Regional cerebral blood flow changes in human brain related to ipsilateral and contralateral complex hand movements--a PET study

The purpose of this study was to investigate the cortical motor areas activated in relation to unilateral complex hand movements of either hand, and the motor area related to motor skill learning. Regional cerebral blood flow (rCBF) was measured in eight right-handed healthy male volunteers using positron emission tomography during a two-ball-rotation task using the right hand, the same task using the left hand and two control tasks. In the two-ball-rotation tasks, subjects were required to rotate the same two iron balls either with the right or left hand. In the control task, they were required to hold two balls in each hand without movement. The primary motor area, premotor area and cerebellum were activated bilaterally with each unilateral hand movement. In contrast, the supplementary motor area proper was activated only by contralateral hand movements. In addition, we found a positive correlation between the rCBF to the premotor area and the degree of improvement in skill during motor task training. The results indicate that complex hand movements are organized bilaterally in the primary motor areas, premotor areas and cerebellum, that functional asymmetry in the motor cortices is not evident during complex finger movements, and that the premotor area may play an important role in motor skill learning.     

Role of the premotor cortex in recovery from middle cerebral artery infarction

OBJECTIVE: To study the mechanisms underlying recovery from middle cerebral artery infarction in 7 patients with an average age of 53 years who showed marked recovery of hand function after acute severe hemiparesis caused by their first-ever stroke. INTERVENTIONS: Assessment of motor functions, transcranial magnetic stimulation, somatosensory evoked potentials, magnetic resonance imaging, and positron emission tomographic measurements of regional cerebral blood flow during finger movement activity. RESULTS: The infarctions involved the cerebral convexity along the central sulcus from the Sylvian fissure up to the hand area but spared the caudate nucleus, thalamus, middle and posterior portions of the internal capsule, and the dorsal part of the precentral gyrus in each patient. After recovery (and increase in motor function score of 57%, P<.001), the motor evoked potentials in the hand and leg muscles contralateral to the infarctions were normal, whereas the somatosensory evoked potentials from the contralateral median nerve were reduced. During fractionated finger movements of the recovered hand, regional cerebral blood flow increases occurred bilaterally in the dorsolateral and medial premotor areas but not in the sensorimotor cortex of either hemisphere. CONCLUSIONS: Motor recovery after cortical infarction in the middle cerebral artery territory appears to rely on activation of premotor cortical areas of both cerebral hemispheres. Thereby, short-term output from motor cortex is likely to be initiated.     

Diagnostic case study: varicella pneumonia

Amyotrophic lateral sclerosis (ALS) can cause hyperintense lesions in the corticospinal tract but rarely can also cause T2 shortening in the motor cortex bilaterally. The present case of ALS showed unilateral T2 shortening of the superior parietal lobule without corticospinal tract changes.     

Dynamic functional coupling of high resolution EEG potentials related to unilateral internally triggered one-digit movements

Between-electrode cross-covariances of delta (0-3 Hz)- and theta (4-7 Hz)-filtered high resolution EEG potentials related to preparation, initiation. and execution of human unilateral internally triggered one-digit movements were computed to investigate statistical dynamic coupling between these potentials. Significant (P < 0.05, Bonferroni-corrected) cross-covariances were calculated between electrodes of lateral and median scalp regions. For both delta- and theta-bandpassed potentials, covariance modeling indicated a shifting functional coupling between contralateral and ipsilateral frontal-central-parietal scalp regions and between these two regions and the median frontal-central scalp region from the preparation to the execution of the movement (P < 0.05). A maximum inward functional coupling of the contralateral with the ipsilateral frontal-central-parietal scalp region was modeled during the preparation and initiation of the movement, and a maximum outward functional coupling during the movement execution. Furthermore, for theta-bandpassed potentials, rapidly oscillating inward and outward relationships were modeled between the contralateral frontal-central-parietal scalp region and the median frontal-central scalp region across the preparation, initiation, and execution of the movement. We speculate that these cross-covariance relationships might reflect an oscillating dynamic functional coupling of primary sensorimotor and supplementary motor areas during the planning, starting, and performance of unilateral movement. The involvement of these cortical areas is supported by the observation that averaged spatially enhanced delta- and theta-bandpassed potentials were computed from the scalp regions where task-related electrical activation of primary sensorimotor areas and supplementary motor area was roughly represented.     

