In vivo, high-resolution, three-dimensional imaging of port wine stain microvasculature in human skin

Background and Objectives Port‐wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization of blood vessels in PWS skin has been demonstrated by several groups. In the past few years, advances in OCT techno...

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Published in	Lasers in surgery and medicine Vol. 45; no. 10; pp. 628 - 632
Main Authors	Liu, Gangjun, Jia, Wangcun, Nelson, J. Stuart, Chen, Zhongping
Format	Journal Article
Language	English
Published	United States Blackwell Publishing Ltd 01.12.2013 Wiley Subscription Services, Inc
Subjects	Adult Algorithms biology and medicine Case-Control Studies Female Humans Imaging, Three-Dimensional Male medical optics and biotechnology Microvessels - pathology optical coherence tomography port sine stain Port-Wine Stain - pathology Tomography, Optical Coherence - methods Vitaceae medical optics and biotechnology biology and medicine port sine stain optical coherence tomography
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Abstract	Background and Objectives Port‐wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization of blood vessels in PWS skin has been demonstrated by several groups. In the past few years, advances in OCT technology have greatly increased imaging speed. Sophisticated numerical algorithms have improved the sensitivity of Doppler OCT dramatically. These improvements have enabled the noninvasive, high‐resolution, three‐dimensional functional imaging of PWS skin. Here, we demonstrate high‐resolution, three‐dimensional, microvasculature imaging of PWS and normal skin using Doppler OCT technique. Study Design/Materials and Methods The OCT system uses a swept source laser which has a central wavelength of 1,310 nm, an A‐line rate of 50 kHz and a total average power of 16 mW. The system uses a handheld imaging probe and has an axial resolution of 9.3 µm in air and a lateral resolution of approximately 15 µm. Images were acquired from PWS subjects at the Beckman Laser Institute and Medical Clinic. Microvasculature of the PWS skin and normal skin were obtained from the PWS subject. Results High‐resolution, three‐dimensional microvasculature of PWS and normal skin were obtained. Many enlarged PWS vessels are detected in the dermis down to 1.0 mm below the PWS skin surface. In one subject, the blood vessel diameters range from 40 to 90 µm at the epidermal–dermal junction and increase up to 300–500 µm at deeper regions 700–1,000 µm below skin surface. The blood vessels close to the epidermal–dermal junction are more uniform, in terms of diameter. The more tortuous and dilated PWS blood vessels are located at deeper regions 600–1,000 µm below the skin surface. In another subject example, the PWS skin blood vessels are dilated at very superficial layers at a depth less than 500 µm below the skin surface. The PWS skin vessel diameters range from 60 to 650 µm, with most vessels having a diameter of around 200 µm. Conclusions OCT can be used to quantitatively image in vivo skin micro‐vasculature. Analysis of the PWS and normal skin blood vessels were performed and the results can provide quantitative information to optimize laser treatment on an individual patient basis. Lasers Surg. Med. 45:628–632, 2013. © 2013 Wiley Periodicals, Inc.
AbstractList	Port-wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization of blood vessels in PWS skin has been demonstrated by several groups. In the past few years, advances in OCT technology have greatly increased imaging speed. Sophisticated numerical algorithms have improved the sensitivity of Doppler OCT dramatically. These improvements have enabled the noninvasive, high-resolution, three-dimensional functional imaging of PWS skin. Here, we demonstrate high-resolution, three-dimensional, microvasculature imaging of PWS and normal skin using Doppler OCT technique.BACKGROUND AND OBJECTIVESPort-wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization of blood vessels in PWS skin has been demonstrated by several groups. In the past few years, advances in OCT technology have greatly increased imaging speed. Sophisticated numerical algorithms have improved the sensitivity of Doppler OCT dramatically. These improvements have enabled the noninvasive, high-resolution, three-dimensional functional imaging