脉络膜成像技术的进展及其在青光眼临床研究中的应用

doi:10.3760/cma.j.issn.1674-845X.2014.10.012

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摘要

脉络膜与青光眼关系的研究一直受限于研究方法而难以深入开展。近年，基于OCT技术的脉络膜成像技术例如增强深部成像OCT（EDI-OCT）和扫频光源OCT（SS-OCT）进入临床应用，青光眼领域借此观察了不同类型青光眼的脉络膜厚度及其有关影响因素，推进了脉络膜厚度与各种青光眼间关系的了解和认识。

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	任泽钦

关键词 ：脉络膜厚度, 体层摄影术, 光学相干, 青光眼

Abstract：

The relationship between the choroid and glaucoma has long been difficult to study due to the limitations of research methods. Based on OCT technology， choroid imaging techniques such as enhanced depth imaging OCT （EDI-OCT） and swept-source OCT （SS-OCT） have been an accepted clinical application in recent years. They are also used in the study of glaucoma to observe the choroidal thicknesses of various glaucomas and the related factors affecting the disease. These techniques promote an understanding and knowledge of the relationship between choroidal thickness and different types of glaucoma.

Key words： Choroidal thickness Tomography optical coherence Glaucoma

收稿日期: 2014-03-06

通讯作者: 任泽钦，Email：renzeqin@ 163.com

引用本文:

任泽钦. 脉络膜成像技术的进展及其在青光眼临床研究中的应用[J]. 中华眼视光学与视觉科学杂志, 2014, 16(10): 626-630. Ren Zeqin. Progress in choroid imaging technology and its application in glaucoma clinical research. Chinese Journal of Optometry Ophthalmology and Visual science, 2014, 16(10): 626-630. DOI: 10.3760/cma.j.issn.1674-845X.2014.10.012

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https://www.cjoovs.com/CN/10.3760/cma.j.issn.1674-845X.2014.10.012 或 https://www.cjoovs.com/CN/Y2014/V16/I10/626

