Your search keyword '"Naruhito Hasui"' showing total 8 results

1. Characteristics of limb kinematics in the gait disorders of post-stroke patients

Author

Naomichi Mizuta, Naruhito Hasui, Takumi Kai, Yasuhiro Inui, Masahiro Sato, Sora Ohnishi, Junji Taguchi, and Tomoki Nakatani

Subjects

Medicine, Science

Abstract

Abstract Post-stroke gait disorders involve altered lower limb kinematics. Recently, the endpoint of the lower limb has been used as a control variable to understand gait kinematics better. In a cross-sectional study of sixty-seven post-stroke patients, the limb extension angle and effective limb length during gait were used as input variables with a mixed Gaussian model-based probabilistic clustering approach to identify five distinct clusters. Each cluster had unique characteristics related to motor paralysis, spasticity, balance ability, and gait strategy. Cluster 1 exhibited high limb extension angle and length values, indicating increased spasticity. Cluster 2 had moderate extension angles and high limb lengths, indicating increased spasticity and reduced balance ability. Cluster 3 had low limb extension angles and high limb length, indicating reduced balance ability, more severe motor paralysis, and increased spasticity. Cluster 4 demonstrated high extension angles and short limb lengths, with a gait strategy that prioritized stride length in the component of gait speed. Cluster 5 had moderate extension angles and short limb lengths, with a gait strategy that prioritized cadence in the component of gait speed. These findings provide valuable insights into post-stroke gait impairment and can guide the development of personalized and effective rehabilitation strategies.

Published

2024

2. Effect of bihemispheric transcranial direct current stimulation on distal upper limb function and corticospinal tract excitability in a patient with subacute stroke: a case study

Author

Takahiro Shiba, Naomichi Mizuta, Naruhito Hasui, Yohei Kominami, Tomoki Nakatani, Junji Taguchi, and Shu Morioka

Subjects

intermuscular coherence, fugl-Meyer assessment, subacute stroke, transcranial direct current stimulation, stroke rehabilitation, Other systems of medicine, RZ201-999, Medical technology, R855-855.5

Abstract

IntroductionActivation of the unaffected hemisphere contributes to motor function recovery post stroke in patients with severe upper limb motor paralysis. Transcranial direct current stimulation (tDCS) has been used in stroke rehabilitation to increase the excitability of motor-related areas. tDCS has been reported to improve upper limb motor function; nonetheless, its effects on corticospinal tract excitability and muscle activity patterns during upper limb exercise remain unclear. Additionally, it is unclear whether simultaneously applied bihemispheric tDCS is more effective than anodal tDCS, which stimulates only one hemisphere. This study examined the effects of bihemispheric tDCS training on corticospinal tract excitability and muscle activity patterns during upper limb movements in a patient with subacute stroke.MethodsIn this single-case retrospective study, the Fugl–Meyer Assessment, Box and Block Test, electromyography, and intermuscular coherence measurement were performed. Intermuscular coherence was calculated at 15–30 Hz, which reflects corticospinal tract excitability.ResultsThe results indicated that bihemispheric tDCS improved the Fugl–Meyer Assessment, Box and Block Test, co-contraction, and intermuscular coherence results, as compared with anodal tDCS. Discussion: These results reveal that upper limb training with bihemispheric tDCS improves corticospinal tract excitability and muscle activity patterns in patients with subacute stroke.

Published

2023

3. Association Between Temporal Asymmetry and Muscle Synergy During Walking With Rhythmic Auditory Cueing in Survivors of Stroke Living With Impairments

Author

Naomichi Mizuta, PT, PhD, Naruhito Hasui, PT, MS, Yuki Nishi, PT, PhD, Yasutaka Higa, PT, Ayaka Matsunaga, PT, Junji Deguchi, PT, PhD, Yasutada Yamamoto, PT, MS, Tomoki Nakatani, PT, Junji Taguchi, MD, PhD, and Shu Morioka, PT, PhD

Subjects

Cues, Central pattern generators, Gait disorders, Hemiplegia, Rehabilitation, Stroke, Medicine (General), R5-920

Abstract

Objective: To examine the relationship between temporal asymmetry and complexity of muscle synergy during walking using rhythmic auditory cueing (RAC) and the factors related to changes in muscle synergy during walking with RAC in survivors of stroke. Design: Cross-sectional study. Setting: Wards at 2 medical corporation hospitals. Participants: Forty survivors of stroke (N=40; mean age, 70.4±10.3 years; time since stroke, 72.2±32.3 days) who could walk without physical assistance. Interventions: Not applicable. Main Outcome Measures: The participants were assessed in a random block design under 2 conditions: comfortable walking speed (CWS) and walking with RAC. Single-leg support time, kinematics, and electromyograms were measured. Factors related to the complexity of muscle synergy (variance accounted for by 1 synergy [VAF1]) between the walking conditions were examined using hierarchical multiple regression analysis. Results: In the RAC condition, lower limb flexion and knee flexion angles, single-leg support time on the paretic side, and the symmetry index of single-leg support time were increased compared with those in the CWS condition. VAF1 was decreased in the RAC condition (73.9±0.15) compared with that in the CWS condition (76.9±0.13, P=.002). Hierarchical multiple regression analysis revealed that the change in VAF1 was explained by change in single-leg support time (R2=0.43, P=.002). Conclusions: The RAC condition demonstrated a more complex representation of muscle synergy than the CWS condition; the change in single-leg support time on the paretic side related to the changes in muscle synergy more than changes in lower limb angle. These findings can help in the walking-training concept to improve muscle synergy deficits in survivors of stroke.

