4.17-5 Effects of high concentration carbon-dioxide foot bath on lower extremity function and walking ability in spastic paraplegia: A case report
Keiko IKEDA ; Shuji MATSUMOTO ; Kodai MIYARA ; Tomohiro UEMA ; Takuya HIROKAWA ; Tomokazu NOMA ; Megumi SHIMODOZONO
The Journal of The Japanese Society of Balneology, Climatology and Physical Medicine 2014;77(5):550-551
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.
5.06-2 Effects of a whole body vibration as a means for controlling spasticity in post-stroke patients: A F-wave study
Kodai MIYARA ; Shuji MATSUMOTO ; Tomohiro UEMA ; Takuya HIROKAWA ; Tomokazu NOMA ; Keiko IKEDA ; Megumi SHIMODOZONO ; Kazumi KAWAHIRA
The Journal of The Japanese Society of Balneology, Climatology and Physical Medicine 2014;77(5):466-467
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.