Production and characterization of profilin monoclonal antibodies

To evaluate the hypothesis that self-paced movements are mediated primarily by the supplementary motor area, whereas externally triggered movements are mainly affected by the lateral premotor cortex, different movements in 6 healthy volunteers were studied while changes in regional cerebral blood flow (rCBF) were measured using positron emission tomography (PET) and 15O-labeled water. Subjects made a series of finger opposition movements initiated in a self-paced manner every 4 to 6 seconds, and separately, made continuous finger opposition movements at a frequency of 2 Hz paced by a metronome. The primary motor cortex, lateral area 6, cerebellum on both sides, and caudal cingulate motor area, and the putamen and thalamus on the contralateral side were more active during the metronome-paced movements. The increases in rCBF in these areas are likely the result of the larger number of movements per minute made with the externally triggered task. The anterior supplementary motor area and rostral cingulate motor area in the midline, prefrontal cortices bilaterally, and lobus parietalis inferior on the ipsilateral side were more active during the self-paced movements. Increases in rCBF in those areas, which include medial premotor structures, may be related to the increased time devoted to planning the movement in this condition.     

Both supplementary and presupplementary motor areas are crucial for the temporal organization of multiple movements

Both supplementary and presupplementary motor areas are crucial for the temporal organization of multiple movements. J. Neurophysiol. 80: 3247-3260, 1998. To study the involvement of the supplementary (SMA) and presupplementary (pre-SMA) motor areas in performing sequential multiple movements that are individually separated in time, we injected muscimol, a gamma-aminobutyric acid agonist, bilaterally into the part of each area that represents the forelimb. Two monkeys were trained to perform three different movements, separated by a waiting time, in four or six different orders. First, each series of movements was learned during five trials guided by visual signals that indicated the correct movements. The monkeys subsequently executed the three movements in the memorized order, without the visual signals. After the injection of muscimol (3 microliter, 5 micrograms/microliters in 10 min) into either the SMA or pre-SMA bilaterally, the animals started making errors in performing the sequence of movements correctly from memory. However, when guided with a visual signal, they could select and perform the three movements correctly. The impaired memory-based sequencing of movements worsened progressively with time until the animals could not perform the task. Yet they still could associate the visual signals with the different movements at that stage. In control experiments on two separate monkeys, we found that injections of the same amount of muscimol into either the SMA or pre-SMA did not cause problems with nonsequential reaching movement regardless of whether it was visually triggered or self-initiated. These results support the view that both the SMA and pre-SMA are crucially involved in sequencing multiple movements over time.     

A case of adult type adrenoleukodystrophy with an acute onset and repeated episodes of ataxic dysarthria

