ABSTRACT
Shoulder subluxation, a risk factor for hemiplegic shoulder pain, is an important target to treat during stroke rehabilitation. Calcific tendinitis is an idiopathic condition characterized by calcium deposition over fibrocartilaginous tenocyte metaplasia that inhibits the efficacy of occupational therapy for the treatment of stroke. To provide comprehensive occupational therapy, we provided repetitive facilitative exercise under continuous neuromuscular electrical stimulation and robot-assisted training, while controlling pain, for fourteen weeks in a case of convalescent post-stroke hemiplegia with rotator cuff calcific tendinopathy and shoulder subluxation. As a result, this comprehensive occupational therapy not only improved upper-extremity function and the ability to manipulate objects, but also reduced calcified deposits. Shoulder subluxation with calcifying tendinitis is rare. There is a possibility that calcified deposits below the acromion may push down the humeral head. Sufficient rest and non-steroidal anti-inflammatory drugs during the acute inflammatory stage may be helpful for the melting and resorption of calcified deposits. In addition, the appropriate and comprehensive occupational therapy may contribute to the effects of upper-extremity hemiplegia with calcific tendinitis and shoulder subluxation.
ABSTRACT
Objectives: To preliminarily assess the effects of a single warm-water bath (WWB) on the quality of sleep, we measured sleep pattern after WWB in healthy volunteers. The primary objective of the present before-after study was to evaluate whether a single 10-minute WWB at 41°C could modulate sleep pattern in a single group of healthy subjects. In this pilot study, we also assessed the difference in general fatigue and subjects’ satisfaction responses to WWB under two conditions: WWB using tap water (WWB with tap water) and WWB using a bath additive that included inorganic salts and artificial carbon-dioxide (CO2) (WWB with ISCO2). Methods: Eleven healthy volunteers aged 20 to 48 years (29.8±8.9 years, mean ± SD) participated in this study. Inclusion criteria were as follows: age 20-50 years; free of cardiovascular disease; not taking medications or supplements. In this within-subject, two-way crossover study, all subjects underwent WWB with tap water or WWB with ISCO2 in random order for two consecutive nights. Objective sleep measures from sleep sensor mat (sleep-scan) and subjective subjects’ reports were collected. This study was approved by the Ethics Committee of Kagoshima University Hospital and written informed consent was obtained from all of the subjects. Results: None of the subjects experienced discomfort before, during or after the study period. The objective sleep measures and subjects’ reports were completed safely in all subjects. WWB with ISCO2 bathing produced significant improvement in objective and subjective sleep latency compared with WWB with tap water bathing (P<0.05). Sleep-scan-determined wake time after sleep onset (WASO), sleep efficiency, and number of awakenings (NA), and patient-reported measures of WASO, NA, sleep quality, sleep depth, and daytime functioning significantly improved following WWB with ISCO2 bathing versus WWB with tap water bathing (P<0.05). WWB with ISCO2 bathing also increased deep sleep time and sleep score (P<0.01 for both comparisons), but did not alter REM or slow-wave sleep. Conclusion: In conclusion, in our group of healthy volunteers, a single warm-water bath was shown to have the potential to modulate the quality of sleep. These findings demonstrate that WWB with ISCO2 bathing might be effective in improving some domains of sleep quality of healthy volunteers, and the subjects showed acceptance towards the intervention. Strengths and limitations of the present study as well as suggestions for further studies were considered. Further evaluations with larger and longer-term randomized double-blind placebo-controlled trials based on the present study are needed.
