[Purpose] This study aimed to clarify the effects of therapeutic ultrasound on range of
motion and stretch pain and the relationships between the effects. [Subjects] The subjects
were 15 healthy males. [Methods] Subjects performed all three interventions: (1)
ultrasound (US group), (2) without powered ultrasound (placebo group), and (3) rest
(control group). Ultrasound was applied at 3鈥匨Hz with an intensity of 1.0鈥匴/cm2
and a 100% duty cycle for 10 minutes. The evaluation indices were active and passive range
of motion (ROM), stretch pain (visual analog scale; VAS), and skin surface temperature
(SST). The experimental protocol lasted a total of 40 minutes; this was comprised of 10
minutes before the intervention, 10 minutes during the intervention (US, placebo, and
control), and 20 minutes after the intervention. [Results] ROM and SST were significantly
higher in the US group than in the placebo and control groups for the 20 minutes after
ultrasound, though there was no change in stretch pain. [Conclusion] The effects of
ultrasound on ROM and SST were maintained for 20 minutes after the intervention. The SST
increased with ultrasound and decreased afterwards. Additionally, the SST tended to return
to baseline levels within 20 minutes after ultrasound exposure. Therefore, these effects
were caused by a combination of thermal and mechanical effects of the ultrasound.
This study's aim was to evaluate the characteristics of newborn and young infants' spontaneous lower extremity movements by using dynamical systems analysis. Participants were 8 healthy full-term newborn infants (3 boys, 5 girls, mean birth weight and gestational age were 3070.6 g and 39 weeks). A tri-axial accelerometer measured limb movement acceleration in 3-dimensional space. Movement acceleration signals were recorded during 200 s from just below the ankle when the infant was in an active alert state and lying supine (sampling rate 200 Hz). Data were analyzed linearly and nonlinearly. As a result, the optimal embedding dimension showed more than 5 at all times. Time dependent changes started at 6 or 7, and over the next four months decreased to 5 and from 6 months old, increased. The maximal Lyapnov exponent was positive for all segments. The mutual information is at its greatest range at 0 months. Between 3 and 4 months the range in results is narrowest and lowest in value. The mean coefficient of correlation for the x-axis component was negative and y-axis component changed to a positive value between 1 month old and 4 months old. Nonlinear time series analysis suggested that newborn and young infants' spontaneous lower extremity movements are characterized by a nonlinear chaotic dynamics with 5 to 7 embedding dimensions. Developmental changes of an optimal embedding dimension showed a U-shaped phenomenon. In addition, the maximal Lyapnov exponents were positive for all segments (0.79-2.99). Infants' spontaneous movement involves chaotic dynamic systems that are capable of generating voluntary skill movements.
The effects of ultrasound were maintained for 20 minutes after the trial on intramuscular blood circulation and oxygen dynamics. These effects were caused by a combination of thermal and mechanical effects of the ultrasound.
[Purpose] This study aimed to clarify the immediate effects of a combined transcutaneous
electrical nerve stimulation and stretching protocol. [Subjects] Fifteen healthy young
males volunteered to participate in this study. The inclusion criterion was a straight leg
raising range of motion of less than 70 degrees. [Methods] Subjects performed two
protocols: 1) stretching (S group) of the medial hamstrings, and 2) tanscutaneous
electrical nerve stimulation (100 Hz) with stretching (TS group). The TS group included a
20-minute electrical stimulation period followed by 10 minutes of stretching. The S group
performed 10 minutes of stretching. Muscle hardness, pressure pain threshold, and straight
leg raising range of motion were analyzed to evaluate the effects. The data were collected
before transcutaneous electrical nerve stimulation (T1), before stretching (T2),
immediately after stretching (T3), and 10 minutes after stretching (T4). [Results]
Combined transcutaneous electrical nerve stimulation and stretching had significantly
beneficial effects on muscle hardness, pressure pain threshold, and straight leg raising
range of motion at T2, T3, and T4 compared with T1. [Conclusion] These results support the
belief that transcutaneous electrical nerve stimulation combined with stretching is
effective in reducing pain and decreasing muscle hardness, thus increasing range of
motion.
Light-reaction time was not significantly influenced by dentures wearing in Sitting Group performing a light body movement that required little muscular force. In a relatively heavy body movement that required agility (i.e., jumping from the standing position), the reactivity changed depending on the muscular force; which might result in the difference of the reactivity due to dentures wearing (i.e., t-test showed a significant difference in the light-reaction time under clenching posture between with and without wearing dentures (p < 0.01)). No significant difference was observed in body sway under clenching posture between with and without wearing dentures.Therefore, we assumed that reaction speed varied depending upon dentures wearing.
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