Kuniharu Okuda

Quickness of trunk movements in a seated position, regardless of the direction, is more important to determine the mobility in the elderly than the range of the trunk movement

Although trunk function is known to be critical for maintaining balance during gait, a detailed evaluation regarding the relationship between trunk function and mobility has not been performed. We previously reported that the ability of quick lateral trunk movements in a seated position reflects mobility in elderly people. In this study, we further examined whether trunk movement in the anterior-posterior direction is also a determinant of mobility. In addition, the correlation between range of lateral trunk movement and mobility was also examined. One hundred and forty community-dwelling elderly participants (73.3±6.2 years) were enrolled in this study. We performed various trunk movement tests in a seated position, such as the seated side tapping test (SST), the seated anterior-posterior tapping test (APT), and the lateral sitting functional reach test (sitting reach test). Maximum gait speed and the timed up and go test (TUG) were performed to determine mobility. Parameters of trunk movement were compared. SST and APT showed moderate significant correlations with both maximum gate speed and TUG, while the sitting reach test weakly correlated (SST r=-0.58, p<0.01, APT r=-0.63, p<0.01, sitting reach test r=0.30, p<0.01). Moreover, multiple regression analysis revealed that SST and APT were independent indicators of both maximum gate speed and TUG, while the sitting reach test was not. These findings indicate that quickness, regardless of the direction of the movement, is more important than range in determining mobility in the elderly.

Maximum movement velocity of the upper limbs reflects maximum gait speed in community-dwelling adults aged older than 60 years.

A number of studies have shown that the maximum movement velocity of the lower limbs is a critical determinant of gait speed in elderly adults. However, it is still unclear whether gait speed is associated with the movement velocity of the lower limbs or the movement velocity itself. Therefore, we measured the movement velocity of upper limbs that would not have a direct effect on gait, and examined the relationship between the movement velocity and gait speed.

Carbon Dioxide Water Bathing Enhances Myogenin but Not MyoD Protein Expression after Skeletal Muscle Injury

[Purpose] We reported that carbon dioxide (CO2) water bathing accelerates skeletal muscle regeneration; however, the underlying mechanism was unclear. MyoD and myogenin play roles in muscle regeneration, and the purpose of this study was to determine changes in MyoD and myogenin caused by CO2 water bathing after injury. [Subjects] Sixteen female Wistar rats (n = 4 per group) were used. [Methods] The rats were divided into four groups: no-injury (NI), injury (IC), injury + tap water bathing (ITW), and injury + CO2 water bathing (ICO2). Muscle injury was induced by injection of bupivacaine hydrochloride into the left tibial anterior (TA) muscles. Tap water and CO2 (1,000 ppm) water bathing were performed at 37 °C for 30 minutes once a day. The left TA muscles were removed 4 days after injury, and the expressions of MyoD and myogenin were measured. [Results] MyoD and myogenin were increased in the IC, ITW, and ICO2 groups compared with the NI group. Although the MyoD level was similar in the IC, ITW, and ICO2 groups, myogenin increased more in the ICO2 group than in the IC and ITW groups. [Conclusion] CO2 water bathing after muscle injury appears to induce an increase in the expression of myogenin.

The effect of transverse prosthetic alignment changes on socket reaction moments during gait in individuals with transtibial amputation

