Does primary lateral sclerosis exist? A study of 20 patients and a review of the literature.

The question of whether primary lateral sclerosis (PLS) is a nosological entity distinct from amyotrophic lateral sclerosis (ALS) has been the subject of controversy since it was first described in the nineteenth century. PLS has been defined as a rare, non-hereditary disease characterized by progressive spinobulbar spasticity, related to the selective loss of precentral pyramidal neurones, with secondary pyramidal tract degeneration and preservation of anterior horn motor neurones. In the recent clinical literature, the frontier between ALS and neurodegenerative disease remains poorly defined. We studied 20 patients with a diagnosis of PLS. We carried out a variety of tests in order to determine the presence of a more diffuse neurodegenerative process. We also performed a longitudinal electrophysiological evaluation. Our clinical, electrophysiological and pathological investigations provide evidence that the disease has a heterogeneous clinical presentation and that degeneration is not restricted to the central motor system.

Hemispheric asymmetry in cortical control of memory-guided saccades. A transcranial magnetic stimulation study.

To study the temporal organisation of memory-guided saccade control we used single-pulse transcranial magnetic stimulation (TMS) over the left posterior parietal (PPC) and prefrontal cortex (PFC) in eight healthy subjects. TMS was applied either following presentation of a visual target, i.e. 160, 260, and 360 ms after the flashed point, or during the period of memorisation, i.e. between 700 and 1500 ms, or finally 100 ms after extinguishing of the central fixation point (i.e. 2100 ms after the target presentation). Latency of memory-guided saccades and the percentage of error in amplitude (PEA) was measured and compared with results without stimulation.TMS over the left PPC 100 ms after the extinguishing of the central fixation point significantly increased memory-guided saccade latency bilaterally. Furthermore, stimulation over the left PFC had a significant effect on the PEA of contralateral memory-guided saccades when applied during the period of memorisation, i.e. between 700 and 1500 ms.In a previous study using identical methodology [13: Müri RM, Vermersch SI, Rivaud S, Gaymard B, Pierrot-Deseilligny C. Effects of single-pulse transcranial magnetic stimulation over the prefrontal and posterior parietal cortices during memory-guided saccades in humans. Journal of Neurophysiology 1996;76:2102-2106], we found that TMS over the right PPC increased the contralateral PEA when applied 260 ms after the flash, the effects on saccade latency after right PPC stimulation or on the PEA after right PFC stimulation being similar to those observed here. Taken together, these results show that (1) a hemispheric asymmetry in the preparation of memory-guided saccade amplitude during the early phase of sensorimotor integration exists, (2) memory-guided saccade triggering is controlled by PPC on both sides, and (3) PFC on both sides are involved in spatial working memory performance.

[Electrophysiologic diagnosis of 2 psycho-visual syndromes: Balint syndrome and cortical blindness. A propos of a case of Benson progressive posterior atrophy]. / Diagnostic électrophysiologique de deux syndromes psycho-visuels: syndrome de Balint et cécité corticale. A propos d'une observation d'atrophie postérieure progressive de Benson.

Cortical blindness and Balint's syndrome are two pathologies not well-known. It seems therefore interesting to report a typical patient case, suffering from Benson's posterior cortical atrophy, who presented successively both syndromes. The Balint's syndrome, which results from a bilateral parieto-occipital junction brain injury, and combines clinically a specified triad defects: a spatial disorder of attention, a psychic paralysis of gaze and an optic ataxia. The cortical blindness, which is caused by bilateral damage of the occipital lobes (Broadman area 17). Electrophysiologically, the abolition of short-latency components of visual evoked potentials and the presence of long-latency potentials are recorded. Visual strategy and visual evoked potentials are thus the only objective examinations allowing to diagnose and follow up these patient's evolution. In any case, an adequate visual rehabilitation has to be carried out in order to help the patient recovering his autonomy.

Role of the prefrontal cortex in the control of express saccades. A transcranial magnetic stimulation study.

