Running out of brain.

Stroke is the third most common cause of death after coronary artery disease and cancer in the UK, and running is a popular form of exercise, and increasingly, people are participating in large scale endurance events such as marathons and half-marathons. We describe here two cases of young men suffering a stroke after running a marathon and who were subsequently found to have a patent foramen ovale (PFO). We have reviewed the existing literature concerning stroke in those undertaking long-distance running, and suggest why PFO may have been important etiologically in our two patients. We tentatively suggest that individuals with a PFO who engage in long distance running may be at increased risk of stroke, independent of other cerebrovascular risk factors.

Primary determinants of ischaemic stroke/brain abscess risks are independent of severity of pulmonary arteriovenous malformations in hereditary haemorrhagic telangiectasia.

BACKGROUND: Brain abscesses and ischaemic strokes complicate pulmonary arteriovenous malformations (PAVMs). At risk individuals are poorly recognised. Stroke/abscess risk factors have not been defined. METHODS: A cohort study of 323 consecutive individuals with PAVMs (n = 219) and/or the commonly associated condition hereditary haemorrhagic telangiectasia (HHT, n = 305) was performed. Most of the 201 individuals with PAVMs and HHT had no respiratory symptoms, and were unaware they had HHT. Anderson-Gill models assessed constant and time dependent potential predictive variables for stroke/abscess, and rate reduction by PAVM embolisation. RESULTS: 57 individuals with PAVMs and HHT experienced brain abscess or ischaemic stroke, usually prior to the diagnosis of underlying PAVMs/HHT. The primary determinants of stroke and abscess risks were unrelated to severity of PAVMs. Males had higher brain abscess rates (hazard ratio 3.61 (95% CI 1.58, 8.25), p = 0.0024); interventional histories and bacteriological isolates suggested dental sources. Once adjusted for gender, there was a marginal association between brain abscess and low oxygen saturation. For ischaemic stroke, there was no association with any marker of PAVM severity, or with conventional neurovascular risk factors. Surprisingly, low mean pulmonary artery pressure was strongly associated with ischaemic stroke (hazard ratio 0.89 (95% CI 0.83, 0.95) per mm Hg increase; p = 6.2x10(-5)). PAVM embolisation significantly reduced ischaemic stroke rate (p = 0.028); no strokes/abscesses occurred following obliteration of all angiographically visible PAVMs. The mean PAVM diagnosis-treatment interval was longer, however, when neurological risks were unrecognised. CONCLUSIONS: Ischaemic strokes and brain abscesses occur commonly in undiagnosed HHT patients with PAVMs. Risk reduction could be improved.

Self-initiated versus externally triggered movements. II. The effect of movement predictability on regional cerebral blood flow.

Event-related potential studies in man suggest a role for the supplementary motor area (SMA) in movement preparation, particularly when movements are internally generated. In a previous study combining PET with recording of movement-related cortical potentials, we found similar SMA activation and early pre-movement negativity during self-initiated and predictably paced index finger extensions. Early pre-movement negativity was absent when finger movements were paced by unpredictable cues. We postulated that preparation preceding self-initiated and predictably cued movements was responsible for equivalent levels of SMA activation in these two conditions. To test this, we have performed further studies on six normal volunteers with H2(15)O-PET. Twelve measurements of regional cerebral blood flow were made in each subject under three conditions: rest; self-initiated right index finger extension at a variable rate of once every 2-7 s; and finger extension triggered by pacing tones at unpredictable intervals (at a rate yoked to the self-initiated movements). Activation associated with these conditions was compared using analysis of covariance and t statistics. Compared with rest, unpredictably cued movements activated the contralateral primary sensorimotor cortex, caudal SMA and contralateral putamen. Self-initiated movements additionally activated rostral SMA, adjacent anterior cingulate cortex and bilateral dorsolateral prefrontal cortex (DLPFC). Direct comparison of the two motor tasks confirmed significantly greater activation of these areas and of caudal SMA in the self-initiated condition. These results, combined with our previous data, suggest that rostral SMA plays a primary role in movement preparation while caudal SMA is a motor executive area. In this experiment and in our earlier study, DLPFC was activated only during the self-initiated task, in which decisions were required about the timing of movements.

Frontal, midbrain and striatal dopaminergic function in early and advanced Parkinson's disease A 3D [(18)F]dopa-PET study.

