Reverse optokinetic after-nystagmus generated by gaze fixation during optokinetic stimulation

Gaze fixation during optokinetic stimulation generates an after-nystagmus with a slow component towards the reverse direction of the optokinetic stimulation. The duration and maximum slow component velocity (SCV) of this "reverse OKAN" were observed by changing the duration, velocity and direction of the optokinetic stimulation in nine normal volunteers. The duration of reverse OKAN increased with increasing stimulation time but was unaffected by changes in the stimulation velocity. The maximum SCV of reverse OKAN decreased with an increase in the stimulation velocity but was not significantly affected by changes in the optokinetic stimulation time. There was no directional difference among the horizontal, upwards and downwards reverse OKANs. The reverse OKAN was thought to be generated by a mechanism different from the velocity storage mechanism which produced optokinetic nystagmus and the first phase of OKAN. Retinal slip during the optokinetic stimulation was considered to be an input to the mechanism which generated the reverse OKAN. We hypothesize that the mechanism causing the reverse OKAN may be a generator of the second phase of OKAN, which was also intimately connected with self-motion sensation during the optokinetic stimulation.     

Optokinetic afternystagmus in humans: normal values of amplitude, time constant, and asymmetry

It has been suggested that the appearance of directional asymmetry and/or a reduced time constant of optokinetic afternystagmus (OKAN) might be a clinical index of vestibular imbalance. However, we do not know the limits for OKAN parameters in normal humans. Accordingly, we studied OKAN in 30 normal subjects using a "sampling" method, in which a number of values of OKAN are obtained by turning out the lights periodically during optokinetic stimulation. We found that the initial velocity of OKAN has a large intrasubject variability. Accordingly, if precision is desired so as to obtain 95% confidence that the measured mean of the initial velocity of OKAN is within 25% of the true mean in an individual subject, at least eight measurements of the initial OKAN velocity must be taken. When 12 measurements are made, all subjects had a minimum value of 5 degrees/s initial OKAN, and there was little directional asymmetry (mean of -0.47 degree/s +/- 3.13 degrees/s). The intrasubject variability of the time constant of OKAN was similar to the variability of initial OKAN velocity. However, because it is not possible to obtain repeated measures of the time constant in a short period of time, the time constant of OKAN is less likely to be useful in clinical testing.     

Cross-coupling between horizontal and vertical eye movements during optokinetic nystagmus and optokinetic afternystagmus elicited in microgravity

The occurrence of horizontal jerks with larger amplitudes than on Earth was observed during vertical optokinetic nystagmus in astronauts tested throughout a 7-day spaceflight. During early exposure to microgravity, a horizontal spontaneous-like nystagmus was recorded in darkness following both vertical and horizontal optokinetic stimulation. In addition, the time constant of vertical OKAN with slow phase up was larger than on the ground. These effects disappeared on flight day 2. Then, the horizontal and vertical OKAN time constants decreased, and gradually returned to the preflight values, as previously observed with the gain of the vestibulo-ocular reflex. The early changes in microgravity are in agreement with those obtained on Earth in monkeys and humans during static tilt relative to gravity. Our findings suggest that the absence of otolithic input in microgravity may have an effect on the optokinetic system which could be mediated by the velocity storage mechanism.     

The effects of intense click sounds on velocity storage in optokinetic after-nystagmus

Vestibular evoked myogenic potentials (VEMP) occurring after click stimulation in cervical muscles are thought to be a polysynaptic response of otolith-vestibular nerve origin. In optokinetic after-nystagmus (OKAN) the direction of after-nystagmus changes and slow-phase velocity decreases with head tilt. This phenomenon may be an otolith response to the direction of gravity. We assumed that intense clicks might have some influence on OKAN via the otolith-vestibular nerve. Twelve normal subjects who showed VEMP at 75 dB normal hearing level (nHL) clicks were examined. The OKAN was recorded under four conditions: right monaural, left monaural and binaural stimulation by 75 dB nHL clicks, and absence of click stimulation. Horizontal optokinetic stimulation was applied using stepwise increasing speeds from 30 deg/s to 90 deg/s. Two seconds before the stimulus ended, clicks were sounded. The slow-phase velocity of the recorded electro-nystagmography was manually measured. There was no effect on OKAN with unilateral stimulation but binaural stimulation suppressed it. These results suggest that a velocity storage integrator is influenced by intense clicks via the otolithic area. Received: 17 November 1999 / Accepted: 30 May 2000     

