Department of Ophthalmology, Duke University School of Medicine, Durham, North Carolina.
National Healthcare Group Eye Institute, Tan Tock Seng Hospital, Singapore, Singapore.
JAMA Ophthalmol. 2021 Feb 1;139(2):182-188. doi: 10.1001/jamaophthalmol.2020.5730.
Noninvasive retinal imaging may detect structural changes associated with Parkinson disease (PD) and may represent a novel biomarker for disease detection.
To characterize alterations in the structure and microvasculature of the retina and choroid in eyes of individuals with PD and compare them with eyes of age- and sex-matched cognitively healthy control individuals using optical coherence tomography (OCT) and OCT angiography (OCTA).
DESIGN, SETTING, AND PARTICIPANTS: This cross-sectional study was conducted at the Duke Neurological Disorders Clinic in Durham, North Carolina. Individuals aged 50 years or older with a diagnosis of PD were eligible for inclusion and underwent an evaluation and diagnosis confirmation before enrollment. Control individuals aged 50 years or older and without subjective cognitive dysfunction, a history of tremor, or evidence of motor dysfunction consistent with parkinsonism were solicited from the clinic or the Duke Alzheimer's Disease Prevention Registry. Individuals with diabetes, glaucoma, retinal pathology, other dementias, and corrected Early Treatment Diabetic Retinopathy Study (ETDRS) visual acuity worse than 20/40 Snellen were excluded. Data were analyzed between January 1, 2020, and March 30, 2020.
All participants underwent OCT and OCTA imaging.
Generalized estimating equation analysis was used to characterize the association between imaging parameters and PD diagnosis. Superficial capillary plexus vessel density (VD) and perfusion density (PFD) were assessed within the ETDRS 6 × 6-mm circle, 6 × 6-mm inner ring, and 6 × 6-mm outer ring, as was the foveal avascular zone area. Peripapillary retinal nerve fiber layer thickness, macular ganglion cell-inner plexiform layer thickness, central subfield thickness, subfoveal choroidal thickness, total choroidal area, luminal area, and choroidal vascularity index (CVI) were measured.
A total of 124 eyes of 69 participants with PD (39 men [56.5%]; mean [SD] age, 71.7 [7.0] years) and 248 eyes of 137 control participants (77 men [56.2%]; mean [SD] age, 70.9 [6.7] years) were analyzed. In the 6 × 6-mm ETDRS circle, VD (β coefficient = 0.37; 95% CI, 0.04-0.71; P = .03) and PFD (β coefficient = 0.009; 95% CI, 0.0003-0.018; P = .04) were lower in eyes of participants with PD. In the inner ring of the 6 × 6-mm ETDRS circle, VD (β coefficient = 0.61; 95% CI, 0.20-1.02; P = .003) and PFD (β coefficient = 0.015; 95% CI, 0.005-0.026; P = .004) were lower in eyes of participants with PD. Total choroidal area (β coefficient = -1.74 units2; 95% CI, -3.12 to -0.37 units2; P = .01) and luminal area (β coefficient = -1.02 units2; 95% CI, -1.86 to -0.18 units2; P = .02) were greater, but CVI was lower (β coefficient = 0.5%; 95% CI, 0.2%-0.8%; P < .001) in eyes of individuals with PD.
This study found that individuals with PD had decreased retinal VD and PFD as well as choroidal structural changes compared with age- and sex-matched control participants. Given the observed population differences in these noninvasive retinal biomarkers, further research into their clinical utility in PD is needed.
非侵入性视网膜成像可能会检测到与帕金森病(PD)相关的结构变化,并且可能代表用于疾病检测的新型生物标志物。
使用光学相干断层扫描(OCT)和 OCT 血管造影(OCTA)来描述 PD 患者眼睛的视网膜和脉络膜的结构和微血管变化,并将其与年龄和性别匹配的认知健康对照组进行比较。
设计、地点和参与者:这是一项在北卡罗来纳州达勒姆市杜克神经疾病诊所进行的横断面研究。符合纳入标准的参与者为年龄在 50 岁或以上、被诊断为 PD 并接受评估和诊断确认的患者。对照组参与者的年龄也在 50 岁或以上,无主观认知障碍、震颤史或与帕金森病一致的运动功能障碍的证据。排除患有糖尿病、青光眼、视网膜病变、其他痴呆症和矫正后的早期糖尿病视网膜病变研究(ETDRS)视力低于 20/40 Snellen 的个体。数据分析于 2020 年 1 月 1 日至 2020 年 3 月 30 日进行。
所有参与者均接受了 OCT 和 OCTA 成像。
使用广义估计方程分析来描述成像参数与 PD 诊断之间的关联。在 ETDRS 6×6mm 圆内评估浅层毛细血管丛血管密度(VD)和灌注密度(PFD),以及 6×6mm 内圈和 6×6mm 外圈的中央无血管区面积。测量了视盘周围视网膜神经纤维层厚度、黄斑神经节细胞-内丛状层厚度、中央小凹区厚度、脉络膜下腔厚度、总脉络膜面积、管腔面积和脉络膜血管指数(CVI)。
共分析了 69 名 PD 患者的 124 只眼(39 名男性[56.5%];平均[标准差]年龄 71.7[7.0]岁)和 137 名对照参与者的 248 只眼(77 名男性[56.2%];平均[标准差]年龄 70.9[6.7]岁)。在 ETDRS 6×6mm 圆内,PD 患者的 VD(β系数=0.37;95%CI,0.04-0.71;P=0.03)和 PFD(β系数=0.009;95%CI,0.0003-0.018;P=0.04)较低。在 ETDRS 6×6mm 内圈中,PD 患者的 VD(β系数=0.61;95%CI,0.20-1.02;P=0.003)和 PFD(β系数=0.015;95%CI,0.005-0.026;P=0.004)较低。总脉络膜面积(β系数=-1.74 单位 2;95%CI,-3.12 至-0.37 单位 2;P=0.01)和管腔面积(β系数=-1.02 单位 2;95%CI,-1.86 至-0.18 单位 2;P=0.02)较大,但 CVI 较低(β系数=0.5%;95%CI,0.2%-0.8%;P<0.001)。
这项研究发现,与年龄和性别匹配的对照组相比,PD 患者的视网膜 VD 和 PFD 降低,脉络膜结构发生变化。鉴于这些非侵入性视网膜生物标志物在人群中存在差异,需要进一步研究它们在 PD 中的临床应用。