Contribution of the maculo-ocular reflex to gaze stability in the rabbit.

The contribution of the maculo-ocular reflex to gaze stability was studied in 10 pigmented rabbits by rolling the animals at various angles of sagittal inclination of the rotation and/or longitudinal animal axes. At low frequencies (0.005-0.01 Hz) of sinusoidal stimulation the vestibulo-ocular reflex (VOR) was due to macular activation, while at intermediate and high frequencies it was mainly due to ampullar activation. The following results were obtained: 1) maculo-ocular reflex gain decreased as a function of the cosine of the angle between the rotation axis and the earth's horizontal plane. No change in gain was observed when longitudinal animal axis alone was inclined. 2) At 0-degrees of rotation axis and with the animal's longitudinal axis inclination also set at 0-degrees, the maculo-ocular reflex was oriented about 20-degrees forward and upward with respect to the earth's vertical axis. This orientation remained constant with sagittal inclinations of the rotation and/or longitudinal animal axes ranging from approximately 5-degrees upward to 30-degrees downward. When the longitudinal animal axis was inclined beyond these limits, the eye trajectory tended to follow the axis inclination. In the upside down position, the maculo-ocular reflex was anticompensatory, oblique and fixed with respect to orbital coordinates. 3) Ampullo-ocular reflex gain did not change with inclinations of the rotation and/or longitudinal animal axes. The ocular responses were consistently oriented to the stimulus plane. At intermediate frequencies the eye movement trajectory was elliptic because of directional differences between the ampullo- and maculo-ocular reflexes. 4) In the upright position the coactivation of the optokinetic reflex (OKR) eliminated the eye disalignment with respect to the stimulus plane and the elliptic trajectory. 5) Combined vertical OKR and VOR gain in the prone position (VOKR + VVOR 0-degrees) was higher than that of the combined VOKR + VVOR in the 90-degrees nose up position. The VVOR + VOKR 90-degrees gain was in turn higher than the VVOR + VOKR gain in the 180-degrees upside down position. 6) We suggest that, in the dark, the maculo-ocular response tends to reduce the disalignment of both eyes with respect to the horizon rather than inducing oculocompensatory responses. In the light, this maculo-ocular reflex increases the gain of combined optokinetic and vestibular responses.