Kenzo Miyamoto

A new simple performance test focused on agility in elderly people: The Ten Step Test.

Background: Not only the reduction of muscle strength or balance, but also the reduction of the agility are regarded as important factors of falls in elderly people. If an agility test for elderly people is established, the precision of the fall prediction rises and can be used for individual training. Objectives: To develop a new performance test focused on agility for elderly people and to evaluate the usefulness of this test. Design: Cross-sectional study. Setting: The Welfare Center of Kagami Town, Kagami Town Office, etc., Kochi, Japan. Participants: 828 community-dwelling, independent adults aged 20–99 years with no obvious cognitive or functional disability, were randomly recruited from Kagami town and the surrounding areas. Measurements: The Ten Step Test (TST, a new performance test), motor reaction time (MRT), knee extensor isometric strength, single leg standing time (SLST), and some other tests were used to evaluate the criterion-related validity and the content validity. TST was developed as a modified version of other step tests which require the subjects to place the whole foot on a block, then return it to the floor. In addition, female participants over 70 were asked whether or not they had fallen in the past year. Results: Excellent reliability for TST was found for interrelation (intra-class correlation coefficients, ICC = 0.96), and re-test reliability was sufficient (ICC = 0.86). Evidence for criterion-related validity was found through high single correlation with the timed supine-to-stand (r = 0.68) and high single correlation with MRT (r = 0.59). In addition, content validity was found through low correlation with knee extensor strength (–0.35) and SLST (–0.36) in 112 women over 70 years of age. The error rate by TST to predict falls (35.2%) was lower than the error rate by muscle strength (44.4%) and the balance (38.7%). TST confirmed decline after 50 years of age, and it conformed to a cubic curve. Conclusion: The findings indicate that TST is a reliable measure of agility, and it can help to predict the risk of falls. The decline of agility accelerates after 50 years of age. It shows that the decline of agility differs from the decline of leg muscle strength and balance.

Interaction interference between arm and leg: Division of attention through muscle force regulation

The first purpose of this study was to examine whether decreases in muscle force similar to the bilateral deficit occur during simultaneous use of arm and leg. The second purpose was to examine the effect on the muscle force of one leg by a division of attention through the regulation of the muscle force in the arm. Six participants completed each of the following three tasks in a random order: (1) maximal unilateral flexion of the right or left elbow, (2) maximal unilateral extension of the left knee, and (3) multilimb effort (a maximal contraction of the muscles in the leg while maintaining a constant submaximal isometric elbow flexion force at 25%, 50%, 75%, or 100% MVC). The results showed that muscle force was lower during simultaneous exertion of arm and leg than during exertion of one limb alone. The maximal knee extension force was significantly (p<.05) lower, by as much as 40% or so, during regulation at 25% MVC. The division of attention is also thought to be involved in task execution and may thus explain the test results. A decrease in the muscle force of the leg due to the level of regulation of the muscle force of the arm indicates that the regulation of the muscle force affects the division of attention, and the finer level of muscle force regulation is a task that requires greater attention. When the muscle force is precisely controlled, a more accurate and more appropriate adjustment is required to focus attention.

Defective imitation of finger configurations in patients with damage in the right or left hemispheres: An integration disorder of visual and somatosensory information?

HighlightsLeft or right brain damage (LBD or RBD) impaired finger configuration imitation.Impaired imitation in RBD patients was observed whether or not vision was available.Impaired imitation in LBD patients was exacerbated by the removal of vision.This is partly due to an abnormal integration of vision and somatosensation. Abstract To explore the mechanism underlying the imitation of finger gestures, we devised a simple imitation task in which the patients were instructed to replicate finger configurations in two conditions: one in which they could see their hand (visual feedback: VF) and one in which they could not see their hand (non‐visual feedback: NVF). Patients with left brain damage (LBD) or right brain damage (RBD), respectively, were categorized into two groups based on their scores on the imitation task in the NVF condition: the impaired imitation groups (I‐LBD and I‐RBD) who failed two or more of the five patterns and the control groups (C‐LBD and C‐RBD) who made one or no errors. We also measured the movement‐production times for imitation. The I‐RBD group performed significantly worse than the C‐RBD group even in the VF condition. In contrast, the I‐LBD group was selectively impaired in the NVF condition. The I‐LBD group performed the imitations at a significantly slower rate than the C‐LBD group in both the VF and NVF conditions. These results suggest that impaired imitation in patients with LBD is partly due to an abnormal integration of visual and somatosensory information based on the task specificity of the NVF condition.

Comparison of timing and force control of foot tapping between elderly and young subjects

[Purpose] To examine the ability of young and elderly individuals to control the timing and force of periodic sequential foot tapping. [Subjects and Methods] Participants were 10 young (age, 22.1 ± 4.3 years) and 10 elderly individuals (74.8 ± 6.7 years) who were healthy and active. The foot tapping task consisted of practice (stimulus-synchronized tapping with visual feedback) and recall trials (self-paced tapping without visual feedback), periodically performed in this order, at 500-, 1,000-, and 2,000-ms target interstimulus-onset intervals, with a target force of 20% maximum voluntary contraction of the ankle plantar-flexor muscle. [Results] The coefficients of variation of force and intertap interval, used for quantifying the steadiness of the trials, were significantly greater in the elderly than in the young individuals. At the 500-ms interstimulus-onset interval, age-related effects were observed on the normalized mean absolute error of force, which was used to quantify the accuracy of the trials. The coefficients of variation of intertap interval for elderly individuals were significantly greater in the practice than in the recall trials at the 500- and 1,000-ms interstimulus-onset intervals. [Conclusion] The elderly individuals exhibited greater force and timing variability than the young individuals and showed impaired visuomotor processing during foot tapping sequences.