of PWS skin. Here, we demonstrate high-resolution, three-dimensional, microvasculature imaging of PWS and normal skin using Doppler OCT technique.The OCT system uses a swept source laser which has a central wavelength of 1,310 nm, an A-line rate of 50 kHz and a total average power of 16 mW. The system uses a handheld imaging probe and has an axial resolution of 9.3 µm in air and a lateral resolution of approximately 15 µm. Images were acquired from PWS subjects at the Beckman Laser Institute and Medical Clinic. Microvasculature of the PWS skin and normal skin were obtained from the PWS subject.STUDY DESIGN/MATERIALS AND METHODSThe OCT system uses a swept source laser which has a central wavelength of 1,310 nm, an A-line rate of 50 kHz and a total average power of 16 mW. The system uses a handheld imaging probe and has an axial resolution of 9.3 µm in air and a lateral resolution of approximately 15 µm. Images were acquired from PWS subjects at the Beckman Laser Institute and Medical Clinic. Microvasculature of the PWS skin and normal skin were obtained from the PWS subject.High-resolution, three-dimensional microvasculature of PWS and normal skin were obtained. Many enlarged PWS vessels are detected in the dermis down to 1.0 mm below the PWS skin surface. In one subject, the blood vessel diameters range from 40 to 90 µm at the epidermal-dermal junction and increase up to 300-500 µm at deeper regions 700-1,000 µm below skin surface. The blood vessels close to the epidermal-dermal junction are more uniform, in terms of diameter. The more tortuous and dilated PWS blood vessels are located at deeper regions 600-1,000 µm below the skin surface. In another subject example, the PWS skin blood vessels are dilated at very superficial layers at a depth less than 500 µm below the skin surface. The PWS skin vessel diameters range from 60 to 650 µm, with most vessels having a diameter of around 200 µm.RESULTSHigh-resolution, three-dimensional microvasculature of PWS and normal skin were obtained. Many enlarged PWS vessels are detected in the dermis down to 1.0 mm below the PWS skin surface. In one subject, the blood vessel diameters range from 40 to 90 µm at the epidermal-dermal junction and increase up to 300-500 µm at deeper regions 700-1,000 µm below skin surface. The blood vessels close to the epidermal-dermal junction are more uniform, in terms of diameter. The more tortuous and dilated PWS blood vessels are located at deeper regions 600-1,000 µm below the skin surface. In another subject example, the PWS skin blood vessels are dilated at very superficial layers at a depth less than 500 µm below the skin surface. The PWS skin vessel diameters range from 60 to 650 µm, with most vessels having a diameter of around 200 µm.OCT can be used to quantitatively image in vivo skin micro-vasculature. Analysis of the PWS and normal skin blood vessels were performed and the results can provide quantitative information to optimize laser treatment on an individual patient basis.CONCLUSIONSOCT can be used to quantitatively image in vivo skin micro-vasculature. Analysis of the PWS and normal skin blood vessels were performed and the results can provide quantitative information to optimize laser treatment on an individual patient basis. Background and Objectives Port-wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization of blood vessels in PWS skin has been demonstrated by several groups. In the past few years, advances in OCT technology have greatly increased imaging speed. Sophisticated numerical algorithms have improved the sensitivity of Doppler OCT dramatically. These improvements have enabled the noninvasive, high-resolution, three-dimensional functional imaging of PWS skin. Here, we demonstrate high-resolution, three-dimensional, microvasculature imaging of PWS and normal skin using Doppler OCT technique. Study Design/Materials and Methods The OCT system uses a swept source laser which has a central wavelength of 1,310nm, an A-line rate of 50kHz and a total average power of 16mW. The system uses a handheld imaging probe and has an axial resolution of 9.3µm in air and a lateral resolution of approximately 15µm. Images were acquired from PWS subjects at the Beckman Laser Institute and Medical Clinic. Microvasculature of the PWS skin and normal skin were obtained from the PWS subject. Results High-resolution, three-dimensional