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Query: UMLS:C0030193 (
pain
)
261,466
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The temporal and spatial processing of
pain
perception in human was traced by magnetoencephalography (MEG). We applied a painful CO2 laser beam to the forearm of 11 normal subjects, and estimated the activated areas using a single equivalent current dipole (ECD) at each time point, and a brain electric source analysis (BESA) as a spatio-temporal multiple source analysis method. The four-source model was found to be the most appropriate; sources 1 and 2 at the secondary sensory cortex (
SII
) contralateral and ipsilateral to the stimulation, and sources 3 and 4 at the anterior medial temporal area (probably the amygdalar nuclei or hippocampal formation) contralateral and ipsilateral to the stimulation, respectively. Activities in all 4 areas were temporally overlapped. Activity in the primary sensory cortex (SI) contralateral to the stimulated site was not identified. Activity in the cingulate cortex was also not clearly identified. These results are probably due to one or more of the following factors; (1) the cingulate cortex is too deep, (2) the ECDs generated in the cingulate cortex are mainly oriented radially, and (3) the ECDs generated in bilateral hemispheres interfere with each other. No significant or consistent magnetic fields were recorded after 500 msec following the stimulation, probably due to the complicated spatial and temporal overlapping of activities in multiple areas.
...
PMID:Pain processing traced by magnetoencephalography in the human brain. 967 24
Activation in numerous regions of the brain is likely to be involved in the complex neural network function of
pain
perception. To detect the cortical representation during nonpainful and painful stimuli, which were presented using electrical finger stimulation in six normal right-handed male volunteers, we performed echo-planar functional magnetic resonance imaging (fMRI). Using a 1.5-T MR system that scanned the supratentorial region of the brain, we obtained multislice BOLD-based functional MR images with single-shot gradient-echo echo-planar imaging (EPI). The data show that dispersed brain regions are activated during painful stimulation, and especially demonstrate the significance of the
SII
-insular region in
pain
perception.
...
PMID:Functional mapping of pain-related activation with echo-planar MRI: significance of the SII-insular region. 969 16
The utility of functional magnetic resonance (fMR) imaging in patients with implanted thalamic electrodes has not yet been determined. The aim of this study was to establish the safety of performing fMR imaging in patients with thalamic deep brain stimulators and to determine the value of fMR imaging in detecting cortical and subcortical activity during stimulation. Functional MR imaging was performed in three patients suffering from chronic pain and two patients with essential tremor. Two of the three patients with
pain
had undergone electrode implantation in the thalamic sensory ventralis caudalis (Vc) nucleus and the other had undergone electrode implantation in both the Vc and the periventricular gray (PVG) matter. Patients with tremor underwent electrode implantation in the ventralis intermedius (Vim) nucleus. Functional MR imaging was performed during stimulation by using a pulse generator connected to a transcutaneous extension lead. Clinically, Vc stimulation evoked paresthesias in the contralateral body, PVG stimulation evoked a sensation of diffuse internal body warmth, and Vim stimulation caused tremor arrest. Functional images were acquired using a 1.5-tesla MR imaging system. The Vc stimulation at intensities provoking paresthesias resulted in activation of the primary somatosensory cortex (SI). Stimulation at subthreshold intensities failed to activate the SI. Additional stimulation-coupled activation was observed in the thalamus, the secondary somatosensory cortex (
SII
), and the insula. In contrast, stimulation of the PVG electrode did not evoke paresthesias or activate the SI, but resulted in medial thalamic and cingulate cortex activation. Stimulation in the Vim resulted in thalamic, basal ganglia, and SI activation. An evaluation of the safety of the procedure indicated that significant current could be induced within the electrode if a faulty connecting cable (defective insulation) came in contact with the patient. Simple precautions, such as inspection of wires for fraying and prevention of their contact with the patient, enabled the procedure to be conducted safely. Clinical safety was further corroborated by performing 86 MR studies in patients in whom electrodes had been implanted with no adverse clinical effects. This is the first report of the use of fMR imaging during stimulation with implanted thalamic electrodes. The authors' findings demonstrate that fMR imaging can safely detect the activation of cortical and subcortical neuronal pathways during stimulation and that stimulation does not interfere with imaging. This approach offers great potential for understanding the mechanisms of action of deep brain stimulation and those underlying
pain
and tremor generation.
...
