Trunk motion and the mechanisms of postural control during pedaling was investigated by analyzing the lower trunk muscle activity and spinal motion.
Eight healthy adult men were assigned to pedal at the rate of 60 cycles per min. with the load of 100 W, 150 W and 200 W. Muscle activity was recorded with the surface electrodes from the m. multifidus, m, iliocostalis, m. obliquus externus, m; rectus abdominis, m. rectus lemons, m. adductor longus and m. semitendinosus. Spinal motion was filmed with 8 mm video camera located 5 m behind the subject and 1 m above the floor, and five markers were attached on the midline of the spine (C 7, Th 6, Th 12, S 1, Co) .
Muscle activity (iEMG) was quantified by integrating one cycle of recorded electromyogram, and significant increase was recognized in the trunk muscles and m. rectus femoris as the load increased. The angles between each segments were calculated and the largest deviation was observed in the lumbo-sacral portion. Focussing on the activity of the m. obliquus externus, four patterns of controling the trunk posture were observed, and as the load increased, the activity patterns changed in four subjects and the other four showed tremendous increase in iEMG without changing the pattern.
The results sugest that the pedaling may cause relatively large motion at lambo-sacral portion of the spine, and either the change in the activity pattern or the increase in the activity level of the trunk muscles, such as m, obliquus externus, should contribute to reduce the stress on the lambo-sacral portion.

Purpose: The purpose of this study was to examine the influence of the exercise program for Osteoarthritis of the knee (knee OA) which American Geriatrics Society Panel on Exercise and Osteoarthritis (AGS) recommends on physical function in Japanese independent elderly with knee joint pain.Methods: Subjects of this study were 36 (7 males : aged 74.7±5.1 years, 29 females : aged 72.3±4.6 years) community-dwelling independent elderly with knee joint pain who voluntary participated in our exercise program. The program consisted of massage around knee, flexibility exercises in knee and ankle joints, and leg muscle development exercises. They performed these exercises twelve times for a month at regular intervals. Physical function were evaluated by the muscle strength during knee extension and flexion, the range of motion of knee joint and the center of pressure during upright standing. There were three times measurements at one month before starting of the program (the 1 st), immediately before beginning of the program (the 2 nd), and just after ending of the program (the 3 rd). Difference between change in measurement values during the observation period (subtract the 1 st from the 2 nd ; Δ1) and that during intervention period (subtract the 2 nd from the 3 rd ; Δ2) were analyzed by Students't-test.Results and Conclusion: There was significant difference between Δ1 (0.01±0.05 kg/wt) and Δ2 (0.04±0.05 kg/wt) on maximal muscle strength during knee extension. This result suggested that the exercise program recommended by AGS was improved the leg muscle strength in Japanese elderly with knee joint pain. However the effects of the exercise intervention were not clarified on the other physical function. As for the reasons it seems to affect the initial level of joint pain and physical function in the subjects. Therefore, reexamination of this point with a greater number of samples which the worse level of knee joint pain is needed in the future.

It has recently demonstrated that central fatigue during sustained maximal voluntary contraction (MVC) progresses faster in the presence of delayed onset muscle soreness due to eccentric contractions than in normal states (Endoh et al., 2005). However, it remains to be clarified whether these findings are related to muscle damage or muscle pain induced by eccentric contractions. The present study investigated which factor plays a more critical role in the earlier onset of central fatigue during sustained MVC with muscle pain induced by injecting hypertonic saline. Ten healthy male right-handed subjects (age, 21~32 yrs.) were asked to perform brief MVCs (~3 sec) before and after injection of isotonic saline (0.9%, 1.0 ml, ISO) or hypertonic saline (5.25%, 1.0 ml, HYP) into the left biceps brachii. The subjects then performed 1 min MVC (fatigue test) with isometric elbow flexion was done in ISO or HYP condition or intact control condition (CON). During these contractions, transcranial magnetic stimulation was delivered to the contralateral motor cortex to evaluate voluntary activation (VA), the motor evoked potential (MEP) and electromyographic (EMG) silent period (SP). Ratio of root mean square of the EMG and elbow flexion force (EMGrms/F) was also measured.The peak pain induced by the injection of HYP was significantly higher than that of ISO (p<0.01). There was no significant difference in either the maximum size of the M response or the twitch force between ISO and HYP (p>0.05). However, during the brief MVCs, both maximal force (p<0.01) and VA (p<0.05) for HYP were significantly decreased compared to those for ISO. During the fatigue test, although MVC, VA, MEP and SP were significantly altered (p<0.05~0.01), there was no significant difference among CON, ISO and HYP (p>0.05). There was no significant difference in EMGrms during the fatigue test (p>0.05).These results suggest that peripheral force-producing capacity remained intact after the injection of ISO and HYP during sustained MVC, and that progression of central fatigue during sustained MVC was less affected by the increased group III and IV afferent activity induced by HYP.

Modulation of the excitability of the corticospinal tract and spinal reflex in static upper and lower limbs was investigated during arm or leg cycling. The excitability of the corticospinal tract was examined with motor-evoked potentials (MEPs) following transcranial magnetic stimulation (TMS). H-reflexes were evoked by electrical stimulation of peripheral nerves in the upper and lower limbs. MEPs and H-reflexes were recorded from the soleus while the subject performed arm cycling and the soleus was at rest. In addition, MEPs and H-reflexes were recorded from the flexor carpi radialis (FCR) during leg cycling while the FCR was at rest. MEPs and H-reflexes were also evoked without arm or leg cycling as a control. TMS or electrical stimulation was delivered at 4 different pedal positions. The subjects performed arm or leg cycling at 30 and 60 rpm. The amplitudes of MEP in the soleus significantly increased during arm cycling compared to the control. In contrast, H-reflexes in the soleus significantly decreased during arm cycling compared to control values. The same results were obtained in FCR during leg cycling. MEPs and H-reflexes were not modulated in a phase-dependent manner during either arm or leg cycling. The degree of modulations in MEP and H-reflex amplitudes depended on the cadence of arm and leg cycling. These findings suggest that a differential regulation of spinal and supraspinal excitability in the static limb was induced by arm and leg cycling. The corticospinal tract and the reflex arc independently would be responsible for coordination between the upper and lower limbs.