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Query: UMLS:C0040822 (
tremor
)
18,428
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Myoclonus, defined as shock-like involuntary movement, may be physiological or caused by a very wide variety of hereditary and acquired conditions. Because myoclonus can originate from different disorders and lesions affecting quite varied levels of the central and peripheral nervous systems, it represents from many points of view a diagnostic challenge. Moreover, new entities have been recently individualized, such as cortical
tremor
, which deserve renewed attention. The aim of this review is to propose a rationale for a diagnostic approach based on clinical and electrophysiological grounds. In this setting, we successively address 1) the clinical features allowing a positive diagnosis of myoclonus; 2) the clinical clues to the etiology; 3) the relevance of the clinical context to the diagnosis; and 4) the contribution of neurophysiology. Differentiating myoclonus from tics, spasm, chorea and dystonia can be difficult, and a careful reappraisal of clinical features allowing precise identification is presented. Moreover, the topographical distribution of myoclonus, the temporal pattern of muscle recruitment, the condition of occurrence and the rhythm of the event, may provide clinical clues relevant to the diagnosis. Myoclonus without associated epilepsy, myoclonus with epilepsy, myoclonus with encephalopathy, parkinsonism and/or dementia represent overlapping clinical categories, although they remain useful for the diagnostic approach. Using electrophysiology (including back-averaging EEG,
MEG
, SEP, C-reflex studies) to determine the origin of myoclonus may not allow us to focus on the underlying condition. Indeed, in many instances, the myoclonus is cortical in origin, but the pathology is found elsewhere.
...
PMID:[Myoclonus in the adult: diagnostic approach]. 1128 Oct 67
Whole-head
MEG
-systems and modern spatial-filter-based analysis tools recently provided new possibilities to analyze non-invasively cerebral networks of human
tremor
syndromes. We compared
tremor
syndromes in Parkinsonian patients with a typical resting
tremor
as well as in patients with hepatic encephalopathy (HE) with a postural
tremor
called "mini-asterixis". In 6 patients with idiopathic Parkinson's disease (PD) we found strong coherence between the electromyography (EMG) of forearm muscles and activity in the contralateral primary motor cortex (M1) at
tremor
frequency but also at double
tremor
frequency. Furthermore, significant coherences were observed between M1 and medial wall areas (CMA/SMA), lateral premotor cortex, diencephalon, SII cortex, posterior parietal cortex and the contralateral cerebellum at
tremor
and, stronger, at double
tremor
frequency. In contrast, in 6 patients with "mini-asterixis" and HE due to chronic liver cirrhosis excessive corticomuscular coherence occurred at the individual
tremor
frequency between EMG and M1 activity. Interestingly, thalamus-M1 coupling was significantly altered towards lower frequencies matching the individual frequency of the mini-asterixis. Cerebro-muscular or cerebro-cerebral coupling at double
tremor
frequency was not observed. Therefore, "mini-asterixis" reflects most likely a pathologically decelerated and augmented synchronized rhythmical motor cortical output. This could be due to functional alterations in the M1-basal-ganglia-thalamo-cortical loops in severe HE. In summary,
tremor
syndromes in PD as well as in patients with HE and "mini-asterixis" are characterized by pathological oscillatory activity within cerebral networks of motor areas. However, the present study shows different mechanisms of
tremor
generation in PD and HE patients.
...
PMID:Pathological oscillatory coupling within the human motor system in different tremor syndromes as revealed by magnetoencephalography. 1601 24
Resting tremor in idiopathic Parkinson's disease (PD) is associated with an oscillatory network comprising cortical as well as subcortical brain areas. To shed light on the effect of levodopa on these network interactions, we investigated 10 patients with
tremor
-dominant PD and reanalyzed data in 11 healthy volunteers mimicking PD resting
tremor
. To this end, we recorded surface electromyograms of forearm muscles and neuromagnetic activity using a 122-channel whole-head magnetometer (
MEG
). Measurements were performed after overnight withdrawal of levodopa (OFF) and 30 min after oral application of fast-acting levodopa (ON). During OFF, patients showed the typical antagonistic resting
tremor
. Using the analysis tool Dynamic Imaging of Coherent Sources, we identified the oscillatory network associated with
tremor
comprising contralateral primary sensorimotor cortex (S1/M1), supplementary motor area (SMA), contralateral premotor cortex (PMC), thalamus, secondary somatosensory cortex (S2), posterior parietal cortex (PPC), and ipsilateral cerebellum oscillating at 8 to 10 Hz. After intake of levodopa, we found a significant decrease of cerebro-cerebral coupling between thalamus and motor cortical areas. Similarly, in healthy controls mimicking resting
tremor
, we found a significant decrease of functional interaction within a thalamus-premotor-motor network during rest. However, in patients with PD, decrease of functional interaction between thalamus and PMC was significantly stronger when compared with healthy controls. These data support the hypothesis that (1) in patients with PD the basal ganglia and motor cortical structures become more closely entrained and (2) levodopa is associated with normalization of the functional interaction between thalamus and motor cortical areas.
...
PMID:Levodopa affects functional brain networks in Parkinsonian resting tremor. 1882 37
Corticokinematic coherence (CKC), i.e., coherence calculated between
MEG
and an accelerometer signal, recording movement kinematics, can be used for functional mapping of the sensorimotor cortex. Cortical sources of CKC, induced by both voluntary and passive movements, localize at the proximity of sensorimotor cortex. We tested the CKC during a static muscle contraction to compare it with simultaneously measured cortico-muscular coherence (CMC) estimated between
MEG
and surface EMG to study the role of postural
tremor
in CMC in ten healthy volunteers. CKC was detectable also during this static task. CKC and CMC spectra had similar power distributions, and sources of CMC and CKC colocalized at the cortex in close proximity of the central sulcus. During the static hold task, the accelerometer signal originates from the postural
tremor
. The similarities between CMC and CKC indicate that postural
tremor
is related to CMC in healthy subjects.
...
PMID:Cortico-muscular coherence parallels coherence of postural tremor and MEG during static muscle contraction. 2611 20