Single pulse transcranial magnet stimulation (TMS) was applied in five subjects during a saccadic gap task, i.e. with a temporal gap of 200 ms between the extinguishing of the central fixation point and the appearance of the lateral target. In all subjects, a significant increase of contralateral express saccades was found when TMS was applied over the dorsolateral prefrontal cortex (DPFC) at the end of the gap of 200 ms. Earlier stimulation over the DPFC during the gap had no significant effect. Furthermore, stimulation over the posterior parietal cortex with the same time intervals, and stimulation during a no gap task had no significant influence on express saccades. These results suggest that TMS is capable of interfering specifically with the functioning of the DPFC, probably by inhibition of this region. Possibly such stimulation of the DPFC reduces the inhibition by this region onto the superior colliculus, which results in a facilitation of express saccades.

Cortical control of saccades.

Saccadic eye movements are controlled by a cortical network composed of several oculomotor areas that are now accurately localized. Clinical and experimental studies have enabled us to understand their specific roles better. These areas are: (1) the parietal eye field (PEF) located in the intraparietal sulcus involved in visuospatial integration and in reflexive saccade triggering; (2) the frontal eye field (FEF), located in the precentral gyrus, involved in the preparation and the triggering of purposive saccades; and (3) the supplementary eye field (SEF) on the medial wall of the frontal lobe, probably involved in the temporal control of sequences of visually guided saccades and in eye-hand coordination. A putative cingulate eye field (CEF), located in the anterior cingulate cortex, would be involved in motivational modulation of voluntary saccades. Besides these motor areas, the dorsolateral prefrontal cortex (dlPFC) in the midfrontal gyrus is involved in reflexive saccade inhibition and visual short-term memory.

Temporal limits of spatial working memory in humans.

An essential feature attributed to working memory is the labile and transient nature of its representations. Using an oculomotor task, we examined the stability of spatial working memory in 16 normal human subjects. Eye movements towards remembered spatial cues (memory-guided saccades) were electro-oculographically recorded after memorization delays that varied unpredictably between 0.5 and 30s. A peaked time-course of saccadic targeting errors, with maximal errors around 20s delay, was found, showing that delay-dependent decay of spatial information in working memory occurs, but is time-limited and reverts significantly beyond delays of about 20s. These data (i) indicate temporal limits of spatial working memory and (ii) provide the first behavioural evidence for the existence of two parallely generated mental representations of space that successively control memory-guided behaviour in humans.

Effects of anterior cingulate cortex lesions on ocular saccades in humans.

Cerebral blood flow studies in humans suggest that the anterior cingulate cortex (ACC) could be involved in eye movement control. In two patients with a small infarction affecting the posterior part of this area (on the right side) and in ten control subjects, we studied several paradigms of saccadic eye movements: gap task, overlap task, antisaccades (using either a 5 degrees or 25 degrees lateral target), memory-guided saccades with a short (1 s) or long (7 s) delay, and sequences of memory-guided saccades. Compared with controls, patients had normal latency in the gap task but increased latency in the other tasks. The gain of memory-guided saccades was markedly decreased, bilaterally, whatever the duration of the delay. Patients made more errors than controls in the antisaccade task when the 5 degrees lateral target was used, and a higher percentage of chronological errors in the sequences of saccades. These results show that the posterior part of the right ACC plays an important role in eye movement control and suggest that this area could correspond to a "cingulate eye field" (CEF). The role of this hypothetical CEF could be an early activation exerted on the frontal ocular motor areas involved in intentional saccades and also a direct action on brainstem ocular premotor structures.

Clinical and molecular features of spinocerebellar ataxia type 6.

The mutation involved in spinocerebellar ataxia type 6 (SCA6) is a small CAG expansion in the alpha-1A subunit of the voltage-dependent calcium channel gene. We looked for this mutation in 91 families with autosomal-dominant cerebellar ataxias and found that SCA6 is a minor locus in our series (2%) and is rare in France (1%). Furthermore, we did not detect the SCA6 mutation on 146 sporadic cases with isolated cerebellar ataxia or olivopontocerebellar atrophy. The normal and expanded alleles ranged from 4 to 15 and 22 to 28 CAG repeats, respectively, and age at onset was correlated to CAG repeat length (r = -0.87). In contrast with other SCA, the expanded allele was stable during transmission. Clinically, SCA6 patients (n = 12) presented with moderate to severe cerebellar ataxia with a lower frequency of associated signs compared with other SCA and a mean age at onset of 45 +/- 14 years (range, 24 to 67). MRI showed extensive cerebellar atrophy but not of the brainstem or cerebral cortex.

Cerebral ocular motor signs.