[1]	Madonna RJ. The choroid and glaucoma[J]. Clin Eye Vis Care，1998，10：17-20.
[2]	Quigley HA， Friedman DS， Congdon NG. Possible mechanisms of primary angle-closure and malignant glaucoma[J]. J Glaucoma，2003，12：167-180.
[3]	Wong IY， Koizumi H， Lai WW. Enhanced depth imaging optical coherence tomography[J]. Ophthalmic Surg Lasers Imaging，2011， 42：S75-S84.
[4]	Adhi M， Duker JS. Optical coherence tomography-current and future applications[J]. Curr Opin Ophthalmol，2013，24：213-221.
[5]	Michalewska Z， Michalewski J， Nawrocki J. Swept-source OCT. wide-field simultaneous choroid， retina， and vitreous visualization[J]. Retina Today，2013：50-52，56.
[6]	Mansouri K， Nuyen B， N Weinreb R. Improved visualization of deep ocular structures in glaucoma using high penetration optical coherence tomography[J]. Expert Rev Med Devices，2013， 10：621-628.
[7]	Banitt M. The choroid in glaucoma[J]. Curr Opin Ophthalmol，2013，24：125-129.
[8]	Mrejen S， Spaide RF. Optical coherence tomography： imaging of the choroid and beyond[J]. Surv Ophthalmol，2013，58：387-429.
[9]	Wu L， Alpizar-Alvarez N. Choroidal imaging by spectral domain-optical coherence tomography[J]. Taiwan J Ophthalmol，2013，3：3-13.
[10]	Spaide RF， Koizumi H， Pozzoni MC. Enhanced depth imaging spectral-domain optical coherence tomography[J]. Am J Ophthalmol，2008，146：496-500.
[11]	Maul EA， Friedman DS， Chang DS， et al. Choroidal thickness measured by spectral domain optical coherence tomography： factors affecting thickness in glaucoma patients[J]. Ophthalmology，2011，118：1571-1579.
[12]	Yasuno Y， Hong Y， Makita S， et al. In vivo high-contrast imaging of deep posterior eye by 1-µm swept source optical coherence tomography and scattering optical coherence angiography[J]. Opt Express，2007，15：6121-6139.
[13]	Duan L， Hong YJ， Yasuno Y. Automated segmentation and characterization of choroidal vessels in high-penetration optical coherence tomography[J]. Optics Express，2013，21：15787-15808.
[14]	Ikuno Y， Maruko I， Yasuno Y， et al. Reproducibility of retinal and choroidal thickness measurements in enhanced depth imaging and high-penetration optical coherence tomography[J]. Invest Ophthalmol Vis Sci，2011，52：5536-5540.
[15]	Miki A， Ikuno Y， Jo Y， et al. Comparison of enhanced depth imaging and high-penetration optical coherence tomography for imaging deep optic nerve head and parapapillary structures[J]. Clin Ophthalmol，2013，7：1995-2001.
[16]	Quigley HA. Angle-closure glaucoma： concepts and epidemiology[J]. Glaucoma Today，2009，8：34-36.
[17]	Quigley HA. What′s the choroid got to do with angle closure?[J]. Arch Ophthalmol，2009，127：693-694.
[18]	Ehrlich JR， Peterson J， Parlitsis G，et al. Peripapillary choroidal thickness in glaucoma measured with optical coherence tomography[J]. Exp Eye Res，2011，92：189-194.
[19]	Hirooka K， Tenkumo K， Fujiwara A， et al. Evaluation of peripapillary choroidal thickness in patients with normal-tension glaucoma[J]. BMC Ophthalmol，2012，12：29.
[20]	李略，毛进，卞爱玲. 原发性开角型青光眼与正常人视乳头周围脉络膜厚度的比较[J]. 中华眼科杂志，2013，49：116-121.
[21]	Li L， Bian A， Zhou Q， et al. Peripapillary choroidal thickness in both eyes of glaucoma patients with unilateral visual field loss[J]. Am J Ophthalmol，2013，156：1277-1284.
[22]	Dai Y， Jonas JB， Huang H， et al. Microstructure of parapapillary atrophy： beta zone and gamma zone[J]. Invest Ophthalmol Vis Sci，2013，54：2013-2018.
[23]	Mwanza JC， Sayyad FE， Budenz DL. Choroidal thickness in unilateral advanced glaucoma[J]. Invest Ophthalmol Vis Sci，2012，53：6695-6701.
[24]	Mwanza JC， Hochberg JT， Banitt MR， et al. Lack of association between glaucoma and macular choroidal thickness measured with enhanced depth-imaging optical coherence tomography[J]. Invest Ophthalmol Vis Sci，2011，52：3430-3435.
[25]	Hirooka K， Fujiwara A， Shiragami C， et al. Relationship between progression of visual field damage and choroidal thickness in eyes with normal-tension glaucoma[J]. Clin Experiment Ophthalmol，2012，40：576-582.
[26]	Usui S， Ikuno Y， Miki A， et al. Evaluation of the choroidal thickness using high-penetration optical coherence tomography with long wavelength in highly myopic normal-tension glaucoma[J]. Am J Ophthalmol，2012，153：10-16.
[27]	Usui S， Ikuno Y， Uematsu S， et al. Changes in axial length and choroidal thickness after intraocular pressure reduction resulting from trabeculectomy[J]. Clin Ophthalmol，2013，7：1155-1161.
[28]	Tarongoy P， Ho CL， Walton DS. Angle-closure glaucoma： the role of the lens in the pathogenesis， prevention， and treatment[J]. Surv Ophthalmol，2009，54：211-225.
[29]	Arora KS， Quigley HA. Author response： choroidal thickness change after water drinking is greater in angle closure than in open-angle eyes[J]. Invest Ophthalmol Vis Sci，2013，54：657-658.
[30]	Yang M， Aung T， Husain R， et al. Choroidal expansion as a mechanism for acute primary angle closure： an investigation into the change of biometric parameters in the first 2 weeks[J]. Br J Ophthalmol，2005，89：288-290.
[31]	Arora KS， Jefferys JL， Maul EA， et al. The choroid is thicker in angle closure than in open angle and control eyes[J]. Invest Ophthalmol Vis Sci，2012，53：7813-7818.
[32]	Hata M， Hirose F， Oishi A， et al. Changes in choroidal thickness and optical axial length accompanying intraocular pressure increase[J]. Jpn J Ophthalmol，2012，56：564-568.
[33]	Arora KS， Jefferys JL， Maul EA， et al. Choroidal thickness change after water drinking is greater in angle closure than in open angle eyes[J]. Invest Ophthalmol Vis Sci，2012，53：6393-6402.
[34]	Wang W， Zhou M， Huang W， et al. Does acute primary angle-closure cause an increased choroidal thickness?[J]. Invest Ophthalmol Vis Sci，2013，54：3538-3545.
[35]	Zhou M， Wang W， Ding X， et al. Choroidal thickness in fellow eyes of patients with acute primary angle-closure measured by enhanced depth imaging spectral-domain optical coherence tomography[J]. Invest Ophthalmol Vis Sci，2013，54：1971-1978.
[36]	Huang W， Wang W， Gao X， et al. Choroidal thickness in the subtypes of angle closure： an EDI-OCT study[J]. Invest Ophthalmol Vis Sci，2013，54：7849-7853.