Extremely rapid recovery of human cone circulating current at the extinction of bleaching exposures

J. S. Kenkre, N. A. Moran, Trevor D. Lamb*, Omar A.R. Mahroo*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

28 Citations (Scopus)

Abstract

We used a conductive fibre electrode placed in the lower conjunctival sac to record the a-wave of the human photopic electroretinogram elicited by bright white flashes, delivered during, or at different times after, exposure of the eye to bright white illumination that bleached a large fraction (∼90%) of the cone photopigment. During steady-state exposures of this intensity, the amplitude of the bright-flash response declined to ∼50% of its dark-adapted level. After the intense background was turned off, the amplitude of the bright-flash response recovered substantially, for flashes presented within 20 ms of background extinction, and fully, for flashes presented 100 ms after extinction. In addition, a prominent 'background-off a-wave' was observed, beginning within 5-10 ms of background extinction. We interpret these results to show, firstly, that human cones are able to preserve around half of their circulating current during steady-state illumination that bleaches 90% of their pigment and, secondly, that following extinction of such illumination, the cone circulating current is restored within a few tens of milliseconds. This behaviour is in stark contrast to that in human rods, where the circulating current is obliterated by a background that bleaches only a few percent of the pigment, and where full recovery following a large bleach takes at least 20 min, some 50 000 times more slowly than shown here for human cones.

Original languageEnglish
Pages (from-to)95-112
Number of pages18
JournalJournal of Physiology
Volume567
Issue number1
DOIs
Publication statusPublished - 15 Aug 2005

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