ABSTRACT
Objectives: Recently, it has been reported that the effects of artificial high concentration carbon-dioxide (CO2) on core temperature, cutaneous blood flow, thermal sensation. However, the effect of artificial high concentration CO2 water foot baths for spasticity, lower extremity motor function and walking ability was not identified. The purpose of this study was to investigate whether the newly artificial high concentration CO2 water foot bath inhibits spasticity and improves lower extremity motor function and gait speed in spastic paraplegia patient. Case Presentation: The patient was a 37 years old man with spastic paraplegia of human immunodeficiency virus encephalopathy, without signs of cognitive impairment. The patient was able to walk without assistance using a T-cane or an ankle-foot orthosis. He had no medical condition that limited footbath usage (such as uncontrolled cardiopulmonary disease, severe joint disability and severe sensory disturbance), severe aphasia that made it impossible to follow verbal instructions, and cognitive dysfunction that interfered with outcome assessments. Informed consent was obtained from him according to the ethical guidelines of the hospital, after he fully understood the purpose and methodology of the study. This work was carried out with permission from the Ethical Committee of Kagoshima University. Methods: This case study was before and after intervention trial. Six outcome instruments were used at baseline and after the artificial high concentration CO2 water foot bath: the modified Ashworth scale (MAS) score for the gastrocnemius muscles as a measure of spasticity, ankle clonus, muscle stiffness at triceps muscle of calf, deep body and surface skin temperature as a monitor for physical condition, the active range of motion as an assessment tool for motor function, and the 10-m walk test as a measure of walking ability. Lower-extremity movement acceleration was also measured using an accelerometer. The subject rested in a chair for 10 min and the above-noted physiological reactions during the last 5 min of the resting period were recorded as baseline values. Next, the subject received a 20-min foot bath in water at 38 °C, with a 10-min recovery period. The artificial high concentration CO2 water foot bath improved the acceleration of the spastic lower extremities and this improvement in acceleration lasted for 10 min after the footbath usage. Results: The subject experienced no discomfort before, during or after the intervention, and all assessments were completed safely. The deep body temperature and skin temperature increased immediately after and 10 minutes after the artificial high concentration CO2 water foot baths. The MAS score, ankle clonus and the muscle stiffness for the triceps muscle of calf were decreased. The active range of motion for ankle dorsiflexion and gait speed improved after the 20-min intervention. Conclusion: These findings suggest that artificial high concentration CO2 water foot bath is an effective method for controlling spasticity, and improves motor function and walking ability in spastic paraplegia patients.
ABSTRACT
Objectives: The warm-water foot bathing is widely used as a clinical method for hemiplegic limb. Recent research have reported that the artificial high concentration carbon-dioxide (CO2) water foot bathing have a potent vasodilative action. However, the definite effects of the artificial high concentration CO2 water foot bath for hemiplegic limbs remain uncertain. We examined that the effects of the artificial high concentration CO2 water foot bath for patients after stroke. Patients: Three inpatients after stroke were recruited for this study. The age and duration after onset were 58.3 ± 21.4 years and 63.0 ± 38.9 months, respectively. Of the three patients (two males and one female), two were diagnosed with cerebral hemorrhage, one with cerebral infarction. Methods: The artificial high concentration CO2 water foot bath and tap water foot bath were prepared. The concentration of CO2 water foot bath was approximately 1000-1,200 ppm, and both lower limbs (under the knee joint) were immersed in 38 °C water for 20 minutes. Foot bathing in tap water was also carried out under the same conditions in the another day. The following physiological data were measured before foot bathing and after the end of foot bathing. Not only the deep body temperature at axillary, the surface skin temperature at the front of femur, the calf of the leg and the dorsal foot, but also the muscle stiffness at triceps muscle of calf were evaluated. Results: None of the subjects experienced discomfort before and after both the high concentration CO2 water and the tap water foot bath. The physiological examination was completed safely in all subjects. The results were as follows: The deep body temperature and the surface skin temperature had increased, and the muscle stiffness had been relieved in the high concentration CO2 water foot bath compared with the tap water bathing. The deep body temperature of the high concentration CO2 water foot bath have risen from 36.4 °C to 36.9 °C, the surface-skin temperature of the front of femur (from 26.7 °C to 28.1 °C), the calf of the leg (from 29.5 °C to 31.9 °C) and the dorsal foot (from 29.9 °C to 32.3 °C) have risen, respectively. The muscle stiffness have been relieved from 55.3 to 51.8 before and after. There was no change that the tap water had increased in the deep body temperature and the surface-skin temperature, and the muscle stiffness had been relieved before and after. Conclusion: These results suggested that the use of the high concentration CO2 water foot bath was more effective in hyperthermia compared with the tap water. Furthermore, we considered that carbon dioxide had promoted to increase the skin and the muscle blood flow by vasodilative action to the arteriole, and use of the high concentration CO2 water foot bath contribute to improve the circulatory dynamics for the hemiplegic limb. These findings may suggest that the use of the high concentration CO2 water foot bath is an effective physiotherapy for circulatory dynamics treatment that might facilitate stroke rehabilitation