Eye movement disturbances resulting from cerebral lesions are reviewed and the specific roles of the different ocular motor areas are summarized. Three cortical areas may trigger saccades: the frontal eye field (FEF), the supplementary eye field (SEF) and the parietal eye field (PEF). The FEF could be involved mainly in intentional visual exploration (intentional saccades), the PEF mainly in reflexive visual exploration (reflexive saccades) and the SEF in the preparation of motor programs (sequences of saccades). Only bilateral lesions affecting these areas result in visible saccade disturbances (at bedside examination), as manifested in Balint's syndrome after parietal lesions, and ocular motor apraxia after fronto-parietal lesions. Other cortical areas prepare saccades: the posterior parietal cortex (near the PEF) controls visuomotor integration; the prefrontal cortex (i.e. area 46 of Brodmann) is involved in inhibition of unwanted reflexive saccades, prediction (predictive saccades) and spatial memory. Smooth pursuit is controlled by the FEF and the medial superior temporal area, located in the posterior part of the cerebral hemisphere. Eye movement disorders resulting from basal ganglia lesions are also reviewed. Lastly, the contribution of eye movement recordings in early diagnosis of some cerebral degenerative diseases (such as progressive supranuclear palsy or corticobasal degeneration) is emphasized.

Effects of single-pulse transcranial magnetic stimulation over the prefrontal and posterior parietal cortices during memory-guided saccades in humans.

1. We used single-pulse transcranial magnetic stimulation (TMS) to explore the temporal organization of the cortical control of memory-guided saccades in eight humans. The posterior parietal cortex (PPC) or the dorsolateral prefrontal cortex (DPFC), which are both known to be involved in the control of such saccades, were stimulated on the right side at different time intervals after the presentation of a flashed lateral visual target. The memorization delay was 2,000 ms. Single pulses were applied at 160, 260, and 360 ms after the flashed target, during the period of 700 and 1,500 ms, and finally at 2,100 ms, i.e., 100 ms after the extinguishing of the central fixation point. The effects of TMS were evaluated by calculating the percentage of error in amplitude (PEA) and latency of memory-guided saccades. The PEA was determined for the primary saccade (motor aspect) and the final eye position, i.e., after the end saccade (mnemonic aspect). Stimulation over the occipital cortex at the same time intervals served as control experiments. 2. After PPC stimulation, a significant increase in the PEA of the primary saccade and final eye position existed for contralateral saccades, compared with the PEA without stimulation, when stimulation was applied 260 ms after target presentation, but not at other time intervals. There was no significant effect on ipsilateral saccades. Latency was significantly increased bilaterally when stimulation was performed 2,100 ms after target presentation. 3. After prefrontal stimulation, a significant increase in the PEA of the primary saccade and final eye position existed for contralateral saccades, when stimulation was applied between 700 and 1,500 ms after target presentation, but not at other time intervals. There was no significant effect on ipsilateral saccades. Latency was not affected by prefrontal TMS at any stimulation times. 4. Occipital stimulation resulted in no significant effect on the PEA and latency of ipsilateral or contralateral saccades, in particular including the application at 260 ms after target presentation or during the memorization phase. 5. From these results it may be concluded that the observed effects of TMS on saccade accuracy were specific to the stimulated region and specific to the stimulation time. The PPC seems to be involved in the preparation of saccade amplitude, during the early phase of the paradigm, i.e., the sensorimotor processing period, whereas the DPFC could play a role during the later phase of the paradigm, i.e., the memorization period. Therefore in humans these results support the experimental findings suggesting that sensorimotor integration is controlled by the PPC and spatial memory by the DPFC. Furthermore, our results suggest that the PPC, although not the DPFC, plays a role in saccade triggering.

Ocular motor consequences of damage to the abducens nucleus area in humans.

A patient with a complete unilateral conjugate gaze paralysis caused by a small lesion affecting the region of the right abducens nucleus, documented by magnetic resonance imaging, is reported. Eye movements were quantitatively evaluated using electro-oculography. A gaze-evoked nystagmus to the contralateral side and impairment of smooth pursuit and vestibular ocular reflex in the contralateral hemifield of movements were found. The differential diagnosis of conjugate gaze paralysis and the additional ocular motor abnormalities are interpreted in light of clinical and experimental findings.

Saccade disturbances after bilateral lentiform nucleus lesions in humans.

