The optimal timing of cardiac surgery for infective endocarditis in patients with severe brain complication remains unclear. We present here the successful surgical treatment of a case of infected mitral endocarditis with intractable heart failure, disseminated intravascular coagulation (DIC), and cerebral infarction with hemorrhage. A 37 year-old woman who received chemotherapy for breast cancer developed mitral infective endocarditis perhaps caused by infection of the implanted central venous access device and was referred to our hospital for an emergency operation. On admission, she had a mild fever and showed motor aphasia and right-sided hemiplegia. Brain CT scan findings revealed a cerebral infarction in the area of the left middle cerebral artery and a cerebral hemorrhage in the right occipital lobe. Echocardiography showed severe mitral regurgitation with huge mobile vegetation. Chest X-ray revealed severe pulmonary congestion and laboratory data showed DIC. After the mitral valve replacement with a bioprosthetic valve following complete excision of infected tissue, she was extubated on the first postoperative day with dramatic improvement of infectious signs and heart failure. Postoperative brain CT showed a new small brain hemorrhage, but no aggravation of the preoperative cerebral lesion. After she underwent surgical drainage for brain abscess on the 15th postoperative day, her postoperative course was uneventful. Even though this report is limited to a single case, only aggressive and prompt surgical intervention could relieve the intractable conditions in such a patient with extremely high risk.

Mitral valve reoperation through a median sternotomy is technically challenging and carries higher postoperative morbidity and mortality than the primary operation, especially for a patient with patent coronary bypass grafts. We here present 3 cases of mitral valve reoperation using the beating heart technique under normothermic cardiopulmonary bypass via a mini-thoracotomy. The reasons that precluded sternal reentry were as follows : previous coronary bypass and patent internal mammary artery grafts in 2 cases, and a history of mediastinal wound infection at the initial operation in 1 case. All cases were carried out via right mini-thoracotomy and cardiopulmonary bypass using arterial cannulation via the ascending aorta or the femoral artery, and venous cannulation via the femoral vein and the superior vena cava. Mitral valve repair was performed for 1 case, and valve replacement for 2 cases. Transfusion was not necessary, except for 1 case that had anemia due to hemolysis preoperatively. All patients were discharged without major complications. This technique is a safe and feasible option for a mitral valve reoperation that excludes re-sternotomy, extensive pericardial dissection and aortic clamping, thereby minimizing risks of bleeding, graft injury and myocardial damage.

A 61-year-old man who had hypertension and renal dysfunction (serum creatinine : 1.5-2.0 mg/dl) was referred to our hospital for an abnormal shadow on chest roentgenogram. Chest CT scan with contrast revealed a distal aortic arch aneurysm (maximum diameter 52 mm) and left subclavian artery aneurysm (maximum diameter 30 mm). For the surgical treatment of the aneurysms, left hemi-collar incision and left subclavian incision followed by median sternotomy were performed. After the left subclavian artery was secured distal to the aneurysm, a ringed dacron graft was anastomosed with the distal left subclavian artery. Cardiopulmonary bypass was commenced, and selective cerebral perfusion was instituted at 25°C. The aorta was transected at the origin of the left common carotid artery. A 30 mm stent graft (length 13 cm) was inserted and was fixed on the transected aorta using 4-0 Prolene continuous suture. Then a branched dacron graft was sewn onto the transected aorta and the stent graft. The left common carotid artery and the brachiocephalic artery were anastomosed onto side branches of the graft. The left subclavian artery was reconstructed by anastomosing the ringed bypass graft onto one of the side branches. The left subclavian artery was ligated between the aneurysm and the origin of the vertebral artery, thereby interposing the subclavian artery aneurysm. After proximal anastomosis was done and the heart was reperfused, the patient was weaned from cardiopulmonary bypass. The patient was discharged without any major complication. Two years after the operation, the patient is doing well and there is no evidence of aneurysmal dilatation or endoleak. In conclusion, frozen elephant trunk technique provides an alternative to conventional graft replacement, resulting in complete exclusion of these aneurysms in a single stage. However, long-term follow up is warranted in order to ensure the durability of the stent graft.

A 75-year-old male with a previous history of coronary artery bypass grafting (LITA-LAD, RITA-RA-4PD-14PL) was referred to our hospital for congestive heart failure. Cardiac workup revealed severe ischemic mitral regurgitation which required surgical correction. His preoperative coronary arterial computed tomography demonstrated total occlusion of both orifices of the native coronary arteries, and the complete dependence of his myocardial blood supply on the patent bypass grafts without any evidence of ischemia. Therefore, antegrade cardioplegia could not be applied for cardiac protection during the procedure. Continuous retrograde cardioplegia was planned to be applied in a case where both arterial grafts could be dissected and clamped whereas systemic hyperkalemia and mild hypothermia would be applied in case where the clamp would be impossible. Intraoperatively, both arterial grafts could be dissected and clamped and we performed mitral annuloplasty and tricuspid annuloplasty using continuous retrograde cardioplegia. The patient could be weaned off cardiopulmonary bypass without difficulty, and his postoperative course was uneventful. We conclude that continuous retrograde cardioplegia is a safe and viable option, especially when antegrade cardioplegia is not securely delivered due to an occluded coronary ostia.