PMID:Thalamic stimulation and functional magnetic resonance imaging: localization of cortical and subcortical activation with implanted electrodes. Technical note. 1006 36
After a painful CO2 laser stimulation to the skin, the magnetoencephalography (MEG) response (164 ms in average peak latency) was not affected by distraction, but the sequential electroencephalography (EEG) responses (240-340 ms), probably generated by a summation of activities in multiple areas, were markedly affected. We suspect that the MEG response, whose dipole is estimated in the bilateral second somatosensory cortex (
SII
) and insula, reflects the primary activities of
pain
in humans.
...
PMID:Effects of distraction on pain perception: magneto- and electro-encephalographic studies. 1021 75
Brain activity was studied with functional magnetic resonance imaging (fMRI) following thermal stimulation. Two groups (n = 6/group) of human male volunteers were given up to four noxious (46 degrees C) and four non-noxious (41 degrees C) stimuli. In the 46 degrees C experiment, positive signal changes were found in the frontal gyri, anterior and posterior cingulate gyrus, thalamus, motor cortex, somatosensory cortex (SI and
SII
), supplementary motor area, insula, and cerebellum. Low-level negative signal changes appeared in the amygdala and hypothalamus. All regions activated by 46 degrees C were also activated by 41 degrees C. However, except for SI and thalamus, significantly more activation was observed for the 46 degrees C stimulus. A significant attenuation of the signal change was observed by the third stimulus for the 46 degrees C, but not for 41 degrees C experiment. Similar findings were replicated in the second group. These fMRI findings specify differences between somatosensory and
pain
sensation and suggest a number of rich avenues for future research.
...
PMID:Human brain activation under controlled thermal stimulation and habituation to noxious heat: an fMRI study. 1033 89
We studied responses of the parieto-frontal opercular cortex to CO2-laser stimulation of A delta fiber endings, as recorded by intra-cortical electrodes during stereotactic-EEG (SEEG) presurgical assessment of patients with drug-resistant temporal lobe epilepsy. After CO2-laser stimulation of the skin at the dorsum of the hand, we consistently recorded in the upper bank of the sylvian fissure contralateral to stimulation, a negative response at a latency of 135 +/- 18 ms (N140), followed by a positivity peaking around 171 +/- 22 ms (P170). The stereotactic coordinates in the Talairach's atlas of the electrode contacts recording these early responses covered the pre- and post-rolandic part of the upper bank of the sylvian fissure (-27 < y < +12 mm; 31 < x < 57 mm; 4 < z < 23 mm), corresponding to the accepted localization of the
SII
area in man, possibly including the upper part of the insular cortex. The spatial distribution of these early contralateral responses in the
SII
-insular cortex fits wit that of the modeled sources of scalp CO2-laser evoked potentials (LEPs) and with PET data from
pain
activation studies. Moreover, this study showed the likely existence of dipolar sources radial to the scalp surface in
SII
, which are overlooked in magnetic recordings. Early responses also occurred in the
SII
area ipsilateral to stimulation peaking 15 ms later than in contralateral
SII
, suggesting a callosal transmission of nociceptive inputs between the two
SII
areas. Other pain responsive areas such as the anterior cingulate gyrus, the amygdala and the orbitofrontal cortex did not show early LEPs in the 200 ms post-stimulus. These findings suggest that activation of
SII
area contralateral to stimulation, possibly through direct thalamocortical projections, represents the first step in the cortical processing of peripheral A delta fiber
pain
inputs.
...
PMID:Intracortical recordings of early pain-related CO2-laser evoked potentials in the human second somatosensory (SII) area. 1034 32
Cerebral processing of
pain
has been shown to involve primary (SI) and secondary (
SII
) somatosensory cortices. However, the temporal activation pattern of these cortices in nociceptive processing has not been demonstrated so far. We therefore used whole-head magnetoencephalography to record cortical responses to cutaneous laser stimuli in six healthy human subjects. By using selective nociceptive stimuli our results confirm involvement of contralateral SI and bilateral
SII
in human
pain
processing. Beyond they show for the first time simultaneous activation onset of contralateral SI and
SII
after approximately 130 ms, indicating parallel thalamocortical distribution of nociceptive information. This contrasts to the serial cortical organization of tactile processing in higher primates and instead corresponds to the parallel cortical organization in lower primates and nonprimates. Thus our finding suggests preservation of the basic mammalian parallel organizational scheme in human
pain
processing, whereas in the tactile modality parallel organization appears to be abandoned in favor of a serial processing scheme. Functionally, preservation of direct access to
SII
underscores the relevance of this area in human
pain
processing, probably reflecting an important role of
SII
in nociceptive learning and memory.
