<p>Rod photoreceptors are essential for vision under dim light conditions and are highly vulnerable in retinal degenerative diseases. Here, we demonstrate that both human and rodent rods undergo a minute and rapid contraction of their outer segments upon photoisomerization, the first step of phototransduction. The contraction is explained as an electromechanical manifestation of the rod early receptor potential generated in the disk membranes, which is challenging to access in electrophysiology. The in vivo optical imaging of light-evoked electrical activity in rodent rods was facilitated by an ultrahigh-resolution point-scan optical coherence tomography (OCT) system, combined with an unsupervised learning approach to separate the light-evoked response of the rod outer segment tips from the retinal pigment epithelium-Bruch’s membrane complex. In humans, an adaptive optics line-scan OCT facilitated high-speed recordings in rods. The non-invasive in vivo optical imaging of rhodopsin activation extends the diagnostic capability of optoretinography, and may facilitate personalized, objective assessment of rod dysfunction and visual cycle impairment in inherited and age-related macular degeneration.</p>

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Optoretinography reveals rapid rod photoreceptor movement upon rhodopsin activation

  • Huakun Li,
  • Connor E. Weiss,
  • Vimal Prabhu Pandiyan,
  • Davide Nanni,
  • Teng Liu,
  • Pei Wen Kung,
  • Bingyao Tan,
  • Veluchamy Amutha Barathi,
  • Leopold Schmetterer,
  • Ramkumar Sabesan,
  • Tong Ling

摘要

Rod photoreceptors are essential for vision under dim light conditions and are highly vulnerable in retinal degenerative diseases. Here, we demonstrate that both human and rodent rods undergo a minute and rapid contraction of their outer segments upon photoisomerization, the first step of phototransduction. The contraction is explained as an electromechanical manifestation of the rod early receptor potential generated in the disk membranes, which is challenging to access in electrophysiology. The in vivo optical imaging of light-evoked electrical activity in rodent rods was facilitated by an ultrahigh-resolution point-scan optical coherence tomography (OCT) system, combined with an unsupervised learning approach to separate the light-evoked response of the rod outer segment tips from the retinal pigment epithelium-Bruch’s membrane complex. In humans, an adaptive optics line-scan OCT facilitated high-speed recordings in rods. The non-invasive in vivo optical imaging of rhodopsin activation extends the diagnostic capability of optoretinography, and may facilitate personalized, objective assessment of rod dysfunction and visual cycle impairment in inherited and age-related macular degeneration.