ABSTRACT
Objectives: The purpose of this study was to investigate whether the whole body vibration (WBV) inhibits spasticity and improves motor function and walking ability in the hemiplegic legs of post-stroke patients. Patients and Methods: This before-and-after intervention trial examined 13 post-stroke patients (11 male and 2 female; mean age, 54.3 ± 13.0 years; range, 24-72 years). The Brunnstrom Recovery Stage of the hemiplegic lower limb was stage 3 in three patients, stage 4 in 7, stage 5 in three. The modified Ashworth scale (MAS) score for the gastrocnemius muscles was 1 in one case, 1+ in 6 cases and 2 in six cases. All patients had increased muscle tonus of the affected lower limb (MAS score ≥1), and were able to walk without assistance using a T-cane or an ankle-foot orthosis. Exclusion criteria were any medical condition preventing vibratory stimulation (such as uncontrolled cardiopulmonary disease, severe joint disability and severe sensory disturbance), severe aphasia that made it impossible to follow verbal instructions, and dementia that interfered with outcome assessments. Each subjects sat on the chair with hip joint angles to approximately 90° of flexion, and with knee joint angles to 0° of extension. WBV was applied at 30 Hz (4-8 mm amplitude) for 5 min on hamstrings, gastrocnemius and soleus muscles (Figure 1). The parameters measured before and after the intervention were the MAS, the F-wave parameters as a measure of motor-neuron excitability, the active and passive range of motion (A-ROM, P-ROM) as a measure of motor function, and the 10-m walk test as a measure of walking ability. Results: None of the subjects experienced discomfort before, during or after the intervention and all assessments were completed safely in all subjects. The MAS and F-wave parameters were significantly decreased (p < 0.05), the A-ROM and P-ROM for ankle dorsiflexion increased (p < 0.01), and the P-ROM for straight leg raising increased (p < 0.01), and walking speed improved (p < 0.01) after the 5-min intervention. Conclusion: These findings suggest that WBV is an effective method for controlling spasticity, and improves motor function and walking ability in post-stroke patients.
ABSTRACT
Objectives: Spasticity is defined as a pathological increase in muscle tonus, and increased muscle tonus of lower limbs is a major obstacle to the stroke rehabilitation. Foot baths are considered to provide beneficial thermal therapy for post-stroke patients with spasticity, but their anti-spastic effects have not been investigated comprehensively. The present study aimed to evaluate alterations in spasticity and motor function using foot baths in post-stroke patients with spastic hemiplegia. Methods: We underwent two separate experiments each consisting of immersion in warm water up to the knee joint level, and measuring spasticity, physiological examination and motor function. Experiment 1; Fourteen post-stroke patients with lower limb spasticity were enrolled in this study (nine males and five females; mean age 50.4±12.9 years; range, 28-65 years). The subjects’ legs from below the knee joint were immersed in water at 41°C for 15 min. Measurements of F-waves and a physiological examination were carried out immediately (within 5 min) after the foot-bath session, and again 30 min later, while the subject remained wrapped in blankets on the lift-bath stretcher. Experiment 2; Six post-stroke patients with lower limb spasticity were enrolled in this study (five males and one female; mean age 55.2±14.6 years; range, 39-68 years). The subjects’ legs from below the knee joint were immersed in the artificial high concentration carbon-dioxide (CO2) water or tap water foot bath at 38°C for 30 min. Measurements of muscle stiffness, motor function (active range of motion: A-ROM) and a physiological examination were carried out immediately (within 5 min) after the foot-bath session, and again 10 min later, while the subject remained wrapped in blankets. Results: None of the subjects experienced discomfort before, during or after the foot-bath treatment. The physiological examination was completed safely in all subjects. Experiment 1; The mean values of F-wave parameters were significantly reduced after foot-bath treatment (P<0.01). The anti-spastic effects of foot-bath treatment were indicated by decreased F-wave parameters, in parallel with decreases in modified Ashworth scale (MAS) score. The body temperature was significantly increased both immediately after, and 30 min following foot-bath treatment. Experiment 2; The changes both in the body and surface skin temperature were higher in the artificial high concentration CO2 water foot bath compared with the tap water foot bath. The changes in the MAS score, muscle stiffness and A-ROM were also higher in the high concentration CO2 water foot bath than in the tap water foot bath. Conclusion: These findings demonstrate that the use of foot baths is an effective non-pharmacological anti-spastic treatment that might facilitate stroke rehabilitation. In addition, the high concentration CO2 water foot baths appeared to play an important role in decreased spasticity.