We have studied focal changes in dopaminergic function throughout the brain volume in early and advanced Parkinson's disease by applying statistical parametric mapping (SPM) to 3D [(18)F]dopa-PET. Data from seven early hemi-Parkinson's disease and seven advanced bilateral Parkinson's disease patients were compared with that from 12 normal controls. Parametric images of [(18)F]dopa influx rate constant (K(i)(o)) were generated for each subject from dynamic 3D [(18)F]dopa datasets and transformed into standard stereotactic space. Significant changes in mean voxel [(18)F]dopa K(i)(o) values between the normal control group and each Parkinson's disease group were localized with SPM. Conventional region of interest analysis was also applied to comparable regions on the untransformed image datasets. In early left hemi-Parkinson's disease, significant extrastriatal increases in [(18)F]dopa K(i)(o) were observed in the left anterior cingulate gyrus and the dorsal midbrain region (P < 0.05, corrected) along with decreases in striatal [(18)F]dopa K(i)(o). In advanced Parkinson's disease, significant extrastriatal decreases in [(18)F]dopa K(i)(o) were observed in the ventral and dorsal midbrain regions (P < 0.05, corrected). No significant changes in [(18)F]dopa K(i)(o) were observed in the anterior cingulate region. In a direct comparison between the early and late Parkinson's disease groups, we observed relative [(18)F]dopa K(i)(o) reductions in ventral and dorsal midbrain, and dorsal pontine regions along with striatal [(18)F]dopa K(i)(o) reductions. Similiar results were found with a region of interest approach, on non-transformed data, except for the focal midbrain [(18)F]dopa K(i)(o) increase seen in early Parkinson's disease. In conclusion, using SPM with [(18)F]dopa-PET, we have objectively localized changes in extrastriatal, pre-synaptic dopaminergic function in Parkinson's disease. The significance of the increased dopaminergic activity of anterior cingulate in early Parkinson's disease remains unclear, but may be compensatory. The [(18)F]dopa signal in dorsal midbrain and pontine regions suggests that [(18)F]dopa is taken up by serotonergic and noradrenergic neurons which also degenerate in advanced Parkinson's disease. This suggests, therefore, that Parkinson's disease is a monoaminergic neurodegenerative disorder.

Association of abnormal cerebellar activation with motor learning difficulties in dyslexic adults.

BACKGROUND: In addition to their impairments in literacy-related skills, dyslexic children show characteristic difficulties in phonological skill, motor skill, and balance. There is behavioural and biochemical evidence that these difficulties may be attributable to mild cerebellar dysfunction. We wanted to find out whether there was abnormal brain activation when dyslexic adults undertook tasks known normally to involve cerebellar activation. METHODS: Brain activation was monitored by positron emission tomography in matched groups of six dyslexic adults and six control adults as they carried out either a prelearned sequence or learned a novel sequence of finger movements. FINDINGS: Brain activation was significantly lower (p<0.01) for the dyslexic adults than for the controls in the right cerebellar cortex and the left cingulate gyrus when executing the prelearned sequence, and in the right cerebellar cortex when learning the new sequence. INTERPRETATION: The results provided direct evidence that, for this group of dyslexic adults, the behavioural signs of cerebellar abnormality reflect underlying abnormalities in cerebellar activation.

Cerebral control of unimanual and bimanual movements: an H2(15)O PET study.

We measured regional cerebral blood flow (rCBF) during unimanual and bimanual movements using H2(15)O PET. Six healthy volunteers performed unimanual, bimanual-symmetric and bimanual-asymmetric ballistic finger movements. The study was designed to minimize anticipation and preparation of movements. Data were analysed using SPM. Unpredictably paced unimanual movements resulted in significant activation of contralateral primary motor-somatosensory cortex (M1-S1) and mesial frontal cortex (p < 0.001). Performance of symmetric bimanual movements resulted in bilateral activation, but no additional activation of mesial frontal cortex was shown. Comparison of asymmetric with symmetric bimanual movements revealed additional recruitment of mesial frontal cortex (p< 0.001). We suggest that rostral mesial frontal cortex facilitates asymmetric non-mirrored bimanual finger movements.

The effect of movement frequency on cerebral activation: a positron emission tomography study.

