The relationship between characteristics of gait disturbance and injury patterns of the corticospinal tract and corticoreticular pathway in post-stroke patients: A case series of 3 patients.

RATIONALE: Corticospinal tract (CST) and corticoreticular pathway (CRP) injury patterns (i.e., the continuity of the nerve fibers) are associated with gait disturbance in post-stroke patients. In this case series study, we examined the case of 3 patients with different CST and CRP injury patterns and analyzed the characteristics of gait disturbance in each patient. PATIENT CONCERNS: Patient 1 (P1) was a 73-year-old woman who presented with paralysis of the right upper and lower extremities due to a left lacunar infarction. Patient 2 (P2) was a 41-year-old man who presented with paralysis of the right upper and lower extremities due to a left putamen hemorrhage. Patient 3 (P3) was a 57-year-old man who presented with paralysis of the left upper and lower extremities due to a right putamen hemorrhage. DIAGNOSIS: In P1, the CRP in the affected hemisphere was intact, but the CST was discontinuous. In P2, the CST in the affected hemisphere was intact, but the CRP was discontinuous. P3 was discontinuous in both CST and CRP in the affected hemisphere. OUTCOMES: Over time, all 3 patients improved to the level of gait independence, but they exhibited different gait patterns. Among them, P3 showed a markedly abnormal gait pattern that included spatiotemporal gait asymmetry, lateral shift of the trunk, and hip hiking. LESSONS: This case series study demonstrated that even if both the CST and CRP were injured, gait recovered to some extent (i.e., independent level-ground gait), but the abnormal gait pattern might remain remarkable.

Kinetic and kinematic parameters associated with late braking force and effects on gait performance of stroke patients.

Late braking force (LBF) is often observed in the late stance phase of the paretic lower limb of stroke patients. Nevertheless, the effects and association of LBF remain unclear. We examined the kinetic and kinematic parameters associated with LBF and its effect on walking. Herein, 157 stroke patients were enrolled. Participants walked at a comfortable speed selected by them, and their movements were measured using a 3D motion analysis system. The effect of LBF was analyzed as a linear relationship with spatiotemporal parameters. Multiple linear regression analyses were performed with LBF as the dependent variable and kinetic and kinematic parameters as independent variables. LBF was observed in 110 patients. LBF was associated with decreased knee joint flexion angles during the pre-swing and swing phases. In the multivariate analysis, trailing limb angle, cooperativity between the paretic shank and foot, and cooperativity between the paretic and non-paretic thighs were related to LBF (p < 0.01; adjusted R2 = 0.64). LBF in the late stance phase of the paretic lower limb reduced gait performance in the pre-swing and swing phases. LBF was associated with trailing limb angle in the late stance, coordination between the paretic shank and foot in the pre-swing phase, and coordination between both thighs.

Effect of Leg Length Discrepancy on Dynamic Gait Stability.

Objectives: : It is unclear whether the increased center of mass lateral shift during gait induced by leg length difference induces lateral instability. The purpose of this study was to investigate the effect of leg length discrepancy (LLD) on dynamic gait stability and the compensatory kinematic and dynamic strategies for this effect by using the extrapolated center of mass and margin of stability. Methods: : Nineteen healthy male participants walked without insoles (no LLD condition; 0 cm) and with added insoles (LLD condition; 3 cm). Kinematic and kinetic data were analyzed using a three-dimensional motion analyzer and force plates; the values were compared between the two conditions. Correlation analysis was performed on the parameters and the margin of stability and significant changes were identified. Results: Compared with the no-LLD condition, in the LLD condition, lateral stability was maintained on both the short leg side and the long leg side. Nonetheless, changes in joint angles and muscle activity on the frontal plane were observed on the short leg side, although the correlations were not significant. On the long leg side, a moderate negative correlation was found between the lateral flexion angle of the trunk and the margin of stability (r=-0.56, P=0.011). Conclusions: The short leg side may compensate for lateral stability by complex changes in joint angles and muscle activity, and the long leg side may compensate for lateral stability by actively adjusting the trunk lateral flexion angle.

