Second somatosensory area (SII) plays a significant role in selective somatosensory attention.

Full Abstract

In order to explore human cortical areas involved in active attention toward a somatosensory modality, somatosensory evoked cortical magnetic fields were recorded in ten healthy adults with a 122-channel whole-head magnetometer while the subjects performed the selective attention task. Two kinds of stimulus modality, somatosensory and auditory, were presented independently in the same session. For the somatosensory modality, a randomized sequence of strong (P=0.45) and weak (P=0.05) electric stimuli was delivered to the right median nerve at the wrist. For the auditory modality, a randomized sequence of 900-Hz (P=0.45) and 950-Hz (P=0.05) tones was delivered to both ears. Subjects were requested to pay attention to the specified stimulus modality (either somatosensory or auditory) and to count the number of rare stimuli of the attended modality (weak stimuli in the somatosensory or 950-Hz tone in the auditory modality). A total of 12 sessions were performed for each subject, among which the order of attended modality was changed alternately and counterbalanced among subjects. In the data analysis, somatosensory evoked fields for frequent stimuli (strong electric stimuli) were compared between the two conditions; attend somatosensory condition (ATS) and attend auditory condition (non-attend somatosensory condition; NATS). In six out of the ten subjects, somatosensory evoked fields showed attention-related change. The magnitude of the estimated generator source in SII, but not in SI, significantly increased from NATS to ATS while keeping the same locations. Moreover, a simulation study using the estimated sources in SII in NATS supported the enhancement of the activity in the SII rather than participation of additional sources in the selective attention task. These results suggest that the SII plays a main role in selective somatosensory attention.

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Author information

Author/s: Fujiwara, Naohito (N); Imai, Makoto (M); Nagamine, Takashi (T); Mima, Tatsuya (T); Oga, Tatsuhide (T); Takeshita, Kazuhide (K); Toma, Keiichiro (K); Shibasaki, Hiroshi (H);

Affiliation: Department of Brain Pathophysiology, Human Brain Research Center, Kyoto University Graduate School of Medicine, Shogoin, Sakyo-ku, Kyoto 606-8507, Japan.

Journal and publication information

Publication Type: Journal Article; Research Support, Non-U.S. Gov't

Journal: Brain research. Cognitive brain research (Brain Res Cogn Brain Res), published in Netherlands. (Language: eng)

Reference: 2002-Nov; vol 14 (issue 3) : pp 389-97

Dates: Created 2002/11/07; Completed 2003/02/07; Revised 2006/11/15;

PMID: 12421662, status: MEDLINE (last retrieval date: 11/6/2008)

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