microvasculature of PWS and normal skin were obtained. Many enlarged PWS vessels are detected in the dermis down to 1.0mm below the PWS skin surface. In one subject, the blood vessel diameters range from 40 to 90µm at the epidermal-dermal junction and increase up to 300-500µm at deeper regions 700-1,000µm below skin surface. The blood vessels close to the epidermal-dermal junction are more uniform, in terms of diameter. The more tortuous and dilated PWS blood vessels are located at deeper regions 600-1,000µm below the skin surface. In another subject example, the PWS skin blood vessels are dilated at very superficial layers at a depth less than 500µm below the skin surface. The PWS skin vessel diameters range from 60 to 650µm, with most vessels having a diameter of around 200µm. Conclusions OCT can be used to quantitatively image in vivo skin micro-vasculature. Analysis of the PWS and normal skin blood vessels were performed and the results can provide quantitative information to optimize laser treatment on an individual patient basis. Lasers Surg. Med. 45:628-632, 2013. © 2013 Wiley Periodicals, Inc. [PUBLICATION ABSTRACT] Background and Objectives Port-wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization of blood vessels in PWS skin has been demonstrated by several groups. In the past few years, advances in OCT technology have greatly increased imaging speed. Sophisticated numerical algorithms have improved the sensitivity of Doppler OCT dramatically. These improvements have enabled the noninvasive, high-resolution, three-dimensional functional imaging of PWS skin. Here, we demonstrate high-resolution, three-dimensional, microvasculature imaging of PWS and normal skin using Doppler OCT technique. Study Design/Materials and Methods The OCT system uses a swept source laser which has a central wavelength of 1,310nm, an A-line rate of 50kHz and a total average power of 16mW. The system uses a handheld imaging probe and has an axial resolution of 9.3 mu m in air and a lateral resolution of approximately 15 mu m. Images were acquired from PWS subjects at the Beckman Laser Institute and Medical Clinic. Microvasculature of the PWS skin and normal skin were obtained from the PWS subject. Results High-resolution, three-dimensional microvasculature of PWS and normal skin were obtained. Many enlarged PWS vessels are detected in the dermis down to 1.0mm below the PWS skin surface. In one subject, the blood vessel diameters range from 40 to 90 mu m at the epidermal-dermal junction and increase up to 300-500 mu m at deeper regions 700-1,000 mu m below skin surface. The blood vessels close to the epidermal-dermal junction are more uniform, in terms of diameter. The more tortuous and dilated PWS blood vessels are located at deeper regions 600-1,000 mu m below the skin surface. In another subject example, the PWS skin blood vessels are dilated at very superficial layers at a depth less than 500 mu m below the skin surface. The PWS skin vessel diameters range from 60 to 650 mu m, with most vessels having a diameter of around 200 mu m. Conclusions OCT can be used to quantitatively image in vivo skin micro-vasculature. Analysis of the PWS and normal skin blood vessels were performed and the results can provide quantitative information to optimize laser treatment on an individual patient basis. Lasers Surg. Med. 45:628-632, 2013. copyright 2013 Wiley Periodicals, Inc. Background and Objectives Port‐wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization of blood vessels in PWS skin has been demonstrated by several groups. In the past few years, advances in OCT technology have greatly increased imaging speed. Sophisticated numerical algorithms have improved the sensitivity of Doppler OCT dramatically. These improvements have enabled the noninvasive, high‐resolution, three‐dimensional functional imaging of PWS skin. Here, we demonstrate high‐resolution, three‐dimensional, microvasculature imaging of PWS and normal skin using Doppler OCT technique. Study Design/Materials and Methods The OCT system uses a swept source laser which has a central wavelength of 1,310 nm, an A‐line rate of 50 kHz and a total average power of 16 mW. The system uses a handheld imaging probe and has an axial resolution of 9.3 µm in air and a lateral resolution of approximately 15 µm. Images were acquired from PWS subjects at the Beckman