Galvanically induced asymmetric optokinetic after-nystagmus

The effect of an asymmetric vestibular input on the symmetry of horizontal optokinetic after-nystagmus (OKAN) was studied in twenty healthy subjects. Optokinetic nystagmus (OKN) was elicited by a whole-field optokinetic drug, rotating at 90 degrees/s, and eye-movements were recorded by a DC electro-oculographic technique (EOG). The ratio of OKAN following right and left-beating OKN respectively was computed. An asymmetric vestibular input was generated by a continuous bi-polar, bi-aural galvanic stimulus (1 mA) to the vestibular nerves during the optokinetic stimulation and the recording of the OKAN. During galvanic stimulation the relation between left and right-beating OKAN was asymmetric, compared with the OKAN found after optokinetic stimulation only. The galvanic stimulus caused a preponderance for OKAN with the fast phase beating toward the cathode. Thus, the small vestibular asymmetry induced by the galvanic stimulus, which was not strong enough to produce nystagmus by itself, caused an asymmetric OKAN. These findings suggest that examination of OKAN may be of value to detect small vestibular asymmetries in peripheral vestibular disorders in man.     

Human optokinetic afternystagmus. Slow-phase characteristics and analysis of the decay of slow-phase velocity

Events following the extinction of lights after 1-minute exposures of naive, normal subjects to an optokinetic stimulus at 40 deg/sec have been closely examined and quantified. Mean eye displacement in each slow phase decreased from 10.12 +/- 1.61 deg during optokinetic nystagmus (OKN) to 3.36 +/- 2.32 deg during optokinetic afternystagmus (OKAN). Slow-phase duration increased from 0.26 +/- 0.03 sec during OKN to 0.45 +/- 0.195 sec during OKAN. Eye displacement per slow phase remained fairly constant during OKAN, suggesting a spatial reference for the resetting of gaze. OKAN decay is a two-component process which can be closely approximated by a sum of two exponentials, one with a short time constant of 1.15 sec and the other with a long time constant of 48.8 sec. OKAN decay commenced at a time after lights out which depended upon the presence and timing of an intervening fast phase. When a fast phase intervened, OKAN decay commenced about 230 msec after it, and about 460 msec after lights out. When lights out occurred during the fast phase, OKAN decay commenced about 340 msec later.     

Optokinetic nystagmus and after-nystagmus during a 6 hour bedrest study

CONCLUSIONS: A lengthy alteration of gravity direction produced different effects on the intrinsic horizontal and vertical optokinetic oculomotor systems. OBJECTIVE: To examine both optokinetic nystagmus (OKN) and optokinetic after-nystagmus (OKAN) in a 6 h 6 degrees head-down bedrest study, in which the subjects were kept lying under simulated micro-gravity conditions. SUBJECTS AND METHODS: In six normal healthy adults, we repeatedly (five times) and comparatively studied OKN and OKAN evoked by horizontal and vertical stimuli. Stage 1 was an upright sitting position. During the 6 h bedrest condition, we studied OKN and OKAN in 90 degrees recumbent lateral positions (stages 2, 3, and 4). In stage 5 the subject returned to an upright position. RESULTS: We confirmed that the change in gravity direction had various effects on the condition of OKN and OKAN. Also, we found that it took more than 3 h to reach a desirable level of systemic adaptive modification to the unique environmental condition. We considered that the early change was basically due to the changes in sensory inputs through the otolith organs, and the latter changes represented the adaptive process of the spatial orientation system. During the tilt, the occurrence rates of both horizontal and vertical OKANs were decreased; however, the conditions of these changes were different.     

Effect of alertness and visual attention on optokinetic nystagmus in humans

The effect of alertness and visual attention on optokinetic nystagmus (OKN) and optokinetic after-nystagmus (OKAN) was studied in 20 volunteers. Electroencephalographic (EEG) activity was recorded over the occipital lobe. Exposure to sound and vibration caused a significant increase in the mean slow-phase velocity of OKN, whereas its maximum slow-phase velocity remained unaffected. Vibration tended to increase the mean slow-phase velocity of OKN more than sound did, though the difference was not statistically significant. Vibration also significantly increased the OKAN. When alpha rhythm appeared in the occipital EEG during OKN, the velocity of concurrent slow phases was reduced. However, the periods of alpha rhythm did not differ between the different stimulus conditions. The findings suggest that sound and vibration activate the subcortical optokinetic mechanism, thus causing an increase in the mean velocity of OKN. Abatement of visual attention is reflected in temporary reduction of OKN in conjunction with the appearance of alpha waves and is to be interpreted as transient quiescence of the cortical optokinetic mechanism.     

