Rapid Expansion of the Descending Thoracic Aortic Aneurysm and Aneurysm-Induced DIC Following Total Arch Replacement with a Long Elephant Trunk / 日本心臓血管外科学会雑誌

<p>A 74-year-old woman presented to our hospital with complaints of dysphagia. On examination, we diagnosed extensive thoracic aortic aneurysm and esophageal compression due to a descending thoracic aortic aneurysm. We planned a two-stage approach for repairing the extensive thoracic aortic aneurysm ; the first stage involving the repair of the ascending and arch segments, and the second stage involving the repair of the descending aorta. In the first stage, we performed the Bentall procedure and total arch replacement with a long elephant trunk. Following this, her dysphagia resolved, although the size of the descending aortic aneurysm was the same as that before the procedure (49 mm in diameter). We decided to treat her conservatively in the outpatient clinic without the second stage, because the descending aorta was asymptomatic and not sufficiently large. One year later, she presented with a sudden recurrence of dysphagia and swelling of buttocks. She was diagnosed with an expansion of the descending aortic aneurysm (62 mm in diameter) and a hematoma in the gluteal muscle due to aneurysm-induced disseminated intravascular coagulation (DIC). After emergency admission, she underwent a successful thoracic endovascular aortic repair and was discharged following a smooth recovery from dysphagia and aneurysm-induced DIC. We report this case along with a review of the literature.</p>

Current Status and Future Perspectives of Cardioplegic Protection in Cardiac Surgery, Highlighting the Mechanisms of Targeted Cellular Components / 日本心臓血管外科学会雑誌

“Depolarized arrest”, induced by hyperkalemic (moderately increased extracellular potassium) cardioplegia is the gold standard to achieve elective temporary cardiac arrest in cardiac surgery. Hyperkalemic cardioplegic solutions provide good myocardial protection, which is relatively safe, and easily and rapidly reversible. However, this technique has detrimental effects associated with ionic imbalance involving sodium and calcium overload of the cardiac cell induced by depolarization of the cell membrane. Hence, the development of an improved cardioplegic solution that enhances myocardial protection is anticipated as an alternative to hyperkalemic cardioplegia. In this review, we assess the suitability and clinical potential of cardioplegic agents to induce “non-depolarized arrest” from the viewpoint of rapid cardiac arrest, myocardial protection, reversibility, and toxicity. “Magnesium cardioplegia” and “esmolol cardioplegia” have been shown to exert superior protection with comparable safety profiles to that of hyperkalemic cardioplegia. These alternative techniques require further examination and investigation to challenge the traditional view that hyperkalemic arrest is best. Endogenous cardioprotective strategies, termed “ischemic preconditioning” and “ischemic postconditioning”, may have a role in cardiac surgery to provide additional protection. The elective nature of cardiac surgery, with the known onset of ischemia and reperfusion, lends it to the potential of these strategies. However, the benefit of preconditioning and postconditioning during cardiac surgery is controversial, particularly in the context of cardioplegia. The clinical application of these strategies is unlikely to become routine during cardiac surgery because of the necessity for repeated aortic crossclamping with consequent potential for embolic events, but offers considerable potential especially if “pharmacological” preconditioning and postconditioning could be established.