Laser Institute and Medical Clinic. Microvasculature of the PWS skin and normal skin were obtained from the PWS subject. Results High‐resolution, three‐dimensional microvasculature of PWS and normal skin were obtained. Many enlarged PWS vessels are detected in the dermis down to 1.0 mm below the PWS skin surface. In one subject, the blood vessel diameters range from 40 to 90 µm at the epidermal–dermal junction and increase up to 300–500 µm at deeper regions 700–1,000 µm below skin surface. The blood vessels close to the epidermal–dermal junction are more uniform, in terms of diameter. The more tortuous and dilated PWS blood vessels are located at deeper regions 600–1,000 µm below the skin surface. In another subject example, the PWS skin blood vessels are dilated at very superficial layers at a depth less than 500 µm below the skin surface. The PWS skin vessel diameters range from 60 to 650 µm, with most vessels having a diameter of around 200 µm. Conclusions OCT can be used to quantitatively image in vivo skin micro‐vasculature. Analysis of the PWS and normal skin blood vessels were performed and the results can provide quantitative information to optimize laser treatment on an individual patient basis. Lasers Surg. Med. 45:628–632, 2013. © 2013 Wiley Periodicals, Inc. Port-wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization of blood vessels in PWS skin has been demonstrated by several groups. In the past few years, advances in OCT technology have greatly increased imaging speed. Sophisticated numerical algorithms have improved the sensitivity of Doppler OCT dramatically. These improvements have enabled the noninvasive, high-resolution, three-dimensional functional imaging of PWS skin. Here, we demonstrate high-resolution, three-dimensional, microvasculature imaging of PWS and normal skin using Doppler OCT technique. The OCT system uses a swept source laser which has a central wavelength of 1,310 nm, an A-line rate of 50 kHz and a total average power of 16 mW. The system uses a handheld imaging probe and has an axial resolution of 9.3 µm in air and a lateral resolution of approximately 15 µm. Images were acquired from PWS subjects at the Beckman Laser Institute and Medical Clinic. Microvasculature of the PWS skin and normal skin were obtained from the PWS subject. High-resolution, three-dimensional microvasculature of PWS and normal skin were obtained. Many enlarged PWS vessels are detected in the dermis down to 1.0 mm below the PWS skin surface. In one subject, the blood vessel diameters range from 40 to 90 µm at the epidermal-dermal junction and increase up to 300-500 µm at deeper regions 700-1,000 µm below skin surface. The blood vessels close to the epidermal-dermal junction are more uniform, in terms of diameter. The more tortuous and dilated PWS blood vessels are located at deeper regions 600-1,000 µm below the skin surface. In another subject example, the PWS skin blood vessels are dilated at very superficial layers at a depth less than 500 µm below the skin surface. The PWS skin vessel diameters range from 60 to 650 µm, with most vessels having a diameter of around 200 µm. OCT can be used to quantitatively image in vivo skin micro-vasculature. Analysis of the PWS and normal skin blood vessels were performed and the results can provide quantitative information to optimize laser treatment on an individual patient basis.
Author	Nelson, J. Stuart Jia, Wangcun Liu, Gangjun Chen, Zhongping
AuthorAffiliation	3 Department of Surgery, University of California, Irvine, California 92697 2 Department of Biomedical Engineering, University of California, Irvine, California 92612 1 Beckman Laser Institute and Medical Clinic, University of California, Irvine, California 92617
