视网膜的无创功能成像揭示了视网膜外层和血流动力学内在光学信号的起源。
Noninvasive functional imaging of the retina reveals outer retinal and hemodynamic intrinsic optical signal origins.
作者信息
Ts'o Daniel, Schallek Jesse, Kwon Young, Kardon Randy, Abramoff Michael, Soliz Peter
机构信息
Department of Neurosurgery, SUNY Upstate Medical University, Syracuse, NY 13210, USA.
出版信息
Jpn J Ophthalmol. 2009 Jul;53(4):334-44. doi: 10.1007/s10384-009-0687-2. Epub 2009 Sep 8.
Abstract
We have adapted intrinsic signal optical imaging of neural activity to the noninvasive functional imaging of the retina. Results to date demonstrate the feasibility and potential of this new method of functional assessment of the retina. In response to visual stimuli, we have imaged reflectance changes in the retina that are robust and spatially colocalized to the sites of stimulation. However, the technique is in its infancy and many questions as to the underlying mechanisms remain. In particular, the source and nature of the activity-dependent intrinsic optical signals in the retina need to be characterized and their anatomic origins determined. The studies described here begin to address these issues. The evidence indicates that the imaged signals are driven by the outer retinal layers and have a dominant hemodynamic component.
摘要
我们已将神经活动的内在信号光学成像技术应用于视网膜的无创功能成像。迄今为止的结果证明了这种视网膜功能评估新方法的可行性和潜力。响应视觉刺激时,我们对视网膜中的反射率变化进行了成像,这些变化强烈且在空间上与刺激部位共定位。然而,该技术尚处于起步阶段,关于其潜在机制仍有许多问题。特别是,视网膜中与活动相关的内在光信号的来源和性质需要加以表征,并确定其解剖学起源。此处所述的研究开始着手解决这些问题。证据表明,所成像的信号由视网膜外层驱动,并且具有主要的血液动力学成分。
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