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Show Journal of Clinical Neuro- ophthalmology 10( 1): 21- 26, 1990. Oculographic Analysis of Acute Esotropia Secondary to a Thalamic Hemorrhage Richard W. HertIe, M. D., and Don C. Bienfang, M. D. © 1990 Raven Press, Ltd., New York We used electrooculography to study the saccadic velocities, smooth pursuit, and vestibular ocular reflex in a patient with an acute thalamic hemorrhage. Our findings confirmed what others have shown in that there were hypometric saccades contralateral to the lesion, impaired smooth pursuit ipsilaterally, and a preserved vestibular ocular reflex. In addition, we demonstrated an asymmetry with the contralateral eye being more affected. It is also shown that the " convergence" movements seen on attempted upgaze are typical of saccades and not vergence movements. A discussion of possible pathophysiologic mechanisms with review of other studies is presented. Key Words: Thalamic hemorrhage- SaccadesEsotropia. From the Department of Ophthalmology,. The University Hospital and Boston City Hospital, Boston UniversIty School of Medicine, ( R. W. H.) and Department of Ophthalmology, The Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts, U. S. A. 21 According to Walsh et al. ( 1), thalamic hemorrhage accounts for 2'>- 35% of all cerebral hemorrhages diagnosed by computerized tomography. Fisher ( 2) localized 13% of intracerebral hemorrhages to the thalamus. Castaigne et al. ( 3) divided them into three categories based on topographical and vascular arrangements: unilateral paramedian, bilateral paramedian thalamic, and paramedian thalamopeduncular. They concluded that paramedian thalamic infarcts were rarely isolated. The mesencephalic gray matter, principal nucleus, and fibers of the third cranial nerve were affected in > 75% of cases. Symptoms from thalamic hemorrhage include altered levels of consciousness from hypersomnia to deep coma, behavioral disturbances, impaired memory, abnormal clonic or atheototic movements, speech and language dysfunction, and oculomotor disturbances ( 1- 3). Fisher ( 2) described the oculomotor signs as convergence spasm, paresis of horizontal and vertical gaze, downward deviation, and miotic, poorly reactive pupilS. Other signs may include ptosis on the involved side and a skew deviation during the acute stage ( 3,4). Full vestibularly driven eye movements, decreased convergence and Bell's phenomenon, and " nystagmoid jerks" are also reported ( 2). Brigell et al. ( 4) reported a case with transient opsoclonus, hypometric saccades contralateral to the lesion, and low gain pursuit ipsilaterally. Wall et al. ( 5) described three cases of rostral midbrain and thalamic infarction with paresis of vertical gaze, absent convergence, aneisicoria, variable response to vestibularly driven eye movements vertically, and decreased pupillary responses to both light and near. Ochs et al. ( 6) found opposed adducting saccades on attempted upgaze in their eye movement recordings of a patient with a thalamic tumor extending to the midbrain causing Paurinaud's syndrome. 22 R. W. HERTLE AND D. C. BIENFANG The associated findings of impaired vertical gaze, convergence spasm ( acute esotropia), convergence retraction nystagmus with attempted upgaze, and miotic poorly reactive pupils constitute Parinaud's syndrome described in 1883 and later elaborated on by Koerber in 1903 ( 7). Investigations into the pathophysiology of the oculomotor disturbances by Gay et al. ( 8), using electromyography, showed cocontraction of all muscles tested during retraction. There was an abrupt onset of electromyographic activity consistent with a saccadic discharge ( 8). Esslen and Papst in 1961 found excessive tonic electromyographic activity resembling spastic innervation from disinhibition of the superior and inferior recti motor nuclei as well as faulty recruitment of motor units in the superior rectus. Daroff and Hoyt ( 8) found no evidence of horizontal vergence movements during retraction, but a pattern of horizontal dysjunctive saccades of unequal amplitude towards the center. We recently had the opportunity to perform oculography on a patient with an acute thalamic hemorrhage. The results with subsequent discussion are reported below. CASE REPORT An 84- year- old right- handed white woman had a history of coronary artery disease and hypertension. She noticed the acute onset of perioral numbness that spread to both sides of her body. At the same time, she noticed severe right- sided headache, diplopia, dizzyness, nausea, and left- sided weakness. She fell while attempting to rise out of a chair and hit her left temple. She had slurred speech while calling her daughter on the phone and was brought to the emergency room. Past medical history was significant for a myocardial infarction 6 years previously and cataracts. Physical examination in the emergency room revealed an 84- year- old white woman in no acute distress. Her blood pressure was 180/ 85, pulse 72 with premature ventricular contractions ( PVCs), and respirations 14- 18/ minute regular and unlabored. There was a fresh 3.0- cm