Naomi Kuboyama scite author profile

It remains unclear whether activation kinetics in the motor cortex area is affected by training. The purpose of the present study was to examine the effect of training on the motor cortex activation. To accomplish this, the correlation between maximal voluntary contraction and motor cortex (M1) activity was examined. Differences in the motor cortex activation between two groups during exercise were examined in 14 male volunteer participants (M age 25.2 yr., SD = 1.4): seven highly trained athletes (VO2max = 60 ml/kg/min.; maximal voluntary contraction > 55 kg, M MVC = 63.6 kg, SD = 4.2) and seven nonathletes (VO2max < 45 ml/ kg/min.; MVC < 50.0 kg, M MVC = 4 3.5 kg, SD = 5.2). Participants were familiarized with the study protocol during which they performed a maximal voluntary static handgrip test. Specifically, M1 activation was measured by near-infrared spectroscopy throughout a handgrip exercise in which participants performed a sustained middle-intensity handgrip exercise (50% of maximal voluntary contraction) until voluntary exhaustion. In the Athlete group, activation in the M1 at voluntary exhaustion fell below the resting value. In the Nonathlete group, activation in the M1 was elevated throughout the exercise. Results suggest that motor signals from the motor cortex area correlate with exercise training status, especially during fatiguing exercise.

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Human motor cortex oxygenation during exhaustive pinching task

Shibuya

Kuboyama

2007

Brain Research

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Relationship between Cerebral Activity and Movement Frequency of Maximal Finger Tapping

Kuboyama

Nabetani

Shibuya

et al. 2005

J. Physiol. Anthropol.

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To examine the cerebral activity of the motor cortex during maximum movement, we measured regional cerebral blood flow (rCBF) in twelve normal volunteers, using near infrared spectroscopy (NIRS). Repetitive tapping of the right index finger was performed at 1.0, 1.5, 2.0, 2.5, 3.0, 3.5, 4.0, and 4.5 Hz, and during maximum effort (ME). The relative increase rate of rCBF during movement beginning with a resting condition was calculated for each movement condition. The left primary sensorimotor cortex showed significant activation during ME compared to the other frequencies. The rapid increase of rCBF was seen immediately after the initiation of finger tapping at all the tested frequencies but showed no increase following that. However, the rCBF during ME continued to increase until the end of the task. Change of the integrated electromyogram (iEMG) for the frequency and change of rCBF for the frequency at all the tested frequencies showed similar tendencies.

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The Effect of Maximal Finger Tapping on Cerebral Activation

Kuboyama

Nabetani

Shibuya

et al. 2004

J. Physiol. Anthropol.

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The purpose of the present study was to investigate the effect of the repetition rate of a simple movement on the magnitude of neuronal recruitment at maximal effort in humans. Nine right-handed healthy subjects [age: 27.4Ϯ4.8 yr, stature: 174.5Ϯ12.2 cm, body-weight 74.3Ϯ16.6 kg (MeanϮSD)] participated in this study. We measured the regional cerebral hemodynamics using 24-channel near infrared spectroscopy (NIRS). An auditory-cued, repetitive flexion movement of the right index finger against a button was performed as the fingertapping task at maximal effort (ME), at 25% of maximal effort (25% ME) and at 50% of maximal effort (50% ME). The increase of the left primary motor cortex hemodynamics during movement relative to the hemodynamics under the resting condition was calculated for each pair of movement conditions. The frequency of finger-tapping was 1.61Ϯ0.18 Hz (25% ME trial), 3.23Ϯ0.36 Hz (50% ME trial), and 6.46Ϯ0.72 Hz (ME trial). The left primary motor cortex showed significant activation under all conditions. The change in total hemoglobin ([tHb]) between the ME trial and the resting value (1.19Ϯ0.93 mmol · mm) was significantly higher than those between the resting value and the 25% ME trial (0.04Ϯ0.04 mmol · mm) or the 50% ME trial (0.08Ϯ0.11 mmol · mm) (p<0.05). There was a 29.8-fold increase of the [tHb] value between the 50% ME trial and the ME trial, but only a 2-fold increase of the [tHb] value between the 25% ME trial and the 50% ME trial. These results demonstrated that the rate of change in regional cerebral hemoglobin at a maximal effort finger-tapping task was much higher than that at a low frequency finger-tapping task.

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Naomi Kuboyama

Cerebral oxygenation during intermittent supramaximal exercise

Decreased Activation in the Primary Motor Cortex Area during Middle-Intensity Hand Grip Exercise to Exhaustion in Athlete and Nonathlete Participants

Human motor cortex oxygenation during exhaustive pinching task

Relationship between Cerebral Activity and Movement Frequency of Maximal Finger Tapping

The Effect of Maximal Finger Tapping on Cerebral Activation

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