We report a 30-year-old man with adult type adrenoleukodystrophy (ALD) who manifested an acute onset and repeated episodes of ataxic dysarthria. He noticed a moderate dysarthria after a high grade fever in February of 1995; however, two weeks later his symptom disappeared completely. Three months later, he noticed the dysarthria again and he was referred to our hospital for further examination. General physical findings on admission revealed a dark skin color, pigmentation of gingivae and reduced body hair. Neurologically he was normal except for a moderate ataxic dysarthria. Cranial T2-weighted MRI showed multiple high intensity lesions in the subcortical white matter of frontal lobe, bilateral peritrigonal white matter, splenium of the corpus callosum and bilateral cerebellar white matter. Only cerebellar lesions responsible for his symptom were enhanced on MRI after gadolinium administration. Initially we diagnosed him with multiple sclerosis (MS) based upon the clinical course and MRI findings, and then started corticosteroid treatment. His dysarthria was slightly improved after the treatment and bilateral gadolinium-enhanced lesions of cerebellar white matter on MRI disappeared. Multimodality evoked potentials such as short latency somatosensory evoked potentials, brainstem auditory evoked potentials and pattern-reversal visual evoked potentials, disclosed a prolonged central conduction time associated with bilaterally symmetric individual interpeak latencies. These findings, which supported diffuse and bilateral subclinical demyelinating lesions in the central nervous system, were unusual for MS; therefore his plasma very-long-chain fatty acids (VLCFA) were assayed for ALD. Finally, he was diagnosed with adult type ALD because of the high ratio of C26: 0/C22: 0 (0.075; normal 0.033). It is very difficult to clinically distinguish the early stage of adult type ALD especially in patients like this from MS. Therefore it is useful and important to evaluate not only the level of plasma VLCFA, but also to evaluate multimodality evoked potentials.     

MRI and clinical features in amyotrophic lateral sclerosis

MRI of the brain and spinal cord was performed in 21 patients with amyotrophic lateral sclerosis (ALS), 8 normal volunteers and 16 neurological disease controls. High signal was seen in the intracranial corticospinal tract in 16 of the 21 patients on T2-weighted and in 10 on proton density (PD)-weighted images. In one patient, the high signal on T2-weighted images became less marked with progression of the disease. Low signal intensity was seen in the motor cortex in 12 of the 21 patients. High signal in the anterolateral column of the spinal cord on T1 weighted images was seen in 14, and high signal in the lateral corticospinal tract on T2 weighted images was seen in 7 of the 21 patients. The relationship between the abnormal images and upper motor neurone signs remained unclear. High signal intensity was seen in the corticospinal tract in the brain on T2-weighted images in two normal volunteers and four disease controls, and on PD weighted images in three disease controls. Low signal intensity in the motor cortex on T2 weighted images was seen in three normal volunteers and four disease controls. However, high signal intensity was seen in the intracranial corticospinal tract on T1 weighted images in five patients with ALS who showed pronounced upper motor neurone signs including spastic paraparesis, but not in controls. Thus, abnormalities on MRI in the brain and spinal cord should be considered in the diagnosis of ALS, and high signal intensity of the intracranial corticospinal tract on T1-weighted images may reflect the severe pathological changes of the upper motor neurones in ALS.     

Cervical lymph node metastatic patterns of squamous carcinomas in the upper aerodigestive tract

We report a patient with medial medullary infarction who showed deep sensory impairment as his prominent neurological manifestation. A 54-year-old man with a history of hypertension was admitted to our hospital with numbness of the bilateral upper and lower extremities, followed by dysarthria and right hemiparesis. Physical examination revealed no abnormalities except for high blood pressure. He hiccuped continuously. On neurological examination, he exhibited dysarthria, mild dysphagia and right hemiparesis without facial or lingual paresis. Sensitivity to light touch and pinprick was normal, but sensitivity to vibration and joint position was severely decreased in the bilateral upper and lower extremities, predominantly in the lower extremities and on the right side in the upper extremities. He had been treated with antiedema agents and thromboxane synthetase inhibitor. His hiccups stopped within two weeks, and his right hemiparesis gradually improved within one month. However, his deep sensory impairments remained prominent. Blood examinations disclosed positive lupus anticoagulant. MRI showed bilateral infarction at the medial portion of the upper medulla oblongata, extending to both pyramids, especially on the left. Somatosensory evoked potentials (SEP) after median nerve stimulation showed P14 and the later components with prolonged latency. No SEP were recorded after posterior tibial nerve stimulation. The latency of P14 was well correlated with the severity of deep sensory impairments in the upper extremities. Neurological manifestations of our patient are not typical of medial medullary infarction, and are informative about the functional anatomy of the deep sensory tract in the medulla oblongata. We discuss the relation of the intractable hiccups to the bilateral medial medullary lesions, and emphasize the importance of lupus anticoagulant as one of the risk factors in brainstem infarction.     

