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.     

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.     

Quantitative analysis of horizontal and vertical optokinetic nystagmus and optokinetic after-nystagmus in the cat

This study reported on the horizontal optokinetic nystagmus (OKN) and vertical OKN of cats under the same conditions with quantitative parameters. Using the search coil method, the horizontal and vertical OKN was investigated in 5 alert cats in an upright position. As the optokinetic stimulus, a stepped random dot pattern was used. We recorded the quantitative parameters in both the horizontal and vertical OKN (for the direct pathway parameters, initial fast rise and fast fall; for the indirect pathway parameters, steady state slow phase velocity [SPV] and the optokinetic after-nystagmus [OKAN] area) in cats. The SPV of the horizontal OKN increased with the stimulus amplitude up to 40-60 degrees/s but saturated thereafter (in some cats even more). Right and left OKN were almost symmetrical. The SPV of the downward OKN increased with the stimulus amplitude up to 20 degrees/s but saturated thereafter. This was lower than the horizontal OKN. On the other hand, the SPV of the upward OKN was weak and irregular. As for the OKAN, the right and left OKAN was also almost symmetrical. A downward OKAN was also observed but was weaker than the horizontal OKAN. A fast fall in the SPV of the OKAN was observed in the horizontal and downward OKN. On the other hand, there was little upward OKAN. OKN in cats was composed of both a direct pathway and an indirect pathway. This study suggested that directional differences of OKN were mainly responsible for the indirect pathway. Both the direct and indirect pathways of cats were smaller than those of monkeys. This suggested that the differences in OKN between cats and monkeys were mainly responsible for the direct pathway.     

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.     

Comparison of vertical and horizontal optokinetic nystagmus in the squirrel monkey.

Horizontal and vertical optokinetic nystagmus (OKN) and optokinetic after-nystagmus (OKAN) of squirrel monkeys were compared with those of rabbits, cats and humans that were previously described. Squirrel monkeys showed similar findings to cats, in which vertical optokinetic nystagmus (VOKN) is not as well elicited as horizontal optokinetic nystagmus (HOKN) and down-pursuit OKN is poorer than up-pursuit OKN. As to the reasons that bring about different responses of OKN and OKAN (and vestibular nystagmus) in different planes, we speculated two possibilities: compensatory activation of horizontal eye movement for narrowed visual field accompanied by frontally positioned eyes, and the gravity that restricts and modifies posture and locomotion. Directional difference of VOKN may be caused by a physiological mechanism that makes visual fixation not susceptible to downward movement of the ground surface during forward locomotion.     

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.     

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.     

Transfer of optokinetic activity to vestibular nystagmus

Transfer of activity generated by prior optokinetic (OK) stimuli of one minute's duration to nystagmus induced in darkness by a subsequent vestibular stimulus consisting of step velocities to and from 40 degrees/s-1 was studied in 10 normal subjects. Four types of OK stimuli were used: (a) full field 'passive'; (b) full field 'active'; (c) full field in the presence of optic fixation, and (d) small OK drum stimulation. Transfer (T) was evident under all conditions and resulted in an enhancement of the vestibulo-ocular (VO) response when activity from the two stimuli were in the same direction (S) and a suppression when in the opposite (O). Expressed by the equation: Formula See Text. the respective transfer values obtained for the above conditions were (a) 66%, (b) 58%, (c) 22%, and (d) 54%. In all tests, rightward OK drum movement was more effective than leftward. In respect of passive OKN the resultant response can be well represented as the algebraic summation of the expected optokinetic after-nystagmus (OKAN) and the VO response, though opposing OKAN is more effective than enhancing. Passive OKN is more effective than active and this can be accounted for by the small contribution made by retinal slip in the former (the indirect path). Surprisingly, the small drum proved almost as effective as active OKN in terms of transfer. Fixation in the presence of full-field OK stimuli induces a non-directionally specific depression of the subsequent VO response, implying that retinal slip could contribute to the mechanism of VO response suppression.     

Effects on the optokinetic system of midline lesions in the pretectum of monkeys

The nucleus of the optic tract (NOT), an important visuo-motor relay between the retina and preoculomotor structures, is responsible for mediating horizontal optokinetic nystagmus (OKN) in monkeys, cats, rabbits and rats. In addition to its projection to the vestibular nuclei, the NOT has a prominent projection to the contralateral NOT via the posterior commissure. In order to evaluate the role of the commissural fibers between the NOTs in OKN, we cut the posterior commissure in three Macaca fuscata. The animals viewed the OKN stripes under three conditions: right eye viewing, left eye viewing, and both eyes viewing. OKN was recorded in response to counter-clockwise and clockwise stimulation at stimulus velocities of 30 degrees/s, 60 degrees/s and 90 degrees/s. After control data were gathered, the posterior commissure was transected with an operating knife. Before the animal was sacrificed, biocytin, an anterograde tracer, was injected into the left NOT in order to confirm that all of the commissural fibers had been cut. Although the midline lesions decreased the initial rapid rise and steady state OKN slow-phase velocity in all three animals, there were no directional differences observed during monocular clockwise or counter-clockwise visual stimulation to either eye. In two of the three animals, there were no significant differences in the time-constants of optokinetic after nystagmus (OKAN) after the lesion. In the remaining animal, the time-constants decreased at stimulus velocities of 30 degrees/s and 60 degrees/s. In conclusion, gain reduction in the rapid rise and steady state slow-phase velocity of OKN can be explained by removal of an excitatory signal mediated by commissural fibers to inhibitory interneurons in the contralateral NOT. However, interrupting the commissural fibers had no effect on the velocity storage mechanism, because the time-constants of OKAN mostly remained largely unchanged by the lesion.     