Published

2022

4. Merged swing-muscle synergies and their relation to walking characteristics in subacute post-stroke patients: An observational study.

Author

Naomichi Mizuta, Naruhito Hasui, Yuki Nishi, Yasutaka Higa, Ayaka Matsunaga, Junji Deguchi, Yasutada Yamamoto, Tomoki Nakatani, Junji Taguchi, and Shu Morioka

Subjects

Medicine, Science

Abstract

In post-stroke patients, muscle synergy (the coordination of motor modules during walking) is impaired. In some patients, the muscle synergy termed module 1 (hip/knee extensors) is merged with module 2 (ankle plantar flexors), and in other cases, module 1 is merged with module 4 (knee flexors). However, post-stroke individuals with a merging pattern of module 3 (hip flexor and ankle dorsiflexor) and module 4, which is the swing-muscle synergy, have not been reported. This study aimed to determine the muscle-synergy merging subtypes of post-stroke during comfortable walking speed (cws). We also examined the effect of experimental lower-limb angle modulation on the muscle synergy patterns of walking in each subtype. Forty-one participants were assessed under three conditions: cws, long stepping on the paretic side (p-long), and long stepping on the non-paretic side (np-long). Lower-limb flexion and extension angles and the electromyogram were measured during walking. Subtype classification was based on the merging pattern of the muscle synergies, and we examined the effect of different lower-limb angles on the muscle synergies. We identified three merging subtypes: module 1 with module 2 (subtype 1), module 1 with module 4 (subtype 2), and module 3 with module 4 (subtype 3). In the cws condition, the lower-limb flexion angle was reduced in subtype 3, and the lower-limb extension angle was decreased in subtype 1. A more complex muscle synergy was observed only in subtype 3 in the p-long condition versus cws (p = 0.036). This subtype classification of walking impairments based on the merging pattern of the muscle synergies could be useful for the selection of a rehabilitation strategy according to the individual's particular neurological condition. Rehabilitation with increased lower-limb flexion may be effective for the training of patients with merging of modules 3 and 4 in comfortable walking.

Published

2022

5. Effects of Transcranial Direct Current Stimulation over the Supplementary Motor Area Combined with Walking on the Intramuscular Coherence of the Tibialis Anterior in a Subacute Post-Stroke Patient: A Single-Case Study

Author

Naruhito Hasui, Naomichi Mizuta, Junji Taguchi, Tomoki Nakatani, and Shu Morioka

Subjects

post-stroke, walking, transcranial direct current stimulation, supplementary motor area, intramuscular coherence, gait variability, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Motor recovery is related to the corticospinal tract (CST) lesion in post-stroke patients. The CST originating from the supplementary motor area (SMA) affects the recovery of impaired motor function. We confirmed the effects of transcranial direct current stimulation (tDCS) over the SMA combined with walk training on CST excitability. This study involved a stroke patient with severe sensorimotor deficits and a retrospective AB design. Walk training was conducted only in phase A. Phase B consisted of anodal tDCS (1.5 mA) combined with walk training. Walking speed, stride time variability (STV; reflecting gait stability), and beta-band intramuscular coherence—derived from the paired tibialis anterior on the paretic side (reflecting CST excitability)—were measured. STV quantified the coefficient of variation in stride time using accelerometers. Intramuscular coherence during the early stance phase noticeably increased in phase B compared with phase A. Intramuscular coherence in both the stance and swing phases was reduced at follow-up. Walking speed showed no change, while STV was noticeably decreased in phase B compared with phase A. These results suggest that tDCS over the SMA during walking improves gait stability by enhancing CST excitability in the early stance phase.