ABSTRACT
<b>Objectives: </b>Recently, it has been reported that the effects of artificial high concentration carbon-dioxide (CO<sub>2</sub>) on core temperature, cutaneous blood flow, thermal sensation. However, the effect of artificial high concentration CO<sub>2</sub> water foot baths for spasticity, lower extremity motor function and walking ability was not identified. The purpose of this study was to investigate whether the newly artificial high concentration CO<sub>2</sub> water foot bath inhibits spasticity and improves lower extremity motor function and gait speed in spastic paraplegia patient.<BR><b>Case Presentation: </b>The patient was a 37 years old man with spastic paraplegia of human immunodeficiency virus encephalopathy, without signs of cognitive impairment. The patient was able to walk without assistance using a T-cane or an ankle-foot orthosis. He had no medical condition that limited footbath usage (such as uncontrolled cardiopulmonary disease, severe joint disability and severe sensory disturbance), severe aphasia that made it impossible to follow verbal instructions, and cognitive dysfunction that interfered with outcome assessments. Informed consent was obtained from him according to the ethical guidelines of the hospital, after he fully understood the purpose and methodology of the study. This work was carried out with permission from the Ethical Committee of Kagoshima University.<BR><b>Methods: </b>This case study was before and after intervention trial. Six outcome instruments were used at baseline and after the artificial high concentration CO<sub>2</sub> water foot bath: the modified Ashworth scale (MAS) score for the gastrocnemius muscles as a measure of spasticity, ankle clonus, muscle stiffness at triceps muscle of calf, deep body and surface skin temperature as a monitor for physical condition, the active range of motion as an assessment tool for motor function, and the 10-m walk test as a measure of walking ability. Lower-extremity movement acceleration was also measured using an accelerometer. The subject rested in a chair for 10 min and the above-noted physiological reactions during the last 5 min of the resting period were recorded as baseline values. Next, the subject received a 20-min foot bath in water at 38 °C, with a 10-min recovery period. The artificial high concentration CO<sub>2</sub> water foot bath improved the acceleration of the spastic lower extremities and this improvement in acceleration lasted for 10 min after the footbath usage.<BR><b>Results: </b>The subject experienced no discomfort before, during or after the intervention, and all assessments were completed safely. The deep body temperature and skin temperature increased immediately after and 10 minutes after the artificial high concentration CO<sub>2</sub> water foot baths. The MAS score, ankle clonus and the muscle stiffness for the triceps muscle of calf were decreased. The active range of motion for ankle dorsiflexion and gait speed improved after the 20-min intervention.<BR><b>Conclusion: </b>These findings suggest that artificial high concentration CO<sub>2</sub> water foot bath is an effective method for controlling spasticity, and improves motor function and walking ability in spastic paraplegia patients.