Knowledge of the effect of performance frequency on activation of motor areas in positron emission tomography (PET) studies is crucial to the interpretation of experiments in which performance is a variable. We studied this effect in six normal right-handed volunteers using H2(15)O PET to measure regional cerebral blood flow (rCBF). Subjects were scanned at rest and while executing joystick movements with the right hand in freely chosen directions at different frequencies. Significant frequency dependent increases in rCBF were demonstrated in contralateral sensorimotor cortex, lateral premotor cortex bilaterally, posterior supplementary motor area (SMA), and ipsilateral cerebellar hemisphere and vermis. The striatum and the right dorsal prefrontal cortex were also activated by joystick movement compared with rest, but the magnitude of activation found in these areas was independent of the frequency of movement. The results suggest that primary motor cortex, posterior SMA, lateral premotor cortex and cerebellum are involved in determining the basic parameters of movement. Frequency dependent activation in these areas suggests phasic activity related to movement. In contrast, activation of the dorsal prefrontal cortex and the striatum is not frequency dependent. This may reflect continuous rather than phasic activity in these areas during the task and suggests their role is not simply related to movement execution but higher level during this free selection joystick task.

The sensory guidance of movement: a comparison of the cerebellum and basal ganglia.

We used positron emission tomography (PET) to compare the contribution of the cerebellum and basal ganglia to the sensory guidance of movement. In one condition the subjects used a computer mouse to draw a series of lines on a computer screen (DRAW). In the second condition the same lines were presented to the subjects, and they had to track the lines with a mouse pointer on the screen (COPY). In a third condition the subjects were again presented with the same lines, and they simply followed movements of the pointer with their eyes (EYES). In the fourth condition, the subjects fixated a central point, ignoring the sequence of presented lines (FIX). The pons and cerebellum were activated more during visually guided tracking than in freely generated drawing (COPY vs DRAW). The basal ganglia were activated equally in both DRAW and COPY. The prefrontal and inferior temporal cortex were activated more when subjects drew lines freely (DRAW) than when they copied them (COPY). We conclude that the cerebellum is specialized for using sensory information to correct movements, but that the basal ganglia are involved both in movements that are self-generated and in movements that are guided by external cues.

Tremor associated with benign IgM paraproteinaemic neuropathy.

The clinical and neurophysiological features of six patients with action tremor of the upper limbs associated with IgM paraproteinaemic neuropathy are described. Symptomatic tremor was confined to the upper limbs and was broadly symmetrical. The frequency of associated rhythmic muscle activity ranged from 2.8 to 5.5 Hz in abductor pollicis brevis and from 3.7 to 5.5 Hz in the forearm flexor muscles. Magnetic brain stimulation, somatosensory evoked potentials (SEPs) and stretch reflex studies did not provide evidence for delayed conduction within central pathways. There was marked slowing of the maximum motor conduction velocities in peripheral nerves. Forearm stretch reflexes were present but their latencies were prolonged. Somatosensory evoked potentials were obtained in the majority of patients, but were delayed. Wrist tremor could be modulated by mechanical perturbations or median nerve electrical shocks. Simple voluntary wrist movements were of normal duration and peak velocity, but the kinematic profile was asymmetric. Each movement was associated with a triphasic EMG pattern in agonist-antagonist-agonist muscles but the durations of the bursts were prolonged and the onset of the second agonist was delayed. These results support the hypothesis that distorted, mistimed peripheral inputs reach a central processor (probably the cerebellum) which although intact is misled into producing tremor in certain parts of the body.

The functional anatomy of remembered saccades: a PET study.

Studies of patients with damage to the dorsolateral prefrontal cortex (DLPFC) and the basal ganglia have shown that these areas are involved in the control of remembered saccades. However, although positron emission tomography (PET) studies of remembered saccades have demonstrated extensive cortical and subcortical activation, they have failed to detect any significant increase in regional cerebral blood flow (rCBF) in these areas. This study was designed to see if these areas could be activated. Eight right-handed male volunteers were studied using H2(15)O PET. Comparison of the rCBF in the remembered saccade task to a rest control state revealed significant activation in both the DLPFC and the basal ganglia, and also the frontal eye fields, the supplementary motor area, the posterior parietal lobe, the cingulate cortex, the striate cortex, the extrastriate cortex and the superior temporal lobe. These findings confirm that remembered saccades are controlled by an extensive cortical and subcortical network, which includes the DLPFC and the basal ganglia.

