健康个体增强深度成像光相干断层扫描下脉络膜-巩膜连接和脉络膜上腔的特征。
Characterization of the choroid-scleral junction and suprachoroidal layer in healthy individuals on enhanced-depth imaging optical coherence tomography.
机构信息
Department of Ophthalmology, Duke University Medical Center, Durham, North Carolina.
Department of Biomedical Engineering, Duke University, Durham, North Carolina.
出版信息
JAMA Ophthalmol. 2014 Feb;132(2):174-81. doi: 10.1001/jamaophthalmol.2013.7288.
IMPORTANCE
Accurate measurements of choroidal thickness (CT) using enhanced-depth imaging optical coherence tomography (EDI-OCT) require a well-defined choroid-scleral junction (CSJ), which may appear in some eyes as a hyporeflective band corresponding to the suprachoroidal layer (SCL).
OBJECTIVE
To identify factors associated with the presence and thickness of the SCL in healthy participants and determine how different CSJ boundary definitions impact CT measurements.
DESIGN, SETTING, AND PARTICIPANTS: Secondary analysis of EDI-OCT images obtained prospectively from 74 eyes of 74 controls (mean age, 68.6 years) from the Age-Related Eye Disease Study 2 Ancillary SDOCT Study.
MAIN OUTCOMES AND MEASURES
The CSJ appearances were categorized as either having no visible SCL or a hyporeflective band corresponding to the SCL. Ocular parameters associated with the presence and thickness of the SCL were identified. Subfoveal CT was measured using 3 different posterior boundaries: (1) the posterior vessel border (vascular CT [VCT]), (2) inner border of the SCL (stromal CT [StCT]), and (3) inner border of the sclera (total CT [TCT]). Manual segmentation using custom software was used to compare VCT, StCT, and TCT across the macula. RESULTS The SCL was visible in 33 eyes (44.6%). Factors associated with SCL presence and thickness included hyperopic refractive error (R2 = 0.123; P = .045) and increased TCT (R2 = 0.215; P = .004), but not age, visual acuity, intraocular pressure, retinal foveal thickness, VCT, or StCT. In eyes where the SCL was not visible, mean [SD] subfoveal VCT was 222.3 [101.5] μm and StCT and TCT were 240.0 [99.0] μm, with a difference of 17.7 [16.0] μm (P < .001). In eyes where the SCL was visible, mean [SD] subfoveal VCT, StCT, and TCT were 221.9 [83.1] μm, 257.7 [97.3] μm, and 294.1 [104.8] μm, respectively, with the greatest difference of 72.2 [30.4] μm between VCT and TCT (P < .001). All 3 CT measurements were significantly different along all points up to 3.0 mm nasal and temporal to the fovea.
CONCLUSIONS AND RELEVANCE
A hyporeflective SCL is visible at the CSJ on EDI-OCT in nearly half of healthy individuals, and its presence correlates with hyperopia. Different posterior boundary definitions may result in significant differences in CT measurements and should be explicitly identified in future choroidal studies and segmentation algorithms.
重要性
使用增强深度成像光相干断层扫描(EDI-OCT)准确测量脉络膜厚度(CT)需要一个明确界定的脉络膜-巩膜交界处(CSJ),在某些眼睛中,这个交界处可能表现为对应于脉络膜上腔(SCL)的低反射带。
目的
确定与健康参与者中 SCL 的存在和厚度相关的因素,并确定不同的 CSJ 边界定义如何影响 CT 测量。
设计、设置和参与者:对来自年龄相关性眼病研究 2 辅助 SDOCT 研究的 74 名健康对照者(74 只眼)前瞻性获得的 EDI-OCT 图像进行二次分析(平均年龄,68.6 岁)。
主要结果和措施
CSJ 外观分为无可见 SCL 或对应于 SCL 的低反射带。确定与 SCL 存在和厚度相关的眼参数。使用 3 种不同的后边界测量:(1)后血管边界(血管 CT [VCT]),(2)SCL 的内边界(基质 CT [StCT]),和(3)巩膜的内边界(总 CT [TCT])。使用定制软件进行手动分割,以比较黄斑区的 VCT、StCT 和 TCT。
结果
SCL 在 33 只眼(44.6%)中可见。与 SCL 存在和厚度相关的因素包括远视屈光不正(R2 = 0.123;P =.045)和增加的 TCT(R2 = 0.215;P =.004),但与年龄、视力、眼内压、视网膜中心凹厚度、VCT 或 StCT 无关。在 SCL 不可见的眼中,平均(标准差)黄斑下 VCT 为 222.3(101.5)μm,StCT 和 TCT 分别为 240.0(99.0)μm,差异为 17.7(16.0)μm(P <.001)。在 SCL 可见的眼中,平均(标准差)黄斑下 VCT、StCT 和 TCT 分别为 221.9(83.1)μm、257.7(97.3)μm 和 294.1(104.8)μm,VCT 和 TCT 之间最大差异为 72.2(30.4)μm(P <.001)。所有 3 种 CT 测量值在距黄斑鼻侧和颞侧 3.0mm 范围内的各个点均有显著差异。
结论和相关性
在近一半的健康个体中,在 EDI-OCT 上可以看到低反射的 SCL,其存在与远视相关。不同的后边界定义可能导致 CT 测量值的显著差异,在未来的脉络膜研究和分割算法中应明确识别。
Zotero 插件