Effect of vestibulo-cerebellar lesions on asymmetry of vertical optokinetic functions in the squirrel monkey

The role of the cerebellar uvula and nodulus in vertical optokinetic after-nystagmus (OKAN) was studied in 4 squirrel monkeys. Aspiration ablation of the uvula and nodulus resulted in no significant change in the initial or peak gain of vertical optokinetic nystagmus (OKN) during the 24-week post-operative observation. However, the asymmetry of vertical OKAN was significantly altered. Using a protracted upward OK stimulus, slow phase-down OKAN-II, which was not seen pre-operatively, was significantly increased. In contrast, a downward OK stimulus produced little change in slow phase-up OKAN-II. Thus, the asymmetric degree of vertical OKAN-II was decreased after uvulonodulectomy. In addition, there was a post-operative reduction in the vertical oculomotor stability. When slow-phase eye velocity of OKAN was plotted along the time scale, the amplitude and frequency of the sinusoidal pattern was increased. OKAN-III and OKAN-IV were found in 50% of the monkeys after uvulonodulectomy. It is therefore thought that inhibition and directional control from the uvula and nodulus influence the stability and asymmetrical behaviour of the leaky integrator in the second order output system.     

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.     

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     

Human optokinetic afternystagmus. Stimulus velocity dependence of the two-component decay model and involvement of pursuit

The dependence of human OKAN characteristics on optokinetic (OK) stimulus velocity was examined using the two-component double exponential model for OKAN decay. Drum velocities studied were between 10 degrees and 70 degrees deg/sec over a constant exposure period of 60 sec. Results reveal two distinct types of response: a 'low'-level response at lower drum velocities (10 degrees, 20 degrees, 30 degrees/sec) and a 'high'-level response at higher drum velocities (40 degrees, 60 degrees, 70 degrees /sec). These findings support our previous proposal that OKAN decay is a two-component process, and extend it by demonstrating that these two components have differing stimulus velocity sensitivities, as would be predicted if it were assumed that they represented direct (pursuit) and indirect (non-pursuit) pathways respectively.     

The significance of the target frequency and the target speed in optokinetic nystagmus (OKN).

The significance of the frequency of the stimuli (target frequency) and the angular velocity of the stimuli (target speed) on horizontal optokinetic nystagmus (OKN) was investigated in 6 normal human subjects using target frequencies from 1/3 Hz to 24 Hz and target speeds from 5 degrees/sec to 120 degrees/sec. Regularity and reproductiveness of the OKN were obtained only in test conditions where each transit of targets was followed by an optokinetic response either as one beat or as a sequence of beats. This is called synchronous response and was found when the target frequency was below 3 Hz and the target speeds below 20--30 degrees/sec, depending on the actual frequency. At higher target frequencies and target speeds, the eyes were unable to take up every target, resulting in uneven responses (hyposynchronous response). Very low target frequencies and target speeds were likewise unsuitable due to drifting of the eyes from one target to another. A target frequency and a target speed close to the upper limit for synchronous response is advocated in clinical tests of OKN. 2 Hz and 20 degrees/sec is proposed as a suitable combination of frequency and target speed.     

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.     

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.     

Horizontal and vertical optokinetic nystagmus in man

Horizontal and vertical optokinetic nystagmus (OKN) was studied in 20 healthy adults. Although the horizontal OKN showed no directional difference, a statistically significant difference was found between horizontal and vertical OKN. Upward optokinetic pursuit was better on average than downward pursuit, but more variable. The inferiority of vertical OKN seems to indicate a suppression of optokinetic pursuit due to a different direction of the rotational axis from that of gravity. Regarding the vertical OKN findings, it is speculated that manifest directionality found in quadrupeds is modified in men by the change of their visual field on forward locomotion accomplished by their upright walking posture.     

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.     

Classification of optokinetic after-nystagmus and its topographical-diagnostic significance in man

The existence of optokinetic after-nystagmus (OKAN) has long been known, as far back as the age of Bárány. The term OKAN means nystagmus appearing after first inducing optokinetic nystagmus, and then the optokinetic stimulation is removed. It appears easily with the eyes open in a dark place. There have been various theories about the mechanism of the onset of OKAN. Sakata et al. previously classified the types of OKAN into the following 7 types: 1) The normal type, (2) the directional preponderance type, (3) the disinhibitory type, (4) the inversive type, (5) the inhibitory type, (6) the dysmetric type, (7) the clonic type. In the present study, the authors performed a vestibular equilibrium function inspection, including an OKAN inspection, on about 10,000 patients who visited the Department of Neuro-Otology with complaints of vertigo and equilibrium disturbance. The results of the inspection were classified in accordance with Sakata's method, and the diagnostic contribution of the OKAN inspection was examined. The diagnostic significance of the OKAN inspection is considered as follows: (1) This inspection can detect a very small difference between the left and right of nystagmus in the vestibular-optokinetic system, which difference cannot be detected with OKP inspection giving a rather strong stimulation or with the caloric test giving a non-physiological strong stimulation. (2) This can be a focal localization diagnostic method by the classification by type.