Self-initiated versus externally triggered movements. I. An investigation using measurement of regional cerebral blood flow with PET and movement-related potentials in normal and Parkinson's disease subjects.

We investigated the functional anatomy of self-initiated and externally triggered movements. Six patients with Parkinson's disease off medication and six age-matched normals were assessed. All subjects had regional cerebral blood flow (rCBF) measurement with PET and recording of movement-related cortical potentials (MRPs) from frontal (F), fronto-central (FC), central (C) and parietal (P) sites to obtain measures of the Bereitschaftspotential (BP). The tasks were (i) self-initiated extension of the right index finger on average once every 3 s, (ii) externally triggered finger extension with the rate yoked to the self-initiated task, and (iii) rest condition with tones presented at a rate yoked with the self-initiated task. For the self-initiated movements, the amplitude of the early and peak BP were lower in Parkinson's disease relative to normals. For the externally triggered movements, the patients and the normals did not differ on any of the measures of cortical negativity prior to movement. For both groups, the late and peak BP components, but not the early component, had a lower amplitude in the externally triggered than the self-initiated movements. In normals, the left primary sensorimotor cortex, the supplementary motor area bilaterally, anterior cingulate, the lateral premotor cortex bilaterally, the insular cortex bilaterally, the left thalamus and the left putamen, parietal area 40 bilaterally and the right dorsolateral prefrontal cortex (DLPFC) were significantly activated during the self-initiated movements relative to rest. For the normals, greater activation of the right DLPFC during the self-initiated movements was the only area that significantly differentiated them from the externally triggered movements. When Parkinson's disease patients and normals were compared for the self-initiated movements relative to rest, normals showed greater activation of the supplementary motor area and anterior cingulate, left putamen, left insular cortex, right DLPFC and right parietal area 40. When the groups were compared for the externally triggered movements relative to rest, the global pattern of blood flow and rCBF change in the two groups did not differ, confirming the absence of group differences in BPs for the externally triggered movements. During the self-initiated movements, the lower amplitude of the early BP in patients with Parkinson's disease as well as the underactivation of the supplementary motor area relative to normals support the premises that (i) the supplementary motor area contributes to the early BP, and (ii) the deficit is self-initiated movements in Parkinson's disease is due to supplementary motor area underactivation. The DLPFC is activated in situations requiring non-routine decision making as in the self-initiated movements.

A positron emission tomography study of cerebral activation associated with essential and writing tremor.

OBJECTIVE: To compare the abnormal patterns of cerebral activation associated with essential and writing tremors. DESIGN: Positron emission tomography using oxygen 15-labeled water was utilized to determine regional cerebral blood flow. Positron emission tomography images that were taken of the brain in individual patients were coregistered with magnetic resonance images of the same brain to ascertain accurate localization of cerebral activation in single patients. Patients with essential tremor underwent scanning at rest, during involuntary postural tremor, and during passive wrist oscillation. Normal control subjects underwent scanning at rest and during voluntary and passive wrist oscillation. Patients with writing tremor underwent scanning while they were holding a pen to paper with consequent involuntary tremor and again while they were holding a pen in the same supinated arm without tremor. SETTING: Research hospital. PATIENTS OR OTHER PARTICIPANTS: Seven patients with essential tremor, six patients with writing tremor, and six matched control subjects. INTERVENTIONS: None. MAIN OUTCOME MEASURES: Regional cerebral blood flow. RESULTS: Essential tremor was associated with abnormal bilateral cerebellar, red nuclear, and thalamic activation. Writing tremor was also associated with abnormal bilateral cerebellar activation. Voluntary wrist oscillation in control subjects caused only ipsilateral cerebellar activation. These findings were evident in single patients, when positron emission tomography images were coregistered with magnetic resonance images and on group analysis of the pooled positron emission tomography data after transformation into stereotaxic space. CONCLUSION: These results indicate that both essential and writing tremors are associated with abnormal bilateral overactivity of cerebellar connections.

Red nuclear and cerebellar but no olivary activation associated with essential tremor: a positron emission tomographic study.