OBJECTIVE: To determine the roles of the putamen and pallidum in ocular motor control. METHODS: Eye movements were recorded electro-oculographically in nine patients with bilateral focal lesions affecting the lentiform nucleus, and in 12 age matched control subjects. Reflexive visually guided saccades (gap task), antisaccades, memorised sequences of saccades, memory guided saccades (with visual input only, and with both visual and vestibular inputs), and predictive saccades (with and without gap) were studied. RESULTS: Latency and accuracy of visually guided saccades were normal. The percentage of errors in the antisaccade task and latency of correct antisaccades did not differ significantly from the results of controls. The percentage of errors in saccade sequences was significantly increased. Accuracy of the two types of memory guided saccades was impaired bilaterally. The percentage of predictive saccades was significantly decreased when a gap existed, but unchanged without a gap, compared with controls. Therefore, saccades made immediately in response to an external target (reflexive visually guided saccades and antisaccades) were performed without difficulty, whereas those requiring an internal representation of such a target (such as memory guided saccades, predictive saccades, and saccade sequences) were performed with significant disturbances. CONCLUSIONS: The lentiform nucleus influences the cortical areas involved in the control of saccades when the experimental paradigm requires the use of an internal representation of the target for correct planning and execution of the ensuing saccade.

Does the enhancement of cholinergic neurotransmission influence brain glucose kinetics and clinical symptomatology in progressive supranuclear palsy?

Cholinergic systems are markedly affected both in cortical and subcortical cerebral areas of patients with progressive supranuclear palsy (PSP). To determine whether it is possible to modify the clinical picture of PSP through the enhancement of brain cholinergic neurotransmission, we studied the effects of physostigmine, an anticholinesterase reference drug, on symptoms and brain glucose metabolism using [18F]fluorodeoxyglucose (FDG) and PET. Patients were evaluated blind in a randomized order with both placebo and physostigmine infusions after an individual determination of maximal tolerated dose. Under steady-state physostigmine infusions, although glucose consumption was not significantly modified, the entry of glucose from blood to brain was regionally increased from 8 to 32% of placebo values suggesting an increase in cerebral blood flow (CBF) or an increase in the activity of brain glucose transporter. Following physostigmine administration in the same patients: the errors in antisaccades during ocular movement testing were significantly reduced, a significant reduction in errors or performance was found in four out of seven neuropsychological tests, and motor disability was not significantly altered. Although the precise pathophysiology of these physostigmine-induced effects needs further investigations, our study suggests that part of the clinical symptomatology in PSP could be relieved by the enhancement of brain cholinergic neurotransmission.

Cortical control of vestibular-guided saccades in man.

Memory-guided saccades, made to a remembered location to which gaze was directed before a passive body rotation (i.e. with a vestibular input), were electro-oculographically recorded in 24 patients with various cortical lesions and in 18 control subjects. Anticipation and latency, direction errors and accuracy of the first saccade, stability of eye position in darkness and final eye position were quantified. Patients were divided into small groups, each with lesions affecting one of the following cortical areas: left or right frontal eye field (FEF), left or right prefrontal cortex (area 46 of Brodmann) (PFC), left supplementary eye field (SEF), left or right posterior parietal cortex (PPC) and right parieto-temporal cortex (PTC). There were some abnormalities in the results of the right FEF group, concerning anticipation, direction errors and latency of the first saccade, but no abnormality in the accuracy of the first saccade or of the final eye position. Results in the left FEF group were normal. Accuracy of the first saccade was impaired in the SEF group, bilaterally. Final eye position was also inaccurate in the SEF group. In both PFC groups, significant and, in general, bilateral abnormalities existed for all tested parameters. Accuracy of the first saccade was impaired in the PTC group, leftwards. In contrast, the results in both PPC groups were not significantly different from those of control subjects. Our results suggest that (i) the PFC is involved in the memorization of saccade goals probably encoded in spatiotopic coordinates; (ii) the SEF, but not the FEF, is involved in the control of accuracy of these vestibular-derived goal-directed saccades; (iii) the PTC (i.e. the vestibular cortex), but not the PPC, is involved in the control of such saccades. Therefore, a cortical network different from that involved in the control of memory-guided saccades made to visual targets, with only the PFC in common, could control vestibular-derived goal-directed saccades.

Cortical control of saccades.