ABSTRACT
<b>Objectives:</b> The warm-water foot bathing is widely used as a clinical method for hemiplegic limb. Recent research have reported that the artificial high concentration carbon-dioxide (CO<sub>2</sub>) water foot bathing have a potent vasodilative action. However, the definite effects of the artificial high concentration CO<sub>2</sub> water foot bath for hemiplegic limbs remain uncertain. We examined that the effects of the artificial high concentration CO<sub>2</sub> water foot bath for patients after stroke. <BR><b>Patients: </b>Three inpatients after stroke were recruited for this study. The age and duration after onset were 58.3 ± 21.4 years and 63.0 ± 38.9 months, respectively. Of the three patients (two males and one female), two were diagnosed with cerebral hemorrhage, one with cerebral infarction. <BR><b>Methods: </b>The artificial high concentration CO<sub>2</sub> water foot bath and tap water foot bath were prepared. The concentration of CO<sub>2</sub> water foot bath was approximately 1000-1,200 ppm, and both lower limbs (under the knee joint) were immersed in 38 °C water for 20 minutes. Foot bathing in tap water was also carried out under the same conditions in the another day. The following physiological data were measured before foot bathing and after the end of foot bathing. Not only the deep body temperature at axillary, the surface skin temperature at the front of femur, the calf of the leg and the dorsal foot, but also the muscle stiffness at triceps muscle of calf were evaluated. <BR><b>Results: </b>None of the subjects experienced discomfort before and after both the high concentration CO<sub>2</sub> water and the tap water foot bath. The physiological examination was completed safely in all subjects. The results were as follows: The deep body temperature and the surface skin temperature had increased, and the muscle stiffness had been relieved in the high concentration CO<sub>2</sub> water foot bath compared with the tap water bathing. The deep body temperature of the high concentration CO<sub>2</sub> water foot bath have risen from 36.4 °C to 36.9 °C, the surface-skin temperature of the front of femur (from 26.7 °C to 28.1 °C), the calf of the leg (from 29.5 °C to 31.9 °C) and the dorsal foot (from 29.9 °C to 32.3 °C) have risen, respectively. The muscle stiffness have been relieved from 55.3 to 51.8 before and after. There was no change that the tap water had increased in the deep body temperature and the surface-skin temperature, and the muscle stiffness had been relieved before and after. <BR><b>Conclusion:</b> These results suggested that the use of the high concentration CO<sub>2</sub> water foot bath was more effective in hyperthermia compared with the tap water. Furthermore, we considered that carbon dioxide had promoted to increase the skin and the muscle blood flow by vasodilative action to the arteriole, and use of the high concentration CO<sub>2</sub> water foot bath contribute to improve the circulatory dynamics for the hemiplegic limb. These findings may suggest that the use of the high concentration CO<sub>2</sub> water foot bath is an effective physiotherapy for circulatory dynamics treatment that might facilitate stroke rehabilitation
ABSTRACT
<b>Objectives:</b> To preliminarily assess the effects of a single warm-water bath (WWB) on the quality of sleep, we measured sleep pattern after WWB in healthy volunteers. The primary objective of the present before-after study was to evaluate whether a single 10-minute WWB at 41°C could modulate sleep pattern in a single group of healthy subjects. In this pilot study, we also assessed the difference in general fatigue and subjects’ satisfaction responses to WWB under two conditions: WWB using tap water (WWB with tap water) and WWB using a bath additive that included inorganic salts and artificial carbon-dioxide (CO<sub>2</sub>) (WWB with ISCO<sub>2</sub>). <BR><b>Methods:</b> Eleven healthy volunteers aged 20 to 48 years (29.8±8.9 years, mean ± SD) participated in this study. Inclusion criteria were as follows: age 20-50 years; free of cardiovascular disease; not taking medications or supplements. In this within-subject, two-way crossover study, all subjects underwent WWB with tap water or WWB with ISCO<sub>2</sub> in random order for two consecutive nights. Objective sleep measures from sleep sensor mat (sleep-scan) and subjective subjects’ reports were collected. This study was approved by the Ethics Committee of Kagoshima University Hospital and written informed consent was obtained from all of the subjects. <BR><b>Results:</b> None of the subjects experienced discomfort before, during or after the study period. The objective sleep measures and subjects’ reports were completed safely in all subjects. WWB with ISCO<sub>2</sub> bathing produced significant improvement in objective and subjective sleep latency compared with WWB with tap water bathing (P<0.05). Sleep-scan-determined wake time after sleep onset (WASO), sleep efficiency, and number of awakenings (NA), and patient-reported measures of WASO, NA, sleep quality, sleep depth, and daytime functioning significantly improved following WWB with ISCO<sub>2</sub> bathing versus WWB with tap water bathing (P<0.05). WWB with ISCO<sub>2</sub> bathing also increased deep sleep time and sleep score (P<0.01 for both comparisons), but did not alter REM or slow-wave sleep. <BR><b>Conclusion: </b>In conclusion, in our group of healthy volunteers, a single warm-water bath was shown to have the potential to modulate the quality of sleep. These findings demonstrate that WWB with ISCO<sub>2</sub> bathing might be effective in improving some domains of sleep quality of healthy volunteers, and the subjects showed acceptance towards the intervention. Strengths and limitations of the present study as well as suggestions for further studies were considered. Further evaluations with larger and longer-term randomized double-blind placebo-controlled trials based on the present study are needed.