There has been debate as to whether essential tremor has a central origin and over the possible role of the inferior olivary nucleus in its genesis. We used positron emission tomography with radioactive water (H2(15)O) to detect abnormal patterns of cerebral activity associated with this condition, at rest, without tremor, and on posture when the tremor was present. At rest, cerebellar blood flow was significantly increased bilaterally in the group with essential tremor (30-40%) but no increased olivary activity was evident. Essential tremor during arm extension was associated with further abnormal increases in bilateral cerebellar and abnormal red nuclear activation. Again, no olivary overactivity was evident. Voluntary wrist oscillation in control subjects caused only ipsilateral cerebellar activation. We conclude that essential tremor is associated with abnormal bilateral overactivity of cerebellar and red nuclear connections but found no evidence of intrinsic overactivity of the inferior olivary nucleus, as evidenced by raised blood flow.

Cortical control of saccades and fixation in man. A PET study.

To identify cortical regions activated during saccades and visual fixation, regional cerebral blood flow (rCBF) was measured in eight healthy subjects using C15O2 PET during the performance of three tasks: (i) central fixation; (ii) reflexive saccades to random targets; (iii) remembered saccades to locations of recent target appearance. Significant rCBF increases were identified using analysis of covariance and the t statistic (P < 0.001). Compared with central fixation there was activation of striate and extra-striate cortex, posterior parietal cortex (PPC) and frontal eye fields (FEF) during both reflexive and remembered saccades. During remembered saccades there was additional activation of supplementary motor area (SMA), insula, cingulate, thalamus, midbrain, cerebellum and right superior temporal gyrus (Brodmann's area 22). Compared with the individual saccadic tasks, central fixation activated extensive regions of ventromedial (areas 10, 11 and 32) and anterolateral (areas 8, 9, 10, 45 and 46) prefrontal cortex, and foveal visual cortex. We conclude that FEF and PPC are associated with the generation of both reflexive and remembered saccades, with SMA additionally involved during remembered saccades. Sustained voluntary fixation is mediated by prefrontal cortex.

Motor sequence learning: a study with positron emission tomography.

We have used positron emission tomography to study the functional anatomy of motor sequence learning. Subjects learned sequences of keypresses by trial and error using auditory feedback. They were scanned with eyes closed under three conditions: at rest, while performing a sequence that was practiced before scanning until overlearned, and while learning new sequences at the same rate of performance. Compared with rest, both sequence tasks activated the contralateral sensorimotor cortex to the same extent. Comparing new learning with performance of the prelearned sequence, differences in activation were identified in other areas. (1) Prefrontal cortex was only activated during new sequence learning. (2) Lateral premotor cortex was significantly more activated during new learning, whereas the supplementary motor area was more activated during performance of the prelearned sequence. (3) Activation of parietal association cortex was present during both motor tasks, but was significantly greater during new learning. (4) The putamen was equally activated by both conditions. (5) The cerebellum was activated by both conditions, but the activation was more extensive and greater in degree during new learning. There was an extensive decrease in the activity of prestriate cortex, inferotemporal cortex, and the hippocampus in both active conditions, when compared with rest. These decreases were significantly greater during new learning. We draw three main conclusions. (1) The cerebellum is involved in the process by which motor tasks become automatic, whereas the putamen is equally activated by sequence learning and retrieval, and may play a similar role in both. (2) When subjects learn new sequences of motor actions, prefrontal cortex is activated. This may reflect the need to generate new responses. (3) Reduced activity of areas concerned with visual processing, particularly during new learning, suggests that selective attention may involve depressing the activity of cells in modalities that are not engaged by the task.

A positron emission tomography study of essential tremor: evidence for overactivity of cerebellar connections.

The origin of essential tremor is unknown. Animal models have suggested that the inferior olivary nucleus may act as a tremor generator. We used positron emission tomography to study changes in regional cerebral blood flow associated with involuntary postural tremor and passive wrist oscillation in patients with essential tremor. Activation due to voluntary wrist oscillation and arm extension without tremor was studied in normal control subjects. The essential tremor group had bilaterally increased cerebellar blood flow at rest (without tremor) compared with the control group. Involuntary postural tremor was associated with further bilateral cerebellar activation, and also contralateral striatal, thalamic, and sensorimotor cortex activation. Voluntary wrist oscillation, maintained arm extension without tremor, and passive wrist oscillation were all associated with significant ipsilateral rather than bilateral cerebellar activation. We conclude that essential tremor is associated with increased bilateral cerebellar activity both at rest and during tremor.