contusion over her left temple. Neurological exam showed orientation to person and place, decreased attention, normal memory, and dysarthria, and cranial nerve examination showed mildly decreased sensation of the left face and central facial weakness. She had a dense flacid left hemiparesis, decreased sensation on the left, and upgoing toes bilaterally. Her oculomotor examination at the time of admission was reported to show miotic poorly reactive pupils to direct light. convergence spasm, limitation of up- I LIm Neu{ v- uIJftliwlliiul, ', 101' , t" i 1 I~) CIIJ gaze with convergence on attempt, and increasing convergence on downgaze. The patient's medical status prohibited examination in the ophthalmology office at anytime during the hospitalization, and some tests, such as calorics, were felt to be too strenuous for her. Ophthalmologic consultation in the intensive care unit 1 day after admission revealed 2.5- mm pupils poorly reactive to both direct and consensual stimulation. There was a 30- 40 prism diopter esotropia, which increased on downgaze simulating a V- pattern. This was measured with the patient fixating a target at 15 ft while performing both the cover- uncover test and the simultaneous prismcover test. There seemed to be a preference for the right eye, but she freely alternated fixation. There was limitation of up gaze to - 10° with " convergence" movements on attempt. The patient responded to commands with limitation of abduction bilaterally. The right abducted to 60% of normal and the left to only 10% of normal. There appeared to be sluggish convergence. Vestibularly driven eye movements showed full horizontal versions. Optokinetic movements using an optokinetic drum showed occasional convergent movements with downgoing stripes. There was also an intermittent, small amplitude, high frequency, rotary nystagmus that increased in intensity on upgaze. The remainder of her ocular examination was normal except for bilateral cataracts and retinal vascular disease consistent with arteriolarsclerosis and hypertension ( Fig. lA- F). Over the course of her hospital stay, all her physical findings improved slowly and steadily. Computerized tomography ( CT) at the time of admission showed a right midbrain hemorrhage extending rostral to the thalamus and into the midbrain. There was no midline shift of intraventricular or subarachnoid hemorrhage ( Fig. 2A and B). RECORDING METHOD A Traucoustics model # BV- 275 saccadic velocity recorder that has DC coupling and a bandwidth of 0- 75 Hz was used. This unit is portable enough to be used at the bedside, which is where the recordings were done. Electrodes were placed both temporally and nasally as well as a ground on the forehead. The stimulus apparatus was a Traucoustics model # RV- 259 Digital Light Bar. This contains light- emitting diodes placed so as to subtend visual angles of 5°, 10°, and 15° both horizontally and vertically 1.5 m from the patient. The patient's head was held steady as she was asked to look at the test lights. The protocol involved both binocu- ESOTROPIA AND THALAMIC HEMORRHAGE 23 ,..' D E FIG. 1. Oculomotor exam performed one day after the patient's cerebrovascular accident. Photographs were taken at the patient's bedside. A: Patient with gaze straight ahead showing both eyes turned in. Acute esotropia. B: Patient asked to look right with limitation of gaze more evident in abducting right eye. C: Patient asked to look left with limitation of gaze more evident in the abducting left eye. 0: Patient asked to look up with obvious limitation of vertical gaze. E: Patient asked to look down showing some limitation but less than in upgaze and increasing esotropia. F: Vestibularly driven eye movements to the left showing full versions in abduction. G: Vestibularly driven eye movements to the right showing full versions in abduction. lar and monocular saccades between center and 10°, and center and 15° lights. Upward saccades to a 10° light was attempted as well. Smooth pursuit was evaluated grossly with the patient instructed to follow a hand held target moving at - 5- lOo/ s in a sinusoidal pattern. The vestibular reflex was tested by asking the patient to view the central diode while the head was manually rotated. RESULTS Electrooculography was performed on the 10th day after the patient's cerebrovascular accident. With the right eye, viewing attempts were made between 15° right and 15° left. The first and third abductive saccades had a gain of close to 1. The first and second adductive saccades were hypometric with no corrective saccade made after the first adductive saccade and a small glissadic- like movement followed by a corrective saccade made after the second. Five millimeters equals 2.5° for calibration on the position trace. Average velocities were 244°/ s in abduction and 229°/ s in adduction calculated for all 15° saccades made during this paradigm ( Fig. 3A). With the left eye viewing center to 15° right ( the patient was unable to voluntarily abduct very far past the midline), there was hypometria in both directions but more severe in abduction compared to adduction. The