ABSTRACT
<b>Objectives:</b> Spasticity is defined as a pathological increase in muscle tonus, and increased muscle tonus of lower limbs is a major obstacle to the stroke rehabilitation. Foot baths are considered to provide beneficial thermal therapy for post-stroke patients with spasticity, but their anti-spastic effects have not been investigated comprehensively. The present study aimed to evaluate alterations in spasticity and motor function using foot baths in post-stroke patients with spastic hemiplegia. <BR><b>Methods:</b> We underwent two separate experiments each consisting of immersion in warm water up to the knee joint level, and measuring spasticity, physiological examination and motor function. <BR><b>Experiment 1;</b> Fourteen post-stroke patients with lower limb spasticity were enrolled in this study (nine males and five females; mean age 50.4±12.9 years; range, 28-65 years). The subjects’ legs from below the knee joint were immersed in water at 41°C for 15 min. Measurements of F-waves and a physiological examination were carried out immediately (within 5 min) after the foot-bath session, and again 30 min later, while the subject remained wrapped in blankets on the lift-bath stretcher. <BR><b>Experiment 2;</b> Six post-stroke patients with lower limb spasticity were enrolled in this study (five males and one female; mean age 55.2±14.6 years; range, 39-68 years). The subjects’ legs from below the knee joint were immersed in the artificial high concentration carbon-dioxide (CO<sub>2</sub>) water or tap water foot bath at 38°C for 30 min. Measurements of muscle stiffness, motor function (active range of motion: A-ROM) and a physiological examination were carried out immediately (within 5 min) after the foot-bath session, and again 10 min later, while the subject remained wrapped in blankets. <BR><b>Results: </b>None of the subjects experienced discomfort before, during or after the foot-bath treatment. The physiological examination was completed safely in all subjects. <BR><b>Experiment 1; </b>The mean values of F-wave parameters were significantly reduced after foot-bath treatment (P<0.01). The anti-spastic effects of foot-bath treatment were indicated by decreased F-wave parameters, in parallel with decreases in modified Ashworth scale (MAS) score. The body temperature was significantly increased both immediately after, and 30 min following foot-bath treatment. <BR><b>Experiment 2;</b> The changes both in the body and surface skin temperature were higher in the artificial high concentration CO<sub>2</sub> water foot bath compared with the tap water foot bath. The changes in the MAS score, muscle stiffness and A-ROM were also higher in the high concentration CO<sub>2</sub> water foot bath than in the tap water foot bath. <BR><b>Conclusion:</b> These findings demonstrate that the use of foot baths is an effective non-pharmacological anti-spastic treatment that might facilitate stroke rehabilitation. In addition, the high concentration CO<sub>2</sub> water foot baths appeared to play an important role in decreased spasticity.
ABSTRACT
<b>Objectives: </b>The purpose of this study was to investigate whether the whole body vibration (WBV) inhibits spasticity and improves motor function and walking ability in the hemiplegic legs of post-stroke patients.<BR><b>Patients and Methods: </b>This before-and-after intervention trial examined 13 post-stroke patients (11 male and 2 female; mean age, 54.3 ± 13.0 years; range, 24-72 years). The Brunnstrom Recovery Stage of the hemiplegic lower limb was stage 3 in three patients, stage 4 in 7, stage 5 in three. The modified Ashworth scale (MAS) score for the gastrocnemius muscles was 1 in one case, 1+ in 6 cases and 2 in six cases. All patients had increased muscle tonus of the affected lower limb (MAS score ≥1), and were able to walk without assistance using a T-cane or an ankle-foot orthosis. Exclusion criteria were any medical condition preventing vibratory stimulation (such as uncontrolled cardiopulmonary disease, severe joint disability and severe sensory disturbance), severe aphasia that made it impossible to follow verbal instructions, and dementia that interfered with outcome assessments. Each subjects sat on the chair with hip joint angles to approximately 90° of flexion, and with knee joint angles to 0° of extension. WBV was applied at 30 Hz (4-8 mm amplitude) for 5 min on hamstrings, gastrocnemius and soleus muscles (Figure 1). The parameters measured before and after the intervention were the MAS, the F-wave parameters as a measure of motor-neuron excitability, the active and passive range of motion (A-ROM, P-ROM) as a measure of motor function, and the 10-m walk test as a measure of walking ability.<BR><b>Results: </b>None of the subjects experienced discomfort before, during or after the intervention and all assessments were completed safely in all subjects. The MAS and F-wave parameters were significantly decreased (p < 0.05), the A-ROM and P-ROM for ankle dorsiflexion increased (p < 0.01), and the P-ROM for straight leg raising increased (p < 0.01), and walking speed improved (p < 0.01) after the 5-min intervention.<BR><b>Conclusion: </b>These findings suggest that WBV is an effective method for controlling spasticity, and improves motor function and walking ability in post-stroke patients.