Optokinetic nystagmus and after-nystagmus during a 6 hour bedrest study

Conclusions. A lengthy alteration of gravity direction produced different effects on the intrinsic horizontal and vertical optokinetic oculomotor systems. Objective. To examine both optokinetic nystagmus (OKN) and optokinetic after-nystagmus (OKAN) in a 6 h 6° head-down bedrest study, in which the subjects were kept lying under simulated micro-gravity conditions. Subjects and methods. In six normal healthy adults, we repeatedly (five times) and comparatively studied OKN and OKAN evoked by horizontal and vertical stimuli. Stage 1 was an upright sitting position. During the 6 h bedrest condition, we studied OKN and OKAN in 90° recumbent lateral positions (stages 2, 3, and 4). In stage 5 the subject returned to an upright position. Results. We confirmed that the change in gravity direction had various effects on the condition of OKN and OKAN. Also, we found that it took more than 3 h to reach a desirable level of systemic adaptive modification to the unique environmental condition. We considered that the early change was basically due to the changes in sensory inputs through the otolith organs, and the latter changes represented the adaptive process of the spatial orientation system. During the tilt, the occurrence rates of both horizontal and vertical OKANs were decreased; however, the conditions of these changes were different.     

Human optokinetic afternystagmus. Charging characteristics and stimulus exposure time dependence in the two-component model

The dependence of human optokinetic afternystagmus (OKAN) velocity storage (charging) and optokinetic nystagmus (OKN) characteristics on optokinetic (OK) stimulus exposure time was investigated, using the two-component double exponential model for OKAN decay. Results are compatible with our previously proposed concept of two velocity storage integrators, one responsible for the short time constant decay (pursuit-mediated) and the other for the long time constant decay (OK system-mediated). The dependence of the long time constant integrator of OKAN on stimulus exposure time was clearly demonstrated. The short time constant integrator appeared to be independent of stimulus exposure time within the range studied. We conclude that the charging time-course of each component is distinct from that of the other. The time constants of each component decay were found to be invariant. A left-right asymmetry observed in both OKN and OKAN responses suggests that the integrators are direction sensitive.     

Slow cumulative eye position to quantify optokinetic afternystagmus.

In 30 normal subjects we computed the slow cumulative eye position (SCEP) of optokinetic afternystagmus (OKAN) that followed 60 seconds of full-field optokinetic stimulation at 60 degrees/s. The mean SCEP was 112.8 degrees +/- 65.0 degrees. The lower and upper fifth percentile limits for directional preponderance of the SCEP were -38.8% and 44.3%, respectively. The time constant, which we calculated by dividing the SCEP by the initial velocity, was 12.0 +/- 7.4 seconds. This value is nearly identical to the time constant obtained from semilogarithmic regression of the decay of OKAN slow-phase velocity versus time. We conclude that the SCEP is a good measure of OKAN and that it reflects the substantial amount of variability and directional asymmetry observed in the optokinetic responses of normal subjects.     

The velocity storage mechanism in human optokinetic nystagmus

The velocity storage mechanism was studied in 12 normal human subjects. For optokinetic stimulation, we principally used step stimuli of 80 deg/sec generated by an Ohm type optokinetic stimulation drum. The charge characteristics of the velocity storage mechanism in the human optokinetic nystagmus were closely approximated by the first-degree delay formula having an average time constant of 26.1 sec. This value was much longer than that reported in other animals. The OKN slow phase eye velocity reached nearly 100% of the stimulus velocity immediately after the onset of stimuli. Then, the velocity gradually decreased during first 30 seconds to approximately 70% of the stimulus velocity, and it increased again to velocity the initial during the next 50-60 seconds of the continuous stimuli. These findings, indicating the characteristics specific in the human OKN may be related to the long time constant in the charge characteristics in human OKN as compared to other animals.     