three adductive saccades have a gain close to 1 and are followed by small additional saccades. The three abductive saccades clearly re-quire more saccades to arrive at the target. The calibration of this position trace is 1.0 mm equals 1.0°. Averages of adducting saccadic velocities were 193°/ s and abducting velocities were 71°/ s calculated for all voluntary or involuntary saccades of 5° made during this paradigm. With both eyes viewing and attempted upgaze to 10°, bilateral convergence was seen. This consisted of an adducting saccade in both the right and left eyes. The average velocities of these saccades were 45°/ s in the left and 42°/ s in the right as calculated for all saccades measuring 5° during this paradigm ( Fig. 3C). Because of lack of sensitivity inherent in electroOCUlography ( EOG), the involuntary oscillations are not fully appreciated in the recording, but there can be seen brief periods of the horizontal component of the oscillation on attempted upgaze. They appear pendular with a jerk component. The position calibration is 1.0 mm equals 1.0° ( Fig. 3D). Smooth pursuit showed low gain in both directions. With the right eye viewing, the gain to the right was 0 as evidenced by total saccadic replacement. Gain to the left, although close to 0, did show evidence of some intact pursuit ( Fig. 3E). The vestibular ocular reflex was relatively well preserved with the right eye fixating ( Fig. 3F). DISCUSSION The most obvious disturbance in this patient is the esotropia. In hysterical individuals, conver- I Clin Neuro- ophthalmol. Vol. 10. No. 1, 1990 24 R. W. HERTLE AND D. C. BIENFANG FIG. 2. CT scan ot tne neao on aa'mlssion. A: Hemorrhage in the right posterior thalamus. B: Higher magnification in the coronal plane showing hemorrhage in the posterior medial thalamus and midbrain. gence is usually associated with accommodation ( 7). Convergence has been described in patients with basilar inflammation following head trauma and as a consequence of hyperopia with a high ACiA ratio ( 7). Mott and Schafer, in 1960, produced convergence in eyes of monkeys by bilateral stimulation of corresponding areas of frontal lobes or occipital eye fields. lampel, in 1959, elicited asymmetric convergence movements associated with variable miosis and accommodation with unilateral stimulation of points in the primate's occipital cortex. In primates, Pasik et al. ( 9,10) obtained adduction of the ipsilateral eye from an area of the tegmentum lying ventrolaterally at the rostral end of the midbrain. Both convergence and downward deviation of the eyes were obtained by stimulation ( If th,' n'" to'fl' , r ' c,'~ rr';'> ry thalamus 13 mm lateral to the midline. In humans, Moster and Hoenig ( 11) reported a case of intermittent " convergence spasm" secondary to metabolic encephalopathy, and Selhorst ( 12) reported two patients with acute esotropia secondary to thalamic hemorrhage. From the preceding animal work and human observation, several areas of cortical and subcortical stimulation could produce convergence. Patients with acquired convergence have lesions that are destructive and not thought to be a cause of excessive stimulation. Selhorst ( 12) postulated, in his two patients, loss of supranuclear inhibition of convergence to be responsible for the acute esotropia. In studying the convergence system in humans, Schor and Cuiffreda ( 13) postulates a constant tonic vergence system that operates independently of both accommodative and proximal vergence. It functions to align the eyes from an anatomical position of rest with a possible role in active convergence ( 13). In our patient, the neural integration between the different types of vergence may be disrupted resulting in an excess of convergence. The associated miosis makes a large contribution from the accommodative component seem highly likely. We know that there is constant neuromuscular activity in the extraocular muscles that is their " tone" and that the only time no recordable activity is found in an inhibited antagonist muscle palsy manifest as an imbalance of tone or spasticity ( 14). Because our patient's esotropia could be overcome by vestibularly driven eye movements, it may be a form of pseudo CN VI palsy ( 15). Impaired vertical gaze is seen in a variety of supranuclear, nuclear, and infranuclear disorders. This seems always to be the result of a bilateral lesion, either directly or involving a decussation. The important areas are the posterior commissure, the rostral interstitial nucleus of the mediallongitudinal fasiculas, the rostral medial longitudinal fasiculas, and the interstitial nucleus of Cajal ( 9,10,16,17). In patients with thalamic hemorrhage, Brigell et al. ( 4), Hirose et al. ( 18), and Masdeau et al. ( 15) reported hypometric saccades contralateral to the side of the lesion. They postulate that interruption of direct synaptic connections from the prefrontal cortex through the thalamus, specifically the " transthalamic bundle," simulate a decorticate state for saccadic activity. Monkey studies have shown similar abnormalities after decortication ( 19). It is interesting that we found the contralateral eye to be more affected. This was true in Selhorst's ( 12) two cases of acute esotropia secondary to thalamic hemorrhage. One could postulate both contralat- ESOTROPIA AND THALAMIC HEMORRHAGE 25 ... ,. ..... Tl - Ol' =.