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References	Liu G, Jia W, Sun V, Choi B, Chen Z. High-resolution imaging of microvasculature in human skin in-vivo with optical coherence tomography. Opt Express 2012; 20:7694. Lee KKC, Mariampillai A, Yu JXZ, Cadotte DW, Wilson BC, Standish BA, Yang VXD. Real-time speckle variance swept-source optical coherence tomography using a graphics processing unit. Biomed Opt Express 2012; 3:1557. Yang VX, Gordon ML, Mok A, Zhao Y, Chen Z, Cobbold RSC, Wilson BC, Vitkin IA. Improved phase-resolved optical Doppler tomography using the Kasai velocity estimator and histogram segmentation. Opt Commun 2002; 208:209. Selim MM, Kelly KM, Nelson JS, Wendelschafer-Crabb G, Kennedy WR, Zelickson BD. Confocal microscopy study of nerves and blood vessels in untreated and treated port-wine stains: Preliminary observations. Dermatol Surg 2004; 30:892-897. Zhao Y, Chen Z, Ding Z, Ren H, Nelson JS. Three-dimensional reconstruction of in vivo blood vessels in human skin using phase-resolved optical Doppler tomography. IEEE J. Selected Top Quantum Electron 2001; 7:931. Nelson JS, Kelly KM, Zhao Y, Chen Z. Imaging blood flow in human port-wine stain in situ and in real time using optical Doppler tomography. Arch Dermatol 2001; 137:741. Liu G, Lin AJ, Tromberg BJ, Chen Z. A comparison of Doppler optical coherence tomography methods. Biomed Opt Express 2012; 3:2669. Makita S, Hong Y, Yamanari M, Yatagai T, Yasuno Y. Optical coherence angiography. Opt Express 2006; 14:7821. Zhou Y, Yin D, Xue P, Huang N, Qiu H, Wang Y, Zeng J, Ding Z, Gu Y. Imaging of skin microvessels with optical coherence tomography: Potential uses in port wine stains. Exp Ther Med 2012; 4:1017. Liu G, Chou L, Jia W, Qi W, Choi B, Chen Z. Intensity-based modified Doppler variance algorithm: Application to phase instable and phase stable optical coherence tomography systems. Opt Express 2011; 19:11429. Smithies D, van Gemert M, Hansen M, Milner T, Nelson J. Three-dimensional reconstruction of port wine stain vascular anatomy from serial histological sections. Phys Med Biol 1997; 42:1843. Shiyong Z, Ying G, Ping X, Jin G, Tingme IS, Tianshi E, Naiyan H, Li Z, Haixia Q, Xin Y, Xunbin W. Imaging port wine stains by fiber optical coherence tomography. J Biomed Opt 2010; 15:036020. doi: 10.1117/1.3445712 Liu G, Chen Z. Advances in Doppler OCT. Chin Opt Lett 2013; 11:011792. 2004; 30 2010; 15 2012; 3 2002; 208 2001; 7 2013; 11 2012; 4 2011; 19 1997; 42 2001; 137 2012; 20 2006; 14 e_1_2_7_5_1 e_1_2_7_4_1 e_1_2_7_3_1 e_1_2_7_9_1 e_1_2_7_8_1 Nelson JS (e_1_2_7_2_1) 2001; 137 e_1_2_7_7_1 Liu G (e_1_2_7_6_1) 2013; 11 e_1_2_7_14_1 e_1_2_7_13_1 e_1_2_7_12_1 e_1_2_7_11_1 e_1_2_7_10_1
References_xml	– reference: Lee KKC, Mariampillai A, Yu JXZ, Cadotte DW, Wilson BC, Standish BA, Yang VXD. Real-time speckle variance swept-source optical coherence tomography using a graphics processing unit. Biomed Opt Express 2012; 3:1557. – reference: Liu G, Jia W, Sun V, Choi B, Chen Z. High-resolution imaging of microvasculature in human skin in-vivo with optical coherence tomography. Opt Express 2012; 20:7694. – reference: Makita S, Hong Y, Yamanari M, Yatagai T, Yasuno Y. Optical coherence angiography. Opt Express 2006; 14:7821. – reference: Liu G, Chen Z. Advances in Doppler OCT. Chin Opt Lett 2013; 11:011792. – reference: Yang VX, Gordon ML, Mok A, Zhao Y, Chen Z, Cobbold RSC, Wilson BC, Vitkin IA. Improved phase-resolved optical Doppler tomography using the Kasai velocity estimator and histogram segmentation. Opt Commun 2002; 208:209. – reference: Smithies D, van Gemert M, Hansen M, Milner T, Nelson J. Three-dimensional reconstruction of port wine stain vascular anatomy from serial histological sections. Phys Med Biol 1997; 42:1843. – reference: Liu G, Chou L, Jia W, Qi W, Choi B, Chen Z. Intensity-based modified Doppler variance algorithm: Application to phase instable and phase stable optical coherence tomography systems. Opt Express 2011; 19:11429. – reference: Shiyong Z, Ying G, Ping X, Jin G, Tingme IS, Tianshi E, Naiyan H, Li Z, Haixia Q, Xin Y, Xunbin W. Imaging port wine stains by fiber optical coherence tomography. J Biomed Opt 2010; 15:036020. doi: 10.1117/1.3445712 – reference: Selim MM, Kelly KM, Nelson JS, Wendelschafer-Crabb G, Kennedy WR, Zelickson BD. Confocal microscopy study of nerves and blood vessels in untreated and treated port-wine stains: Preliminary observations. Dermatol Surg 2004; 30:892-897. – reference: Zhao Y, Chen Z, Ding Z, Ren H, Nelson JS. Three-dimensional reconstruction of in vivo blood vessels in human skin using phase-resolved optical Doppler tomography. IEEE J. Selected Top Quantum Electron 2001; 7:931. – reference: Liu G, Lin AJ, Tromberg BJ, Chen Z. A comparison of Doppler optical coherence tomography methods. Biomed Opt Express 2012; 3:2669. – reference: Zhou Y, Yin D, Xue P, Huang N, Qiu H, Wang Y, Zeng J, Ding Z, Gu Y. Imaging of skin microvessels with optical coherence tomography: Potential uses in port wine stains. Exp Ther