M?bius syndrome with crossed total hemiatrophy--a case report

The patient was a 26-year-old male who was noted to have asymmetry on the face, upper limbs, and trunk, and who showed no pursuit eye movements and no changes in the facial expression from birth. The patient developed transient global amnesia and was hospitalized. Neurological examination established atrophy of the right face, and left trunk involving the upper limb, and bilateral oculomotor and abducens nerve palsy. In auditory brainstem response, waves III to V were bilaterally obscured, and the blink reflex disclosed disturbances of peripheral facial nerve and the brainstem, suggesting developmental abnormalities of the facial motor nucleus. Contralateral R1 was also recorded in the blink reflex, and crossed trigeminofacial pathway was suspected. M?bius syndrome is associated with various muscle and skeletal abnormalities, but the coexistence of crossed total hemiatrophy has not been reported. We think that our case might be the first case of M?bius syndrome with total hemiatrophy.     

Corticospinal direct response to transcranial magnetic stimulation in humans

The corticospinal motor evoked potential (MEP) response to transcranial magnetic stimulation of the motor cortex was investigated in comparison with the direct (D) response to electrical stimulation of the exposed motor cortex from the spinal epidural space in 7 neurologically normal patients during brain tumor surgery. The D response during operation was obtained by transcranial magnetic stimulation of the scalp over the areas of the cerebral motor cortex, the hand or arm areas. The magnetic induced D response showed a conduction velocity of 50.5-72.7 m/sec and was resistant to anesthesia and unaffected by muscle relaxants and tolerant to high frequency (500 Hz) paired magnetic stimulus, and the latencies of magnetic MEPs corresponded to those with direct electrical stimulation. Thus, recordings of the D response by transcranial magnetic stimulation are useful for not only identifying the location of the motor cortex during intracranial surgery but also for non-invasive recording of pyramidal tract activity during extracranial surgery under general anesthesia.     

Effect of acute dietary fibre supplementation on colonic pH in healthy volunteers

Two patients presented with a tumor involving mainly the supplementary motor area or the premotor cortex. Shortly after tumor resection, each developed transient impairment of voluntary movements. An electromyogram, with the skin electrodes placed over the muscles of the upper arms and forearms, demonstrated aberrant ipsilateral, contralateral or bilateral muscle activation during unilateral motor tasks in both patients. The bilateral activation was more prominent in the patient who had an intact dominant hemisphere. The present study suggests for the first time the importance of non-primary motor areas of the human brain in activating the proper set of muscles on the proper side of the body.     

Prognostic significance of electrophysiological investigations in stroke patients: somatosensory and motor evoked potentials and sympathetic skin response

A prospective 3-month follow-up examination was carried out in 12 patients with supratentorial stroke. Motor evoked potentials (MEP), somatosensory evoked potentials (SEP) and sympathetic skin responses (SSR) were performed 1-7 days, 30 days and 3 months after stroke. The functional outcome measured by a daily activity index (Barthel index) was assessed 3 months after the stroke. There was a significant correlation between SEP and MEP results obtained for the first week and recovery of sensation and motility 3 months later. When initially normal, motor potentials evoked by transcranial magnetic stimulation had a significant predictive value for long-term functional outcome, whereas SEP and SSR did not. SSR present at the initial stage was correlated with the state of consciousness.     

