视觉诱发电位(VEPs)研究在评估无视网膜病变的糖尿病患者视觉通路功能障碍中的实用性:与糖尿病周围神经病变及其他临床发现的相关性。

Kumar Ashok, Panjwani Ankit, Pandey K Nitin, Kumar Sanjeev
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引用次数: 0

摘要

目的和目标:糖尿病(DM)患者的视觉功能障碍是多因素造成的,可由血管疾病和代谢异常引起,这些疾病可影响视网膜、视神经和视觉通路。视觉诱发电位(VEP)是一种电生理测试,可量化从视网膜经视神经和视束到视觉皮层的视觉通路的功能完整性。本研究旨在调查无视网膜病变的糖尿病患者与健康对照组相比视觉通路功能障碍的情况,并寻找与糖尿病神经病变、糖尿病病程或 HbA1c 水平的相关性。研究方法研究对象包括 75 名糖尿病患者和 75 名年龄和性别匹配的对照组。在美敦力肌电图机上使用模式反转刺激法记录 VEPs,并记录糖尿病患者和健康对照组的 P100 潜伏期和 N75-P100 振幅。结果显示与健康对照组相比,糖尿病病例的平均 P100 潜伏期明显延长,N75-P100 振幅明显降低(P < 0.001)。与无周围神经病变的糖尿病患者相比,有周围神经病变的糖尿病患者的 P100 潜伏期明显延长,N75-P100 振幅明显减小。此外,还发现 VEP P100 潜伏期(p < 0.001)和 N75-P100 振幅(p < 0.001)与病程呈明显的正相关和负相关。结论糖尿病患者在出现视网膜病变或周围神经病变之前就可观察到 VEP 变化,这表明糖尿病患者在出现这些并发症之前就已出现视通路功能障碍。早期临床前视觉通路功能障碍可促使采取必要措施减少糖尿病并发症。缩写:DM = 糖尿病,VEP = 视觉诱发电位,HbA1c = 血红蛋白 A1 c,MRI = 磁共振成像,EEG = 脑电图,P100 = 潜伏期 100 毫秒(毫秒)时的正波峰值,N75 = 潜伏期 75 毫秒(毫秒)时的负波峰值,N145 = 潜伏期 145 毫秒(毫秒)时的负波峰值、OCT=光学相干断层扫描,PRVEP=模式反转视觉诱发电位,NCS=神经传导研究,SSR=交感皮肤反应,IL1=白细胞介素-1,LIF=白血病抑制因子,CNTF=睫状神经营养因子,TNF alpha=肿瘤坏死因子-α,TGF-beta=转化生长因子-beta。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Utility of Visual Evoked Potentials (VEPs) study in the evaluation of visual pathway dysfunction in diabetics without retinopathy: correlations with diabetic peripheral neuropathy and other clinical findings.

Aim and objectives: Visual dysfunction in diabetes mellitus (DM) is multifactorial and can be due to vascular disease, and metabolic abnormalities that can affect the retina, optic nerve, and visual pathways. Visual evoked potential (VEP) is an electrophysiological test that can quantify the functional integrity of the visual pathways from the retina via the optic nerves, and optic tracts to the visual cortices. In this study, we aimed to investigate the visual pathway dysfunction among diabetics without retinopathy compared with healthy controls and to look for any correlation with diabetic neuropathy, duration of diabetes, or HbA1c level. Methods: The study included 75 diabetic patients and 75 age and sex-matched controls. VEPs were recorded using the pattern reversal stimulation method on the Medtronic EMG EP machine, and P100 latency and N75-P100 amplitude were recorded in both diabetic patients and healthy controls. Results: Mean P100 latency was significantly prolonged and N75-P100 amplitude significantly reduced among diabetic cases compared to healthy controls (p < 0.001). Among diabetics with peripheral neuropathy, P100 latency was significantly prolonged and N75-P100 amplitude was significantly reduced compared to diabetics without peripheral neuropathy. A significant positive correlation of VEP P100 latency (p < 0.001) and a negative correlation with N75-P100 amplitude (p < 0.001) with duration of disease were also found. Conclusion: VEP changes are observed in diabetics before the development of retinopathy or peripheral neuropathy indicating optic pathway dysfunction, which precedes the development of these complications. Early preclinical visual pathway dysfunction can warrant taking the necessary measures to reduce diabetic complications. Abbreviations: DM = Diabetes Mellitus, VEP = Visual Evoked Potential, HbA1c = Hemoglobin A1 c, MRI = Magnetic Resonance Imaging, EEG = Electroencephalography, P100 = Positive wave peak at latency 100 ms (millisecond), N75 = Negative wave peak at latency 75 ms (millisecond), N145 = Negative wave peak at latency 145 ms (millisecond), OCT = Optical coherence tomography, PRVEP = Pattern Reversal Visual Evoked Potential, NCS = Nerve Conduction Study, SSR = Sympathetic Skin Response, IL1 = Interleukin-1, LIF = Leukemia inhibitory factor, CNTF = Ciliary neurotrophic factor, TNF alpha = Tumor necrosis factor-alpha, TGF-beta = Transforming growth factor-beta.

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