The effect of saccular ablation on vertical optokinetic after-nystagmus in squirrel monkeys

Summary The effect of bilateral saccular ablation on the asymmetry of vertical optokinetic after-nystagmus (OKAN) was studied in squirrel monkeys. No significant changes occurred in the initial slow-phase eye velocity (SPEV) or the time constant of the upward or downward OKAN first phase (OKAN-I) under various stimulus conditions. However, with a protracted downward stimulus, the maximum SPEV and the number of beats of the slow-phase-up OKAN second phase (OKAN-II) significantly increased. This increase should be the result from enhancement of the downward optokinetic input. In contrast, there was only minimal change in the slow-phase-down OKAN-II. Thus, the asymmetrical dominance of the vertical OKAN (dominance upward) remained the same after saccular deafferentation. Offprint request to: M. Igarashi     

Effects of static orientation upon human optokinetic afternystagmus

"Normal" human subjects were placed in a series of 5 static orientations with respect to gravity and were asked to view an optokinetic display moving at a constant angular velocity. The axis of rotation coincided with the subject's rostro-caudal axis and produced horizontal optokinetic nystagmus and afternystagmus. Wall (1) previously reported that these optokinetic afternystagmus responses were not well characterized by parametric fits to slow component velocity. The response for nose-up, however, was larger than for nose-down. This suggested that the horizontal eye movements measured during optokinetic stimulation might include an induced linear VOR component as presented in the body of this paper. To investigate this hypothesis, another analysis of these data has been made using cumulative slow component eye position. Some subjects' responses had reversals in afternystagmus direction. These reversals were "filled in" by a zero slow component velocity. This method of analysis gives a much more consistent result across subjects and shows that, on average, responses from the nose-down horizontal (prone) orientation are greatly reduced (p < 0.05) compared to other horizontal and vertical orientations. Average responses are compared to responses predicted by a model previously used to predict successfully the responses to post-rotatory nystagmus after earth horizontal axis rotation. Ten of 11 subjects had larger responses in their supine than their prone orientation. Application of horizontal axis optokinetic afternystagmus for clinical otolith function testing, and implications for altered gravity experiments are discussed.     

Effects of prolonged optokinetic stimulation on oculomotor and locomotor balance functions

Squirrel monkeys were exposed to optokinetic stimulus (90 degrees/sec constant speed, unidirectional) for 60 min. Eye movements during and after the stimulus exposure were recorded. Comparison of the data between very early and late stages of exposure showed the oculomotor gain increase and the nystagmic frequency decline. Slow phase eye velocity of bilaterally labyrinthectomized squirrel monkeys in the late exposure stage could reach almost to the level of normal animals. Post-stimulus analysis in normal monkeys showed that amphetamine enhanced the optokinetic after-nystagmus duration, the maximum slow phase eye velocity, and the time constant. In contrast, the effect of amphetamine on reversed optokinetic after-nystagmus was not at the significant level in all parameters studied. The manifestation of directional reciprocity of optokinetic after-nystagmus was inconsistent. In bilaterally labyrinthectomized animals, ipsilateral optokinetic after-nystagmus did not appear after the stimulus cessation. Instead, immediate reversed optokinetic after-nystagmus appeared. When the normal animal was kept in the light after the stimulus cessation, slow phase eye velocity of reversed optokinetic after-nystagmus declined relatively rapidly. Reversed optokinetic after-nystagmus and vestibular evoked nystagmus were summated or deducted, in velocity domain, depending upon the direction. Optokinetically induced system imbalance did not depict when the monkey's spinal locomotor function was measured by the platform runway test with the availability of vision.     

Visual-vestibular interaction in humans during earth-horizontal axis rotation

Visual-vestibular interaction (VVI) using 60 degrees/s constant velocity earth horizontal axis (EHA) yaw rotation was measured in 7 human subjects. This so-called 'barbecue spit' rotation stimulated both the horizontal semicircular canals and the otolith organs. Subjects were tested with their eyes open in the dark (EOD), while fixating upon a target rotating with them (FIX), and while observing stationary optokinetic stripes (VVR). The resulting nystagmus slow component velocity (SCV) was analyzed. During EOD, subjects showed an exponentially decaying SCV response with a time constant of between 10 and 15 s that decayed to a non-zero baseline value (bias). Superimposed was a cyclic activity, modulation, whose period equalled the time for a complete revolution of the subject. During FIX, the average value of SCV was nearly zero indicating almost complete abolition of the exponential decay and bias components. The modulation component was reduced by half. During VVR, an exponential decay was observed in most subjects and the average value of the bias component nearly equalled that of the velocity of rotation. Modulation during VVR varied on a cycle-by-cycle basis. On average, the modulation component was nearly twice that for the EOD condition. We conclude that visual-vestibular interactions during EHA differ significantly from those during rotation about the vertical; specifically, there is a non-linear interaction between linear acceleration and optokinetic nystagmus.     

