Dark adaptation of human rod bipolar cells measured from the b-wave of the scotopic electroretinogram

Date

2006

Authors

Cameron, Allison
Mahroo, O
Lamb, Trevor

Journal Title

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Volume Title

Publisher

Cambridge University Press

Abstract

To examine the dark adaptation of human rod bipolar cells in vivo, we recorded ganzfeld ERGs to (a) a family of flashes of increasing intensity, (b) dim test flashes presented on a range of background intensities, and (c) dim test flashes presented before, and up to 40 min after, exposure to intense illumination eliciting bleaches from a few per cent to near total. The dim flash ERG was characterized by a prominent b-wave response generated principally by rod bipolar cells. In the presence of background illumination the response reached peak earlier and desensitized according to Weber's Law. Following bleaching exposures, the response was initially greatly desensitized, but thereafter recovered slowly with time. For small bleaches, the desensitization was accompanied by acceleration, in much the same way as for real light. Following a near-total bleach, the response was unrecordable for >10 min, but after ∼23 min half-maximal sensitivity was reached, and full sensitivity was restored between ∼35 and 40 min. With smaller bleaches, recovery commenced earlier. We converted the post-bleach measurements of desensitization into 'equivalent background intensities'using a Crawford transformation. Across the range of bleaching levels, the results were described by a prominent 'S2'component (0.24 decades min-1) together with a smaller and slower 'S3'component (0.06 decades min-1), as is found for dark adaptation of the scotopic visual system. We attribute the S2 component to the presence of unregenerated opsin, and we speculate that the S3 component results from ion channel closure by all- trans retinal. 2006 The Authors. Journal compilation

Description

Keywords

Keywords: ion channel; opsin; retinal; article; B wave; controlled study; dark adaptation; electroretinogram; human; human cell; human experiment; illumination; in vivo study; light intensity; night vision; normal human; photoreceptor; photosensitivity; priority jo

Citation

Source

Journal of Physiology

Type

Journal article

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2037-12-31