics Forum, 36, 57-68(2017).

[45] V. Semyachkina-Glushkovskaya Oxana, V. Lychagov Vladislav, A. Bibikova Olga, et al. The assessment of pathological changes in cerebral blood flow in hypertensive rats with stress-induced intracranial hemorrhage using Doppler OCT: Particularities of arterial and venous alterations. Photonics and Lasers in Medicine, 2, 109-116(2013).

[46] A D Aguirre, Y Chen, J G Fujimoto, et al. Depth-resolved imaging of functional activation in the rat cerebral cortex using optical coherence tomography. Optics Letters, 31, 3459-3461(2006).

[47] W Chen, C Du, Y Pan. Cerebral capillary flow imaging by wavelength-division-multiplexing swept-source optical Doppler tomography. J Biophotonics, 11, 201800004(2018).

[48] C Rodriguez, J I Szu, M M Eberle, et al. Decreased light attenuation in cerebral cortex during cerebral edema detected using optical coherence tomography. Neurophotonics, 1, 025004(2014).

[49] S Askaruly, Y Ahn, H Kim, et al. Quantitative evaluation of skin surface roughness using optical coherence tomography in vivo. IEEE Journal of Selected Topics in Quantum Electronics, 25, 7202308(2019).

[50] M Mogensen, L Thrane, T M Jørgensen, et al. OCT imaging of skin cancer and other dermatological diseases. Journal of Biophotonics, 2, 442-451(2010).

[51] M Ziolkowska, C M Philipp, J Liebscher, et al. OCT of healthy skin, actinic skin and NMSC lesions. Medical Laser Application, 24, 256-264(2009).

[52] J Holmes, S Schuh, F L Bowling, et al. Dynamic optical coherence tomography is a new technique for imaging skin around lower extremity wounds. The International Journal of Lower Extremity Wounds, 18, 65-74(2019).

[53] F H Silver, R G Shah. Mechanical spectroscopy and imaging of skin components in vivo: Assignment of the observed moduli. Skin Res Technol, 25, 47-53(2019).

[54] S M Jansen, B De, B H M I Van, et al. Optical techniques for perfusion monitoring of the gastric tube after esophagectomy: A review of technologies and thresholds. Diseases of the Esophagus Official Journal of the International Society for Diseases of the Esophagus, 31, 1-11(2018).

[55] Q Ji, N Sudheendran, C H Liu, et al. Raman spectroscopy complements optical coherent tomography in tissue classification and cancer detection. Biological Trace Element Research, 12, 2078539(2015).

[56] M. Jansen Sanne, Almasian Mitra, S. Wilk Leah, et al. Feasibility of optical coherence tomography (OCT) for intra-operative detection of blood flow during gastric tube reconstruction. Sensors (Basel), 18, 1331(2018).

[57] X Yu, Y Luo, X Liu, et al. Towards high speed imaging of cellular structures in rat colon using micro-optical coherence tomography. IEEE Photonics Journal, 8, 3900308(2016).

[58] Tsung-Han Tsai, Hsiang-Chieh Lee, Osman O Ahsen, et al. Ultrahigh speed endoscopic optical coherence tomography for gastroenterology. Biomed Opt Express, 5, 4387-4404(2014).