Evaluation of the effect of ivermectin administered topically at zero and six weeks after turnout on gastrointestinal nematode infection in first-season grazing cattle

OBJECTIVES: Slow potentials appearing during simple repetitive acral limb movement were investigated. Twenty-six patients suffering from drug resistant partial epilepsies and explored with implanted intracerebral electrodes were examined using two protocols. METHODS: In 18 patients, readiness potential (RP), in 13 patients contingent negative variation (CNV), and in 7 patients both protocols, were tested. The recordings from leads with evident pathological EEG activity were excluded from evaluation. The results concerning the slow potentials preceding the movements in RP and CNV protocols have already been published. RESULTS: The movement-accompanying slow potentials (MASP) were polyphasic or monophasic, started before or during the movement. In the primary motor cortex they followed the pre-movement potentials depending on the protocol: in the RP paradigm they were present only contralateral to the movement, but were bilateral in the CNV protocol. In other areas they either followed the potentials preceding the movement, in some cases with opposite polarity, or they occurred alone. MASP was recorded in motor and supplementary motor, premotor and prefrontal, midtemporal, somatosensory, superior parietal and cingular cortices. The cingular cortex was heavily involved in the self-paced movements but rarely in the cued movements. CONCLUSION: The major involvement of the cingular gyrus contrasted with the absence of slow potentials in temporal limbic structures. MASP is evidently a heterogenic phenomenon. Its genesis could be involved in a spread of information through the relevant structures.     

Reduced MTR in the corticospinal tract and normal T2 in amyotrophic lateral sclerosis

The objective of this study was to test the hypothesis that magnetization transfer ratios (MTR) are decreased in the corticospinal tract of patients with amyotrophic lateral sclerosis (ALS); to determine if T2 is increased in corticospinal tract or reduced in motor cortex in ALS; to determine if corticospinal tract MTR correlates with a clinical measure of motor neuron function in ALS. Ten ALS patients and 17 age-matched controls were studied. Double spin echo MRI and 3D gradient echo MRI with and without off-resonance saturation were acquired on each subject. 3D data sets were coregistered and resliced to match the spin echo data set. MTR was calculated for corticospinal and non-corticospinal tract white matter. T2 was calculated for corticospinal and non-corticospinal tract white matter, motor cortex and non-motor cortex. MTR was reduced by 2.6% (p < .02) in corticospinal, but not in non-corticospinal, tract white matter in ALS. There was no difference in T2 in any brain region. The correlation between a clinical measure of motor neuron function and corticospinal tract MTR was statistically significant. These findings are consistent with the known pathology in ALS and suggest that MTR is more sensitive than T2 for detecting involvement of the corticospinal tract. Quantitative MTR of the corticospinal tract may be a useful, objective marker of upper motor neuron pathology in ALS.     

Command neurons in the unconditioned reflex arc of the grape snail

Independent intracellular activation of any one of the five identified neurones elicits a behavioral act of pneumostome closing. Similar closing is evoked by adequate stimulation of different modalities. Comparison of unconditioned reflex properties and characteristics of responses of the studied cells leads to the conclusion that neurones under discussion are command elements for the unconditioned reflex. Command neurones respond to all sensory stimuli which can evoke reflex closing. There is a lot of synchronous EPSPs in their spontaneous activity, but no action potentials. A spike discharge of command neurones evoked by an adequate stimulus always precedes the effector movements but there is no action potentials during the pneumostome closing. Conclusion is made that the functional role of command neurones in the unconditioned reflex arc consists in evaluating the sensory input and in triggering motor programmes.     

Sustained activity in the medial wall during working memory delays

We have taken advantage of the temporal resolution afforded by functional magnetic resonance imaging (fMRI) to investigate the role played by medial wall areas in humans during working memory tasks. We demarcated the medial motor areas activated during simple manual movement, namely the supplementary motor area (SMA) and the cingulate motor area (CMA), and those activated during visually guided saccadic eye movements, namely the supplementary eye field (SEF). We determined the location of sustained activity over working memory delays in the medial wall in relation to these functional landmarks during both spatial and face working memory tasks. We identified two distinct areas, namely the pre-SMA and the caudal part of the anterior cingulate cortex (caudal-AC), that showed similar sustained activity during both spatial and face working memory delays. These areas were distinct from and anterior to the SMA, CMA, and SEF. Both the pre-SMA and caudal-AC activation were identified by a contrast between sustained activity during working memory delays as compared with sustained activity during control delays in which subjects were waiting for a cue to make a simple manual motor response. Thus, the present findings suggest that sustained activity during working memory delays in both the pre-SMA and caudal-AC does not reflect simple motor preparation but rather a state of preparedness for selecting a motor response based on the information held on-line.     