£.' .1. - c . , --- - .... · ..., L,... ;~ IJiio.~~" 1.""~~ rQ : s ~ F FIG. 3. Oculomotor recordings completed 10 days after the patient's cerebrovascular accident. Velocities were either 40 0 / s/ cm or 200 0 / s/ cm as marked on each recording sample. Calibration for position was 5.0 mm equals 2.5° or 3.0° as marked on the photograph and described in the text. Rightward eye movements are up and leftward are down on each of the position traces. A: Right eye ( 00) viewing with saccades attempted between 15° right and 15° left showing hypometria in both abduction and adduction but greater in adduction ( contralateral to the lesion). See text. B: Left eye ( OS) viewing center to 15° right ( patient could not voluntarily abduct much beyond midline) again with hypometria in both directions with a more profound difference between abduction and adduction. It is worse in abduction, contralateral to the lesion. C: Saccades made between center and 10° up with representative velocity tracings from both eyes. Oysjunctive movements with saccadic characteristics are evident. These are convergent and correlate with the clinical appearance of convergence on attempted upgaze ( arrows). D: Position traces of same saccades between 10° up and center showing bilateral adduction saccades and oscillations. See text for details. E: Right eye smooth pursuit was tested to a hand- held target moving in a sinusoidal pattern at - 5- 100 / s with the head held stationary. This shows symmetrical low gain pursuit at almost 0 gain but occasional pursuit was seen to the left ( contralateral to the lesion). F: Vestibular ocular reflex with the 00 fixating a central target. This shows a well- preserved reflex with almost a gain of 1.0. eral cortical control, not only of saccadic gaze, but also uniocular saccades of the contralateral eye. Our patient also had impaired smooth pursuit. It was not as easy to see the asymmetry in our patient as it was in the patients reported by Hirose et al. ( 18) and Brigell et al. ( 4). Pursuit was more impaired ipsilateral to the lesion. Although not as well understood as the saccadic system, interruption of descending fibers from the inferior parietal lobe or peristriate cortex in and around the thalamus could interfere with smooth pursuit. Leigh and Zee ( 14) say that low gain pursuit can be attributed to large lesions of the human parietal lobe and the impairment is ipsilateral. The convergence retraction seen in our patient and those with Parinaud's syndrome is not a true convergence movement but either a cocontraction of all extraocular muscles or impaired saccadic dynamics ( 6- 8). Hypotheses to explain these movements include a " diffuse spread" of voluntary impulses, in which the medial rectus, being the largest, caused con-vergence; isolated medial recti activity; and an exaggerated stretch reflex ( 6- 8). Ochs et al. ( 6) have shown the fine structure of these eye movements and proposed a more physiologic explanation. These opposed adducting saccades are the result of a normal dynamic overshoot mechanism operating at high gain in the contralateral eye. This explains their observed asynchronous initiation and the convergent movement. The normal lower level brain stem is modified by highgain signals. In summary, an upward eye movement attempt is followed by a contralateral directed conjugated saccadic impulse that is modified by a supranuclear high- gain instability to the contralateral eye, causing a large dynamic overshoot manifesting clinically as opposed adducting saccades or " convergence" ( 6). The variety of oculomotor abnormalities seen with thalamic hemorrhage imply involvement of tracts going through the thalamus, near the thalamus, or coincidental involvement of nearby structures. As Castaigne et al. ( 3) found in their study of JClin Neuro · ophthalmol. Vol. 10, No. 1, 1990 26 R. W. HERTLE AND D. C. BIENFANG 28 patients, at least 50% had oculomotor abnormalities. Paramedian thalamic or midbrain infarcts are rarely isolated, and they often involved the mesencephalic grey and third cranial nerve. These patterns are inconstant and dependent on variation in blood supply and etiology of destruction. Oculomotor findings consisted of parts of or the complete Parinaud's syndrome plus variable third nerve involvement. Attention to these deficits can be clues to the diagnosis of thalamic hemorrhage. REFERENCES 1. Walsh TM, Davis KR, Fisher CM. Thalamic hemorrhage: a computed tomographic correlation. Neurology 1977; 27: 21722. 2. Fisher CM. The pathologic and clinical aspects of thalamic hemorrhage. Trans Am Neural Assoc 1959; 84: 56. 3. Castaigne P, Lherrnette F, Buge A, Escourolle R, Hauw H, Luon- Caen O. Paramedian thalamic and midbrain infarcts: clinical and neuropathological study. Ann Neural 1981; 10: 127- 48. 4. Brigell M, Babikian V, Goodwin JA. 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