Med 2012; 4:1017. – reference: Nelson JS, Kelly KM, Zhao Y, Chen Z. Imaging blood flow in human port-wine stain in situ and in real time using optical Doppler tomography. Arch Dermatol 2001; 137:741. – volume: 4 start-page: 1017 year: 2012 article-title: Imaging of skin microvessels with optical coherence tomography: Potential uses in port wine stains publication-title: Exp Ther Med – volume: 42 start-page: 1843 year: 1997 article-title: Three‐dimensional reconstruction of port wine stain vascular anatomy from serial histological sections publication-title: Phys Med Biol – volume: 14 start-page: 7821 year: 2006 article-title: Optical coherence angiography publication-title: Opt Express – volume: 19 start-page: 11429 year: 2011 article-title: Intensity‐based modified Doppler variance algorithm: Application to phase instable and phase stable optical coherence tomography systems publication-title: Opt Express – volume: 11 start-page: 011792 year: 2013 article-title: Advances in Doppler OCT publication-title: Chin Opt Lett – volume: 3 start-page: 1557 year: 2012 article-title: Real‐time speckle variance swept‐source optical coherence tomography using a graphics processing unit publication-title: Biomed Opt Express – volume: 208 start-page: 209 year: 2002 article-title: Improved phase‐resolved optical Doppler tomography using the Kasai velocity estimator and histogram segmentation publication-title: Opt Commun – volume: 15 start-page: 036020 year: 2010 article-title: Imaging port wine stains by fiber optical coherence tomography publication-title: J Biomed Opt – volume: 137 start-page: 741 year: 2001 article-title: Imaging blood flow in human port‐wine stain in situ and in real time using optical Doppler tomography publication-title: Arch Dermatol – volume: 20 start-page: 7694 year: 2012 article-title: High‐resolution imaging of microvasculature in human skin in‐vivo with optical coherence tomography publication-title: Opt Express – volume: 3 start-page: 2669 year: 2012 article-title: A comparison of Doppler optical coherence tomography methods publication-title: Biomed Opt Express – volume: 7 start-page: 931 year: 2001 article-title: Three‐dimensional reconstruction of in vivo blood vessels in human skin using phase‐resolved optical Doppler tomography publication-title: IEEE J. Selected Top Quantum Electron – volume: 30 start-page: 892 year: 2004 end-page: 897 article-title: Confocal microscopy study of nerves and blood vessels in untreated and treated port‐wine stains: Preliminary observations publication-title: Dermatol Surg – ident: e_1_2_7_4_1 doi: 10.1109/2944.983296 – ident: e_1_2_7_10_1 doi: 10.1016/S0030-4018(02)01501-8 – ident: e_1_2_7_14_1 doi: 10.1111/j.1524-4725.2004.30259.x – ident: e_1_2_7_12_1 doi: 10.1364/BOE.3.001557 – ident: e_1_2_7_3_1 doi: 10.1117/1.3445712 – ident: e_1_2_7_9_1 doi: 10.1364/OE.19.011429 – volume: 11 start-page: 011792 year: 2013 ident: e_1_2_7_6_1 article-title: Advances in Doppler OCT publication-title: Chin Opt Lett – volume: 137 start-page: 741 year: 2001 ident: e_1_2_7_2_1 article-title: Imaging blood flow in human port‐wine stain in situ and in real time using optical Doppler tomography publication-title: Arch Dermatol – ident: e_1_2_7_13_1 doi: 10.1088/0031-9155/42/9/014 – ident: e_1_2_7_11_1 doi: 10.1364/OE.14.007821 – ident: e_1_2_7_5_1 doi: 10.3892/etm.2012.711 – ident: e_1_2_7_8_1 doi: 10.1364/BOE.3.002669 – ident: e_1_2_7_7_1 doi: 10.1364/OE.20.007694
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Snippet	Background and Objectives Port‐wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT)... Port-wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT) for the characterization... Background and Objectives Port-wine stain (PWS) is a congenital, progressive vascular malformation of the dermis. The use of optical coherence tomography (OCT)...
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StartPage	628
SubjectTerms	Adult Algorithms biology and medicine Case-Control Studies Female Humans Imaging, Three-Dimensional Male medical optics and biotechnology Microvessels - pathology optical coherence tomography port sine stain Port-Wine Stain - pathology Tomography, Optical Coherence - methods Vitaceae
Title	In vivo, high-resolution, three-dimensional imaging of port wine stain microvasculature in human skin
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