Influence of gait exercise using a walking-assist robot for swing-leg motion in hemiplegic stroke patients: a preliminary study focusing on the immediate effect.

Fujii R, Tamari M, Nonaka Y, Tamiya F, Hosokawa H, Tanaka S. Influence of gait exercise using a walking-assist robot for swing-leg motion in hemiplegic stroke patients: A preliminary study focusing on the immediate effect. Jpn J Compr Rehabil Sci 2022; 13: 49-55. Objective: We analyzed the effect of gait training using a walking-assist robot that assists a subject's knee joint movement and leg swing to achieve toe clearance of the paralyzed-side lower limb during treadmill walking. Methods: The subjects were 10 hemiplegic stroke patients in a rehabilitation ward. The intervention consisted of gait training using the Welwalk WW-1000 (Welwalk) robot for 40 min. Immediately before and after this intervention, a gait analysis of the patients' treadmill walking was performed by a three-dimensional motion capture system. Statistical analyses compared the foot-to-floor distance and the shortening of hip-toe length (SHTL) of the paralyzed side before and after the intervention, and examined the relationship between the change of lower-limb joint kinematics and toe clearance before and after the intervention. Results: The post-intervention SHTL was significantly lower compared to before the intervention, and there was a significant negative correlation between the change in the SHTL and the knee flexion angle from before to after the intervention. Conclusion: Gait exercise using the Welwalk could contribute to the acquisition of more normal leg-swing strategies.

Effect of spasticity of the ankle plantar flexors on the walking speed of hemiplegic stroke patients after maximum walking speed exercises.

Yamada T, Ohta M, Tamari M. Effect of spasticity of the ankle plantar flexors on the walking speed of hemiplegic stroke patients after maximum walking speed exercises. Jpn J Compr Rehabil Sci 2021; 12: 64-69. Objective: This study examined the effect of ankle plantar flexor spasticity on the walking speed of hemiplegic stroke patients immediately following maximum walking speed exercises. Methods: A total of 23 hemiplegic stroke patients were divided into two groups based on the presence (n = 13) or absence (n = 10) of ankle plantar flexor spasticity on the paralyzed side. Gait speed, propulsive force during pre-swing, paretic side ankle plantar flexion movement during pre-swing, paretic side ankle dorsiflexion angle during the stance phase, angular velocity of paretic side dorsiflexion during the stance phase, paretic side trailing limb angle in the terminal stance, paretic side plantar flexion angle in the terminal stance, and the timing of maximum dorsiflexion of the ankle joint on the paretic side were measured before and after the maximum walking speed exercises, using a three-dimensional motion analyzer. Results: In the spasticity group, no significant improvement was observed in any of the categories. In contrast, in the non-spasticity group, significant improvement was observed in all categories, except for the paretic side ankle dorsiflexion angle. Conclusion: This study showed that maximum walking speed exercises immediately improved walking speed in hemiplegic stroke patients without ankle plantar flexor spasticity.

Predicative factors of the effect of Body Weight Support Treadmill Training in stroke hemiparesis patients.

[Purpose] The aim of this study was to determine if gait index predicts the efficacy of weight-support treadmill training (BWSTT) in hemiplegic stroke patients. [Participants and Methods] In total, 21 patients who had sustained a hemiplegic stroke, on an average 71 days prior, and could walk independently on level ground were included in the study. BWSTT was performed under 20% of bodyweight unloading at the maximum speed possible for each participant to a perceived level of fatigue of 15 on the 20-point Borg scale. The immediate effects of BWSTT were evaluated as the change in the following variables, calculated from 5 level ground gait cycles; walking speed and rate, root mean square, coefficient of variability, auto-correlation coefficient, and single leg stance time ratio. All indices were calculated from the triaxial accelerometer attached to the waist of the participant. Linear regression was used to identify predictive variables of BWSTT effectiveness. [Results] Only single leg stance time ratio on level ground was extracted as a predictor of BWSTT effectiveness. [Conclusion] Single leg stance time ratio was a predictive factor of improved gait symmetry after BWSTT and therefore, could be used as a factor to select patients who might benefit from BWSTT as a component of stroke rehabilitation.