Published

2022

6. Effects of Transcranial Direct Current Stimulation of Bilateral Supplementary Motor Area on the Lower Limb Motor Function in a Stroke Patient with Severe Motor Paralysis: A Case Study

Author

Sora Ohnishi, Naomichi Mizuta, Naruhito Hasui, Junji Taguchi, Tomoki Nakatani, and Shu Morioka

Subjects

stroke, motor paralysis, supplementary motor area of the non-injured hemisphere, corticospinal tract excitability, transcranial direct current electrical stimulation, coherence, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

In patients with severe motor paralysis, increasing the excitability of the supplementary motor area (SMA) in the non-injured hemisphere contributes to the recovery of lower limb motor function. However, the contribution of transcranial direct current stimulation (tDCS) over the SMA of the non-injured hemisphere in the recovery of lower limb motor function is unclear. This study aimed to examine the effects of tDCS on bilateral hemispheric SMA combined with assisted gait training. A post-stroke patient with severe motor paralysis participated in a retrospective AB design. Assisted gait training was performed only in period A and tDCS to the SMA of the bilateral hemisphere combined with assisted gait training (bi-tDCS) was performed in period B. Additionally, three conditions were performed for 20 min each in the intervals between the two periods: (1) assisted gait training only, (2) assisted gait training combined with tDCS to the SMA of the injured hemisphere, and (3) bi-tDCS. Measurements were muscle activity and beta-band intermuscular coherence (reflecting corticospinal tract excitability) of the vastus medialis muscle. The bi-tDCS immediately and longitudinally increased muscle activity and intermuscular coherence. We consider that bi-tDCS may be effective in recovering lower limb motor function in a patient with severe motor paralysis.

Published

2022

7. Effects of rhythmic auditory cueing on gait variability and voluntary control of walking -a cross-sectional study

Author

Naruhito, Hasui, Naomichi, Mizuta, Ayaka, Matsunaga, Junji, Taguchi, and Tomoki, Nakatani

Subjects

Stroke, Cross-Sectional Studies, Biophysics, Humans, Experimental and Cognitive Psychology, Orthopedics and Sports Medicine, Walking, General Medicine, Cues, Gait

Abstract

Temporal gait variability is strongly associated with motor function and falls in the context of numerous diseases. Rhythmic auditory cueing (RAC) can influence stride-to-stride time, although its effects on temporal gait variability remain unclear. Therefore, the aim of the present cross-disease study was to examine the effects of RAC on stride time variability (STV), as well as the factors affecting changes in STV during walking with RAC. Participants with post-stroke (n = 12) and orthopedic disease (n = 23) performed a random block design under four conditions: comfortable walking speed (CWS) and walking with RAC (RAC 0%, RAC +10%, RAC -10%). STV was measured along with co-contraction and inter-muscular coherence of the shank muscles during walking for each condition. The contributions of the muscle activity pattern and voluntary control to the change in STV between the CWS and RAC 0% conditions were examined using hierarchical multiple regression analysis. STV was significantly lower in the RAC 0% condition than in the CWS condition (p = 0.03). Hierarchical multiple regression analysis revealed that the change in STV was explained by STV in the CWS condition (β = -0.36) and by changes in co-contraction (β = 0.43) and inter-muscular coherence (β = 0.38) during the stance phase between the CWS and RAC 0% conditions (R

Published

2022

8. Walking characteristics including mild motor paralysis and slow walking speed in post-stroke patients

Author

Yusaku Takamura, Junji Taguchi, Shu Morioka, Tomoki Nakatani, Naruhito Hasui, Naomichi Mizuta, Shintaro Fujii, and Masako Tsutsumi

Subjects

Male, 030506 rehabilitation, medicine.medical_specialty, lcsh:Medicine, Walking, Motor function, Article, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Medical research, medicine, Paralysis, Humans, lcsh:Science, Aged, Multidisciplinary, business.industry, lcsh:R, Stroke Rehabilitation, Middle Aged, Trunk, Walking Speed, Preferred walking speed, Stroke, Neurology, Cortical control, Post stroke, lcsh:Q, Female, medicine.symptom, 0305 other medical science, business, human activities, 030217 neurology & neurosurgery, Psychomotor Performance, Neuroscience

Abstract

Walking speed is strongly influenced by the severity of motor paralysis in post-stroke patients. Nevertheless, some patients with mild motor paralysis still walk slowly. Factors associated with this difference in walking speed have not been elucidated. To confirm walking characteristics of patients with mild motor paralysis and slow walking speed, this study identified patient subgroups based on the association between the severity of motor paralysis and walking speed. Fugl-Meyer assessment synergy score (FMS) and the walking speed were measured (n = 42), and cluster analysis was performed based on the association between FMS and walking speed to identify the subgroups. FMS and walking speed were associated (ρ = 0.50); however, some patients walked slowly despite only mild motor paralysis. Cluster analysis using FMS and walking speed as the main variables classified patients into subgroups. Patients with mild motor paralysis (FMS: 18.4 ± 2.09 points) and slow walking speed (0.28 ± 0.14 m/s) exhibited poorer trunk stability, increased co-contraction of the shank muscle, and increased intramuscular coherence in walking compared to other clusters. This group was identified by their inability to fully utilize the residual potential of motor function. In walking training, intervention in instability and excessive cortical control may be effective.

Published

2020