A scheme for the cortical control of saccadic eye movements is proposed based partly on defects revealed by specific test paradigms in humans with discrete lesions. Three different cortical areas are capable of triggering saccades. The frontal eye field disengages fixation, and triggers intentional saccades to visible targets, to remembered target locations, or to the location where it is predicted that the target will reappear (i.e., saccades concerned with intentional exploration of the visual environment). The parietal eye field triggers saccades made reflexively on the sudden appearance of visual targets (i.e., saccades concerned with reflexive exploration of the visual environment). The supplementary eye field is important for triggering sequences of saccades and in controlling saccades made during head or body movement (i.e., saccades concerned with complex motor programming). Three other areas contribute to the preparation of certain types of saccades. The prefrontal cortex (area 46 of Brodmann) plays a crucial role for planning saccades to remembered target locations. The inferior parietal lobule is involved in the visuospatial integration used for calculating saccade amplitude. The hippocampus appears to control the temporal working memory required for memorization of the chronological order of sequences of saccades.

Effects of transcranial magnetic stimulation over the region of the supplementary motor area during sequences of memory-guided saccades.

Transcranial magnetic stimulation (TMS) over the region of the supplementary motor area (SMA) was used to study the cortical control of sequences of memory-guided saccades. In ten healthy subjects, TMS was applied during (a) the target presentation (learning) phase, (b) the memorization phase, and (c) the execution phase of such saccade sequences. Stimulation during the presentation phase resulted in a significant increase in errors, compared to the results without stimulation. In contrast, stimulation during the memorization or execution phases had no significant influence on the performance of these sequences. The effect of TMS during the presentation phase seems to be specific for an interaction with the SMA function, since, in a control experiment with TMS of the occipital cortex during the same phase, the results were similar to those without stimulation. It is hypothesized that different cortical areas are involved in the learning, memorization and execution of sequences of memory-guided saccades. The SMA action could be crucial during the learning phase, but not during the memorization and execution phases of such sequences.

Horizontal eye movement disorders after posterior vermis infarctions.

The horizontal saccade, smooth pursuit, and vestibulo-ocular reflex gains were recorded in 19 patients with cerebellar infarction documented with MRI, and in a group of control subjects. Bilateral saccade hypometria and a decrease in ipsilateral smooth pursuit gain were found only in patients with a lesion affecting the posterior vermis. These results in humans support experimental findings suggesting that the posterior vermis controls both saccade accuracy and smooth pursuit velocity.

Role of pontine nuclei damage in smooth pursuit impairment of progressive supranuclear palsy: a clinical-pathologic study.

We performed a quantitative study of the pontine nuclei in the basis pontis and a semiquantitative study of extrapontine structures involved in smooth pursuit in four patients with severe impairment of horizontal smooth pursuit and histopathologically confirmed diagnosis of progressive supranuclear palsy (PSP). There were only slight changes in the extrapontine structures involved in smooth pursuit, but there was a significant neuronal loss--massive in three patients and mild in one patient--in all nuclei of the basis pontis. Our results suggest that degenerative lesions affecting the pontine nuclei are largely responsible for the horizontal smooth pursuit impairment in PSP.

Eye movements in parkinsonian syndromes.

Eye movements were recorded in 14 patients with Parkinson's disease (PD) in the "off" condition, 14 patients with striatonigral degeneration (SND), 10 patients with corticobasal degeneration (CBD), and 10 patients with progressive supranuclear palsy (PSP), with comparison with 12 control subjects. Vertical saccade paralysis was not observed in the PD, SND, and CBD groups but was present in 9 patients of 10 in the PSP group. In the PD and SND groups, horizontal reflexive visually guided saccade latency and accuracy were similar, and differed only slightly from those of controls. In the CBD group, saccade latency was significantly increased and correlated to an "apraxia score"; whereas, in the PSP group, saccade amplitude was significantly decreased. Thus, the abnormalities of both horizontal saccade parameters in the PSP group contrasted with those observed in the CBD group. The percentage of errors in the antisaccade task, an index of prefrontal dysfunction, was markedly increased only in the PSP group. The smooth pursuit gain was decreased in all groups but more severely in the PSP group. It may be concluded that saccade abnormalities are clearly different in SND, CBD, and PSP, and might help in early differential diagnosis in individual patients, but that SND cannot be differentiated from PD on the simple basis of eye movement abnormalities.