Greater functional activation during galvanic vestibular stimulation is associated with improved postural stability: a GVS-fMRI study.

PURPOSE: Previous literature has shown that standing stability relies on the vestibular system; however, the neural correlates underlying standing stability remains unclear. This study aimed to investigate the neural correlates of standing stability using functional magnetic resonance imaging (fMRI) following galvanic vestibular stimulation (GVS). MATERIALS AND METHODS: Forty-five healthy right-handed healthy volunteers were included. Postural stability was measured using the modified Clinical Test of Sensory Interaction and Balance (mCTSIB), which measures swaying speed and area on hard and soft surfaces when the volunteer's eyes are open and closed. Functional activation as determined by the blood oxygenation level-dependent (BOLD) response, was measured during GVS using fMRI. We investigated the association between BOLD responses during GVS and postural stability. RESULTS: Relative to rest, participants showed significantly higher BOLD signal during GVS in the parietal operculum, central operculum, and the opercular part of the inferior frontal gyrus. Moreover, functional activation in the central operculum was negatively correlated with standing stability, indexed using swaying speed when volunteers stood on a foam surface with their eyes closed. CONCLUSIONS: Our findings suggest that the neural correlates of standing stability involve greater functional activation in the central operculum.

Relationship between walking ability of patients with stroke and effect of body weight-supported treadmill training.

[Purpose] Reports on the amount of unloading maximizing walking ability in patients with stroke are limited. The effect of body weight-supported treadmill training (BWSTT) in patients with stroke has not been clarified. We aimed to investigate the effects of unloading rate during BWSTT on the gait of patients with stroke and the relationship between BWSTT and walking ability on flat ground. [Participants and Methods] We performed BWSTT in 17 patients at three unloading rates: 0%, 20%, and 40%. Then, we examined the walking speed and rate, number of steps, single-leg support time ratio, and root mean square before and after unloading. Furthermore, we examined the relationship between walking ability on flat ground and immediate effects of BWSTT at each unloading rate. [Results] We observed no significant improvement under all conditions. However, walking ability improved at unloading rates of 20% and 40%, with poor temporal symmetry while walking on flat ground. [Conclusion] Our results revealed that BWSTT has diverse effects depending on the unloading rate and the ability to walk on flat ground. In particular, it tends to be highly effective for those who have poor sway and symmetry, which may serve as an index for prescribing BWSTT.

Relationship between white matter fiber damage and revised version of the ability for basic movement scale in patients with stroke: a diffusion tensor tract-based spatial statistic study.

[Purpose] To clarify the relationship between white matter fiber damage and the Ability for Basic Movement Scale (ABMS) II in patients with stroke in a diffusion tensor tract-based spatial statistic study. [Subjects and Methods] Twelve patients with stroke (seven men and five women, mean age ± SD: 61.6 ± 8.5 years) were evaluated using the ABMS II. The patients were divided into the ABMS II good group and the ABMS II poor group. Tract-based spatial statistical analysis was performed using diffusion tensor images in both groups. [Results] Patients in the ABMS II good group had significantly higher fractional anisotropy values of the anterior thalamic radiation (ATR), superior longitudinal fasciculus (SLF), inferior occipitofrontal fasciculus (IOF), and uncinate fasciculus (UF) of the lesion-containing hemisphere than patients in the ABMS II poor group. [Conclusion] ATR, SLF, and IOF damage may affect ABMS II scores in patients with stroke.