We have developed the new dynamometer to measure twist strength of upper limbs that was not investigated sufficiently before. This dynamometer can measure both twisting hold strength and torque at a time. Therefore, it can be applied to motion analysis at demonstrating muscle strength. Both development curve of the age group's average of the average hold strength of left and right hand { (LH⋅HS+RH⋅HS) /2} and the average twisting hold strength of left and right hand { (LF⋅HS+RF⋅HS) /2} showed the peak of development in man's thirties and in woman's twenties-thirties and then marked depreciation gradually with ageing. The average torque of forward twisting of left hand and that of right hand { (LF⋅T+RF⋅T) /2} showed the same tendency in respect of the peak of development too, but woman's curve showed the peak in twenties different from that in man and then didn't mark depreciation remarkably. From the analysis with respect to twisting motion by the subjects of right handedness, we have recognized that the twisting hold strength of right hand by the action of left or right forward twisting (LF·RH·HS, RF·RH·HS) is greater than that of left hand (LF·LH·HS, RF·LH·HS), the torque of forward twisting of left hand (LF·T) is greater than that of right hand (RF·T) and that the hand of back twisting supports the grip-torque dynamometer from the result of EMG. Therefore, we can understand that the stronger torque is generated by the motion of forward twisting of left hand which can support stronger than by that of right hand. But we have recognized too that the average hold strength and the average torque correlate to one another closely. Therefor, we can understand that it requires the stronger hold strength to generate the higher torque.

A 29-year-old man, who had undergone valvotomy for pure pulmonary stenosis at 6 months of age, was admitted to our institution for surgical treatment of a giant ascending aortic aneurysm and annuloaortic ectasia. Chest MRI revealed a 14-cm ascending aneurysm in contact with the sternum. After establishing femoro-femoral bypass for hypothermia, a left lateral thoracotomy was perfomed at the 4th intercostal space. Pulmonary artery cannulation was performed for left heart venting, and the proximal aortic arch was dissected for aortic cross-clamping. Median sternotomy was performed under circulatory arrest at 18°C and the aortic arch was opened. Under retrograde cerebral perfusion, the proximal arch was replaced by an artificial graft, and then aortic root replacement was completed using a composite graft under CPB. The postoperative course was uneventful, and the patient was discharged on the 37th postoperative day. He has been well without any complications. This case suggests that our method of approach to the giant aortic aneurysm with sternal adhesion and aortic regurgitation, and the use of extracorporeal circulation in view of the annuloaortic ectasia is effective and safe in case of reoperation.