Asymmetry of vertical optokinetic after-nystagmus in squirrel monkeys

Asymmetry of vertical optokinetic after-nystagmus (OKAN) was studied in 6 squirrel monkeys. The slow-phase eye velocity (SPEV) of upward OKAN first-phase (OKAN-I) increased with increasing stimulus velocity, whereas the SPEV of downward OKAN-I diminished. The time constant of OKAN-I was shortened with the increase in stimulus speed in both directions. With a downward stimulus, the short stimulus duration failed to produce OKAN second-phase (OKAN-II) (upward slow-phase); however, with an increase in stimulus duration, the percentage appearance increased. There was no change in percentage appearance, regardless of the duration of upward stimulus. The asymmetry of OKAN-I and that of OKAN-II differed to a certain degree.     

Suppression of optokinetic velocity storage in humans by static tilt in pitch.

The effects of static tilts about the pitch axis on human horizontal optokinetic after-nystagmus OKAN (HOKAN) were examined. Static tilts in pitch produced tilt-dependent HOKAN suppression. The slow decay (indirect pathway) component (coefficient C and long time constant 1/D) of the two-component model for OKAN was significantly reduced, while the short decay (direct pathway) component (coefficient A and short time constant 1/B) remained invariant as angle of tilt was increased. These results provide further evidence that otolith organ activity can couple to horizontal velocity storage in humans, in accordance with models proposed in the literature.     

Effect of body positions in human optokinetic nystagmus and optokinetic after nystagmus

We determined whether whole body tilt would shift the axis of optokinetic nystagmus (OKN) and optokinetic-after nystagmus (OKAN) induced by full-field rotation at 35 degrees/sec. Fifteen normal people were positioned upright or tilted 30 degrees, 60 degrees or 90 degrees to both sides. Stripes of 5 degrees were projected on a 10-foot dome around the subject's yaw axis. Each trial lasted 45 sec. The lights were then extinguished, and the subject remained in darkness for 30 sec, while after nystagmus (OKAN) was recorded. Horizontal and vertical eye movements were recorded by video-oculography at 60 Hz. Eye position and velocity data were stored on optic disk cartridge by use of the data acquisition system. A. OKAN: For the subject in the upright position, the OKN velocity vector was aligned with both gravity and the subject's yaw axis with two minor exceptions. When the subject was tilted, a vertical OKN component (VOKN) appeared in a majority of subjects. For all 15 subjects, the mean angle of the OKN velocity vector regravity (Vectorg) was 22.6 +/- 7.2 degrees at 30 degrees tilted position. The Vectorg were 48.5 +/- 10.3 degrees at 60 degrees tilted position, and 76.4 +/- 12.6 degrees at 90 degrees tilted position. This represented shifts of the OKN velocity vector from the body axis of 7.4 degrees, 11.5 degrees and 13.6 degrees, respectively. The horizontal OKN (HOKN) gain remained unchanged in different positions. B. OKAN: The duration of HOKAN and initial slow phase velocity (SPV) of HOKAN decreased as the body position increased from upright to 30 degrees, 60 degrees and 90 degrees tilted position, respectively. The incidence and initial SPV of VOKAN and Re-Body did not change as the body position increased from upright to 30 degrees, 60 degrees and 90 degrees tilted position, respectively. Thus, VOKN was observed during HOKN as subjects were tilted and tended to vector to gravity, but VOKAN was not always observed during horizontal OKAN when subjects were tilted.     

Asymmetric optokinetic afterresponse in patients with small acoustic neurinomas.

Directional asymmetry of primary and secondary optokinetic afternystagmus (OKAN I and OKAN II, respectively) was studied in 20 patients with small acoustic neurinomas (< or = 20 mm), and results were compared to those for 24 normal controls. The optokinetic afterresponse was induced by 60 s of horizontal whole-field optokinetic stimulation in both directions. Among patients, the optokinetic afterresponse was asymmetric, OKAN I and OKAN II beating toward the lesioned ear being significantly weaker than the OKAN I and OKAN II beating toward the healthy ear. Hence, in these patients with gradual deterioration of vestibular function, the vestibular side-difference was reflected both in OKAN I and OKAN II. Although asymmetry in OKAN I was frequently observed among controls, it was significantly more pronounced among the patients. Moreover, patients could be distinguished by the occurrence of OKAN II, as it did not occur at all among controls exposed to the same stimulation.