BACKGROUND Alignment affects gait of individuals with transtibial prostheses. Sagittal and coronal alignment changes of the transtibial prostheses were demonstrated to affect socket reaction moments. However, the effects of transverse alignment changes on the socket reaction moments are not known. RESEARCH QUESTION The aim of this study was to investigate the effects of transverse alignment changes on the socket reaction moments and temporal-spatial parameters of gait in transtibial prostheses. METHODS The effects of transverse prosthetic alignment changes (i.e. 10° and 5° of internal and external rotations: toe-in and toe-out of the foot relative to the socket from a baseline alignment) on the sagittal and coronal socket reaction moments and temporal-spatial parameters (gait speed, cadence and step width) while walking in 9 individuals with transtibial amputation were investigated using an instrumented prosthetic pyramid adaptor and a three-dimentional (3D) motion capture system. RESULTS The transverse alignment changes demonstrated significant effects on the socket reaction moments in the coronal plane at 5% (P =  0.04), 20% (P =  0.04) and 75% (P =  0.0001) of stance phase. No significant effects were found in the socket reaction moments in the sagittal plane and the temporal-spatial parameters. The internal and external rotations of the prosthetic feet may have opposite effect in early and mid- to late-stance potentially due to changes in the spatial position of the heel (rearfoot) and toe (forefoot) of the prosthetic foot relative to the socket. SIGNIFICANCE Transverse alignment of the transtibial prostheses should be tuned not only considering the symmetry in toe-out angles of the feet, but also considering the potential effects of transverse alignment changes that may affect the coronal socket reaction moments.BACKGROUND Alignment affects gait of individuals with transtibial prostheses. Sagittal and coronal alignment changes of the transtibial prostheses were demonstrated to affect socket reaction moments. However, the effects of transverse alignment changes on the socket reaction moments are not known. RESEARCH QUESTION The aim of this study was to investigate the effects of transverse alignment changes on the socket reaction moments and temporal-spatial parameters of gait in transtibial prostheses. METHODS The effects of transverse prosthetic alignment changes (i.e. 10° and 5° of internal and external rotations: toe-in and toe-out of the foot relative to the socket from a baseline alignment) on the sagittal and coronal socket reaction moments and temporal-spatial parameters (gait speed, cadence and step width) while walking in 9 individuals with transtibial amputation were investigated using an instrumented prosthetic pyramid adaptor and a three-dimentional (3D) motion capture system. RESULTS The transverse alignment changes demonstrated significant effects on the socket reaction moments in the coronal plane at 5% (P =  0.04), 20% (P =  0.04) and 75% (P =  0.0001) of stance phase. No significant effects were found in the socket reaction moments in the sagittal plane and the temporal-spatial parameters. The internal and external rotations of the prosthetic feet may have opposite effect in early and mid- to late-stance potentially due to changes in the spatial position of the heel (rearfoot) and toe (forefoot) of the prosthetic foot relative to the socket. SIGNIFICANCE Transverse alignment of the transtibial prostheses should be tuned not only considering the symmetry in toe-out angles of the feet, but also considering the potential effects of transverse alignment changes that may affect the coronal socket reaction moments.

Relationship between the duration and trunk inclination and hip angle during car transfer in individuals with tetraplegia

[Purpose] The purpose of the present study was to investigate the relationship between the duration of the car transfer (CT) movement and trunk inclination and hip angles during this movement in individuals with tetraplegia. [Subjects and Methods] Eleven adult males with C6 tetraplegia participated in this study. The CT movement was recorded from the passenger side of the car using a digital video camera. From the video, the duration and trunk inclination and hip joint angle were recorded, and correlation coefficients were calculated. [Results] No correlation was found between the trunk inclination angle and the duration of the CT movement. However, a significant correlation was found between the hip angle and the duration of the CT movement: when the duration was short, the hip flexion angle was substantial. [Conclusion] The trunk inclination angle probably showed no effect on the duration of the CT movement because the movement was performed in a limited space and because the trunk muscles of the subjects were paralyzed. In contrast, C6 tetraplegia enabled smooth CT by allowing for control of trunk inclination, such as placing the lower extremities in the car, whereby the pelvis backward tilt angle increased.

Muscle activity and mood state during simulated plant factory work in individuals with cervical spinal cord injury

[Purpose] The present study investigated the physical and mental effects of plant factory work in individuals with cervical spinal cord injury and the use of a newly developed agricultural working environment. [Subjects] Six males with C5–C8 spinal cord injuries and 10 healthy volunteers participated. [Methods] Plant factory work involved three simulated repetitive tasks: sowing, transplantation, and harvesting. Surface electromyography was performed in the dominant upper arm, upper trapezius, anterior deltoid, and biceps brachii muscles. Subjects’ moods were monitored using the Profile of Mood States. [Results] Five males with C6–C8 injuries performed the same tasks as healthy persons; a male with a C5 injury performed fewer repetitions of tasks because it took longer. Regarding muscle activity during transplantation and harvesting, subjects with spinal cord injury had higher values for the upper trapezius and anterior deltoid muscles compared with healthy persons. The Profile of Mood States vigor scores were significantly higher after tasks in subjects with spinal cord injury. [Conclusion] Individuals with cervical spinal cord injury completed the plant factory work, though it required increased time and muscle activity. For individuals with C5–C8 injuries, it is necessary to develop an appropriate environment and assistive devices to facilitate their work.