ABSTRACT
The effects of bathing in a solution of artificial bath additive including inorganic salts and carbon dioxide (CO2-bathing: 41°C, 10 minutes; the concentration of carbon dioxide was 160-180 ppm, and that of inorganic salts was about 64 ppm) on the cardiovascular system, body flexibility, muscle stiffness and the subjective feeling of bathing were compared with those of no bathing and plain water bathing in the healthy subjects. The deep body temperature and skin blood flow increased after bathing, and the increases after CO2-bathing were significantly greater than those after plain water bathing. Body flexibility after CO2-bathing was similar to that of no bathing and plain water bathing. Stiffness of the trapezius muscle was decreased at both 15 min and 30 min after CO2-bathing and plain water bathing, with no change in no bathing. The changes at 15 min after CO2-bathing and plain water bathing were statistically significant. Stiffness in the latissimus dorsi muscle decreased at both 15 min and 30 min after CO2-bathing and plain water bathing, with no change in no bathing. However, only these changes at 15 min and 30 min after CO2-bathing were statistically significant. A large decrease in the stiffness of the trapezius muscle by its isometric contraction was observed during both CO2-bathing and plain water bathing, and the decrease after CO2-bathing was greater than that after plain water bathing. These changes did not reach statistical significance. Improvements in subjective feeling of bathing were observed after both plain water bathing and CO2-bathing. Improvements after CO2-bathing in stiffness of muscle, ease of movements and mental relaxation were statistically greater than those after plain water bathing. Compared with plain water bathing, CO2-bathing showed additional effects on muscle stiffness and subjective feeling of bathing. Further research is needed to confirm the effectiveness of the CO2-bathing alone and combined with isometric movements on muscle stiffness.
ABSTRACT
The effects of bathing in a solution of artificial bath additive including inorganic salts and carbon dioxide (CO<SUB>2</SUB>-bathing: 41°C, 10 minutes; the concentration of carbon dioxide was 160-180 ppm, and that of inorganic salts was about 64 ppm) on the cardiovascular system, body flexibility, muscle stiffness and the subjective feeling of bathing were compared with those of no bathing and plain water bathing in the healthy subjects.<br> The deep body temperature and skin blood flow increased after bathing, and the increases after CO<SUB>2</SUB>-bathing were significantly greater than those after plain water bathing.<br>Body flexibility after CO<SUB>2</SUB>-bathing was similar to that of no bathing and plain water bathing.<br> Stiffness of the trapezius muscle was decreased at both 15 min and 30 min after CO<SUB>2</SUB>-bathing and plain water bathing, with no change in no bathing. The changes at 15 min after CO<SUB>2</SUB>-bathing and plain water bathing were statistically significant. Stiffness in the latissimus dorsi muscle decreased at both 15 min and 30 min after CO<SUB>2</SUB>-bathing and plain water bathing, with no change in no bathing. However, only these changes at 15 min and 30 min after CO<SUB>2</SUB>-bathing were statistically significant.<br> A large decrease in the stiffness of the trapezius muscle by its isometric contraction was observed during both CO<SUB>2</SUB>-bathing and plain water bathing, and the decrease after CO<SUB>2</SUB>-bathing was greater than that after plain water bathing. These changes did not reach statistical significance.<br> Improvements in subjective feeling of bathing were observed after both plain water bathing and CO<SUB>2</SUB>-bathing. Improvements after CO<SUB>2</SUB>-bathing in stiffness of muscle, ease of movements and mental relaxation were statistically greater than those after plain water bathing.<br> Compared with plain water bathing, CO<SUB>2</SUB>-bathing showed additional effects on muscle stiffness and subjective feeling of bathing. Further research is needed to confirm the effectiveness of the CO<SUB>2</SUB>-bathing alone and combined with isometric movements on muscle stiffness.
