Membrane voltage was recorded in rod photoreceptors in retina isolated from macaque monkey. The size of the single photon response and the magnitude of membrane voltage fluctuations were assessed in dark- and light-adapted retina. The “dark light” rate ID, defined as the rate of spontaneous photopigment isomerizations that would produce a variance equivalent to that of the noise measured in the dark, was calculated after matched filtering. The average value of 0.08 s−1 fell at the higher end of psychophysical estimates of dark light in human observers. In light-adapted rods the photon response decreased in amplitude and duration, and the magnitude of the voltage fluctuations increased with increasing background light intensity. The signal-to-noise ratio (SNR) for single rods was defined as the ratio of the peak amplitude of the photon response to the standard deviation of the noise fluctuations. The signal-to-noise ratio for dark-adapted rods SNRD was about 7. With increasing background intensity I, the SNR fell as SNRD(1 + I/ID)−1/2. This function may account for the increment thresholds measured with small brief test flashes in human psychophysical experiments.

Recovery from bright light was studied in macaque rods by measuring the membrane current of single outer segments. The recovery phase of some responses displayed a plateau current of about one picoampere lasting for several seconds. The following evidence suggests these “steps” are single photon responses of abnormally long duration. (1) Over a limited range of intensities, step amplitude remained constant and summed linearly with intensity. The collecting area for step generation was about 2.6 × 10−3 μm2. (2) Step duration varied exponentially with a mean duration of about 6.5 s. (3) Fluctuation analysis of the tail currents was consistent with the idea that a step is evoked by isomerization of a single rhodopsin molecule, and that only 1 in 400 isomerizations leads to a response with a step-like waveform. (4) With only the distal portion of the outer segment in the electrode, the polarity of the step response reversed when the proximal portion of the outer segment was illuminated, indicating that step generation results from a local change in outer segment conductance near the site of photon absorption. (5) The probability of eliciting a step varied with the wavelength of light in the manner expected from the absorption spectrum of rhodopsin.