...
PMID:Parallel activation of primary and secondary somatosensory cortices in human pain processing. 1036 26
Magnetoencephalographic (MEG) field recordings are unique to detect current dipoles in SI and
SII
. Few devices are available for painful mechanical stimulation in magnetically shielded MEG rooms. The aim of the present MEG (dual 37-channel biomagnetometer) study was to investigate the location of the cortical generators evoked by painful impact stimuli of different intensities. An airgun was placed outside the shielded MEG room, and small plastic bullets were fired at the arm and trunk of the subjects in the room. The velocity of the bullet was measured and related to the evoked
pain
intensity. Stimuli were delivered for each of the following three conditions: strong
pain
intensity elicited from the upper arm and upper trunk; weak
pain
intensity elicited from the upper trunk. The evoked MEG responses had a major component with the characteristically polarity-reversal deflections indicating a dipole located beneath the coils. The response could be estimated by a single current dipole. When the estimated locations of the dipoles were superimposed on the individual magnetic resonance images (MRIs), consistent bilateral activation of areas corresponding to the secondary sensory cortices (
SII
) was found.
...
PMID:Magnetoencephalographic responses to painful impact stimulation. 1048 16
Parietal, insular and anterior cingulate cortices are involved in the processing of noxious inputs and genesis of
pain
sensation. Parietal lesions may generate central
pain
by mechanisms generally assumed to involve the 'medial'
pain
system (i.e. medial thalamic nuclei and anterior cingulate cortex (ACC)). We report here PET and fMRI data in a patient who developed central
pain
and allodynia in her left side after a bifocal infarct involving both the right parietal cortex (SI and
SII
) and the right ACC (Brodmann areas 24 and 32), thus questioning the schematic representation of cortical
pain
processing. No rCBF increase was found in any part of the residual cingulate cortices, neither in the basal state (which included spontaneous
pain
and extended hypoperfusion around the infarct), nor during left allodynic
pain
. Thus, as previously observed in patients with lateral medullary infarct, neither spontaneous
pain
nor allodynia reproduce the cingulate activation observed after noxious
pain
in normal subjects. Conversely, both PET and fMRI data argue in favour of plastic changes in the 'lateral discriminative'
pain
system. Particularly, allodynia was associated with increased activity anteriorly to the infarct in the right insula/
SII
cortex. This response is likely to be responsible for the strange and very unpleasant allodynic sensation elicited on the left side by a non-noxious stimulation.
Pain
2000 Jan
PMID:Parietal and cingulate processes in central pain. A combined positron emission tomography (PET) and functional magnetic resonance imaging (fMRI) study of an unusual case. 1060 75
Positron emission tomography (PET) and accumulation of H(2)(15)O as a marker of neuronal activity were used to create maps of cerebral blood-flow changes evoked by painful heat stimulation in 10 subjects. Two levels of painful tonic and phasic heat stimuli were applied with use of a newly developed contact heat thermode on the volar surface of the dominant (right) arm. The subjects participated in two separate PET sessions. Maps reflecting low and high levels of painful tonic heat were obtained in the first session, and low and high levels of painful phasic heat in the second session. The subjects scored their peak
pain
intensity and unpleasantness on 10-cm visual analogue scales. For each subject, PET images were aligned to nuclear magnetic resonance (NMR) images and remapped into the standardized co-ordinate system of Talairach. After normalization of the PET volumes, subtraction images were formed voxel-by-voxel and converted to a t-statistic volume. The perceived
pain
intensity and unpleasantness were identical with painful tonic and phasic heat stimulation. Directed searches revealed significant blood-flow increases in the contralateral primary sensorimotor cortex (MI/SI),
SII
, insular cortex and cingulate cortex when the low tonic heat map was subtracted from the high. A similar, but not identical,
pain
-processing network was observed for the maps representing the subtraction of low and high phasic heat. In this subtraction, the blood-flow increases in MSI/SI did not reach statistical significance, and significant blood flow decreases were found in the contralateral middle temporal gyrus. Finally, the location of the activation site in the cingulate cortex was different from that observed during tonic heat
pain
. This study has provided more evidence for the existence of a common
pain
-processing network engaged during the perception of different levels of toxic and phasic heat
pain
. Copyright 1998 European Federation of Chapters of the International Association for the Study of
Pain
.
Eur J
Pain
1998
PMID:Cerebral blood-flow changes evoked by two levels of painful heat stimulation: a positron emission tomography study in humans. 1070 Mar 5
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