偏头痛患者马格诺细胞、细小细胞和konio细胞视觉流失调的层次性心理生理评估

IF 3.1 Q1 OPHTHALMOLOGY

Eye and Brain Pub Date : 2019-11-01 DOI:10.2147/EB.S225171

M. F. Wesner, James N. R. Brazeau

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引用次数: 2

摘要

虽然在偏头痛中已经注意到有意识的图像形成幻觉，但很少有研究专门寻求集体评估所有三个平行的视觉处理流在涉及图像形成视觉的视网膜生成纹状体通路中的作用及其在偏头痛症状发展中的意义。方法:我们从心理物理上评估了三个临床组在不同层次位点推断的大细胞(MC)、小细胞(PC)和小细胞(KC)流的功能:经历先兆偏头痛的个体(MA;n=13)，无先兆偏头痛(MWO;n=14)和对照组(n=15)。参与者完成了四个实验:实验1旨在评估视网膜短波长敏感(S-)锥体的灵敏度;实验2旨在测量拉伸后的时间和空间色彩对比敏感度;实验3旨在评估拉伸后时空消色差对比敏感度;实验4旨在测量沿三个锥体激励轴的丘脑皮质颜色辨别。结果与MWO受试者相比，MA组出现s -锥体缺损，受影响的视网膜区域更大。四个实验的结果表明，在MA中有一个突出的视网膜功能障碍位点(在MWO中较少)，在KC视觉流中发生潜在的前馈补偿。结论在考虑偏头痛沿视觉通路的失调影响时，需要考虑复杂的、综合的网络代偿。

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The Psychophysical Assessment of Hierarchical Magno-, Parvo- and Konio-Cellular Visual Stream Dysregulations in Migraineurs

Introduction Although conscious, image-forming illusions have been noted in migraine, few studies have specifically sought to collectively evaluate the role of all three parallel visual processing streams in the retinogeniculostriate pathway involved with image-forming vision and their implications in the development of migraine symptoms. Methods We psychophysically assessed the functionality of the inferred magnocellular (MC), parvocellular (PC), and koniocellular (KC) streams at different hierarchical loci across three clinical groups: individuals who experience migraine with aura (MA; n=13), experience migraine without aura (MWO; n=14), and Controls (n=15). Participants completed four experiments: Experiment 1 designed to assess retinal short-wavelength-sensitive (S-) cone sensitivities; Experiment 2 intended to measure postretinal temporal and spatiochromatic contrast sensitivities; Experiment 3 intended to assess postretinal spatiotemporal achromatic contrast sensitivities; and Experiment 4 designed to measure thalamocortical color discriminations along the three cone-excitation axes. Results S-cone deficits were revealed with greater retinal areas being affected in MA compared to MWO participants. Findings across the four experiments suggest a prominent retinal locus of dysfunction in MA (lesser in MWO) with potential feedforward compensations occurring within the KC visual stream. Conclusion Complex, integrative network compensations need to be factored in when considering the dysregulating influences of migraine along the visual pathway.

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来源期刊

Eye and Brain OPHTHALMOLOGY-

CiteScore

7.90

自引率

2.30%

发文量

审稿时长

16 weeks

期刊介绍： Eye and Brain is an international, peer-reviewed, open access journal focusing on basic research, clinical findings, and expert reviews in the field of visual science and neuro-ophthalmology. The journal’s unique focus is the link between two well-known visual centres, the eye and the brain, with an emphasis on the importance of such connections. All aspects of clinical and especially basic research on the visual system are addressed within the journal as well as significant future directions in vision research and therapeutic measures. This unique journal focuses on neurological aspects of vision – both physiological and pathological. The scope of the journal spans from the cornea to the associational visual cortex and all the visual centers in between. Topics range from basic biological mechanisms to therapeutic treatment, from simple organisms to humans, and utilizing techniques from molecular biology to behavior. The journal especially welcomes primary research articles or review papers that make the connection between the eye and the brain. Specific areas covered in the journal include: Physiology and pathophysiology of visual centers, Eye movement disorders and strabismus, Cellular, biochemical, and molecular features of the visual system, Structural and functional organization of the eye and of the visual cortex, Metabolic demands of the visual system, Diseases and disorders with neuro-ophthalmic manifestations, Clinical and experimental neuro-ophthalmology and visual system pathologies, Epidemiological studies.