ABSTRACT
<b>Purpose</b><br> Forearm bathing is considered beneficial for the hands of patients with spastic hemiplegia, but the effect has not been investigated comprehensively. This study investigated the effectiveness of forearm bathing for patients with hemiplegic hands. <br><b>Subjects and Methods</b><br> In total, nine hemiplegic patients participated in the study (mean±standard deviation age=56.9±16.6 years; mean±standard deviation period from onset=21.1±21.2 months). Participants sat in a relaxed position on a chair, and dipped the affected forearms into 40°C warm water for 15 mins. The Simple Test for Evaluating Hand Function (STEF) score was evaluated before and after forearm bathing as an indicator of hemiplegic hand function. The Modified Ashworth Scale (MAS) score for the biceps brachii muscle, and both the resistance power of elbow extension and the F/M ratio (F-wave amplitudes/ M wave amplitudes) for the abductor pollicis brevis muscle, were evaluated as indicators of hemiplegic hand spasticity. The device used to measure the resistance power of elbow extension comprised a motor, cuffs to fix the hemiplegic arm and forearm in place, and a control system. The axis of rotation of the device was positioned over the axis of rotation of the elbow joint. The device induced passive elbow flexion and extension movements at an angular velocity of 60°/sec or 90°/sec.<br><b>Results</b><br> After forearm bathing, the STEF score increased significantly (<i>p</i><0.05) from 42.9±28.0 to 47.8±28.4 (<i>n</i>=9), the resistance power of elbow extension at 90°/min decreased significantly (<i>p</i><0.01) from 4.0±1.8 N to 3.0±1.9 N, and the MAS score and F/M ratio were unchanged (<i>n</i>=6).<br><b>Conclusions</b><br> Forearm bathing appeared to improve function and decrease spasticity in hemiplegic hands. This treatment might facilitate hand rehabilitation.
ABSTRACT
<b>Objective</b>: Exercise baths are generally considered to be one of the most appropriate and advantageous rehabilitative therapies, yet their effects have not been comprehensively investigated. The aim of this study is to assess the efficacy of exercise baths on quality of life (QOL).<br><b>Methods</b>: The 49 subjects consisted of 20 patients with brain disease, 21 patients with orthopaedic disease, and 8 patients with other diseases (i.e., 7 life-style related diseases and one heat burn). In the present study, all patients were first treated by conventional rehabilitation comprising physical therapy and occupational therapy for 4.2±1.4 weeks. Exercise baths were then added to the rehabilitation program for a further 4.4±1.2 weeks. The subjects were immersed in water at 38°C for 30-60min, twice a week. QOL was evaluated by alterations in the MOS Short-Form 36-item Health Survey (SF-36). We defined the period from admission to exercise bath start as Treatment I, and the period from exercise bath start to discharge (exercise bath finish) as Treatment II. On admission, before and after exercise bath, QOL was evaluated using the SF-36 scores.<br><b>Results</b>: We found that the increase of all eight subscales of the SF-36 was smaller in Treatment I period than in Treatment II period. Increases in SF-36 scores were observed in all patients, in all eight domains. Specifically, after exercise baths, increased scores of Physical functioning (PF), Role physical (RP), General health (GH), Vitality (VT), Role emotional (RE) and Mental health (MH) subscales of the SF-36 were observed in the patients with brain disease. Further, after exercise baths, increased scores of PF, RP, Bodily pain (BP), GH, VT, RE and MH subscales of the SF-36 were observed in the patients with orthopedic disease.<br><b>Conclusions</b>: It was concluded that exercise baths are an effective non-pharmacological treatment that might facilitate rehabilitation programs.
ABSTRACT
The effect of spa-drink (Misasa hot spring) on exocrine pancreatic function was studied in controls and drink therapy group. To examine exocrine pancreatic function, two different methods were used for determination of pancreatic chymotrypsin activity. One was a colorimetric method for the determination of fecal chymotrypsin activity and the other was PFD fest. Following conclusions were obtained.<br>1) With spa-drink therapy, fecal chymotrypsin activity was raised in 2 weeks in 40% of patients, while it remained unchanged in the next 2 weeks.<br>2) With spa-drink therapy, PFD value was raised in 2 weeks in 50% of patients, while it returned to the pre-treatment value in the next 2 weeks.<br>3) Spa-drink therapy for 2 weeks was effective for improving exocrine pancreatic function.