Retinal arterial occlusions in young adults

Stereotactic posteroventral pallidotomy can improve motor performance in Parkinson's disease. Interruption of inhibitory pallidal projections to ventrolateral thalamus, components of a cortical-basal ganglia motor loop allows for this clinical benefit. We hypothesized that pallidotomy would lead to increased movement related activity in motor cortical areas receiving projections from ventrolateral thalamus. This was tested in 6 Parkinson's disease patients who underwent stereotactic posteroventral pallidotomy. Each patient was imaged with positron emission tomography (PET) measures of regional cerebral blood flow (rCBF) during performance of a simple prehension task and at rest. Scans were acquired before and 17 weeks after surgery. After pallidotomy, movement-related changes of rCBF increased significantly in both the supplementary motor area (SMA) and premotor cortex but not in primary motor cortex. The results demonstrate the importance of pallidothalamic circuitry for regulating volitional movements and confirm that disruption of inhibitory input to the ventrolateral thalamus can augment movement-related activity in motor association areas.     

Functional results after resective procedures involving the supplementary motor area

In this article, the authors report their experience with surgically induced supplementary motor area (SMA) deficiency syndrome in a prospective clinical trial of 28 patients who underwent surgery for tumorous (19 patients) or nontumorous (nine patients) lesions. The dominant side was affected in 17 patients and the nondominant side in 11 patients. The primary presenting symptoms included seizure activity (23 patients), hemiparesis (four patients), and aphasia (one patient). Functional topographic mapping, achieved by phase reversal of somatosensory evoked potentials, allowed precise localization of the central sulcus in 25 of the 28 patients. Motor evoked potential (MEP) monitoring, which was performed successfully in 13 of 15 cases during the resective procedure, showed no significant changes in the potentials in any patient. Immediately after surgery, 25 (89%) of the 28 patients displayed additional neurological deficits (aphasia and/or hemiparesis) that depended on the extent of the SMA resection. In 12 patients the SMA was resected completely: nine of these patients demonstrated a complete and three an incomplete deficit. In 16 patients the SMA resection was incomplete: 13 of these patients displayed an incomplete deficit, whereas three had no deficit. Neurological disorders resolved completely within 3 to 42 days (mean 11 days), except for a minimal disturbance of fine motor and/or speech function in complex tasks or at high speed. Electromagnetically elicited MEPs, examined postoperatively in five patients, were initially absent but recovered with improvement of motor function. In conclusion, although the SMA is known to control important functions such as initiation of motor activity or speech, our findings show that unilateral SMA removal can be accomplished without resulting in significant permanent deficits. Functional topographic mapping and monitoring facilitate the exact delineation of the adequate resection plane along the precentral sulcus, and postoperative magnetic resonance imaging allows precise correlation of clinical and anatomical data.     

Role for cells in the presupplementary motor area in updating motor plans

Two motor areas are known to exist in the medial frontal lobe of the cerebral cortex of primates, the supplementary motor area (SMA) and the presupplementary motor area (pre-SMA). We report here on an aspect of cellular activity that characterizes the pre-SMA. Monkeys were trained to perform three different movements sequentially in a temporal order. The correct order was planned on the basis of visual information before its execution. A group of pre-SMA cells (n = 64, 25%) were active during a process when monkeys were required to discard a current motor plan and develop a plan appropriate for the next orderly movements. Such activity was not common in the SMA and not found in the primary motor cortex. Our data suggest a role of pre-SMA cells in updating motor plans for subsequent temporally ordered movements.