Lymphatic drainage of the heart]

The study was carried out on 91 adult cadavers to point out clearly the lymphatic drainages of the heart into the blood circulation. 45 right and 63 left ventricles and 9 right and 5 left atria were injected by means of a green modified gerota medium. A right collecting trunk received its afferents from 29 right and 5 left ventricles, ran upwards in front of the ascending aorta, involved the left brachiocephalic nodes and opened into the left subclavicular veins but also in 1 case in 5 into thoracic duct. A left collecting trunk received its afferents from 59 left and 23 right ventricles, ascended along the pulmonary trunk, involved the right paratracheal nodes and opened into the right subclavicular veins. From the right paratracheal nodes were also injected the left tracheobronchial nodes in 14 cases, and then the left brachiocephalic nodes twice, the left paratracheal nodes in 3 cases until the thoracic duct once and directly the thoracic duct in the mediastinum in one case. Afferents from the right atria ran upwards the superior vena cava and involved the right brachiocephalic nodes but connected also with the right paratracheal nodes as did the afferents of the left atria too. The connections with the thoracic duct must be emphasized.     

Abdominal aortic aneurysms after heart transplantation.

BACKGROUND: In recent years abdominal aortic aneurysms were diagnosed in several heart transplant recipients at our center. Only case reports or small series have been reported previously and little is known about abdominal aortic aneurysms after heart transplantation. Therefore, the goals of this study were to estimate the incidence of this condition after heart transplantation, to identify risk factors for its development, and to assess its clinical consequences. METHODS: Our investigation was a retrospective, single-center cohort study of 368 consecutive patients transplanted between 1984 and 1999. RESULTS: During a mean follow-up of 75 +/- 49 months, 37 of the 368 (10%) transplant recipients and 36 of 202 (18%) of the sub-group with a history of ischemic heart disease were found to have an abdominal aortic aneurysm. All patients were male, and all except 1 had a history of ischemic heart disease. A history of ischemic heart disease prior to heart transplantation was the sole independent risk factor for developing an aneurysm by multivariate analysis. Aneurysm-related events occurred earlier and more frequently in the 7 transplant recipients who already had a dilated abdominal aorta prior to transplantation. The abdominal aortic aneurysm was the direct or indirect cause of death in at least 9 patients. CONCLUSIONS: Abdominal aortic aneurysms are relatively frequent after heart transplantation, occur at a younger age than in the general population, and have serious clinical consequences. Close ultrasonographic follow-up of patients with a history of ischemic heart disease or with an abnormal abdominal aorta prior to heart transplantation seems indicated.     

Abdominal aortic aneurysms following orthotopic heart transplantation

The purpose of these authors' study was to analyze their center's experience with orthotopic heart transplantation (OHT) and abdominal aortic aneurysms (AAA) with particular attention to corticosteroid dosing, hemodynamic parameters, and aneurysm growth rate. A retrospective review of all patients (453) who underwent OHT at their university-affiliated medical center over an 18-year period (1981-1999) was undertaken. Nine (2%) patients who developed AAAs were identified and aneurysm growth was correlated with corticosteroid immunosuppression and hemodynamic parameters. The mean age of OHT patients was 44.5 +/-15 years and the majority were males (371 males, 82%). Median follow-up was 5.7 years. Ischemic cardiomyopathy (IC) was the most common indication for transplantation (45.5% of patients). All AAA patients were male (p=0.157), with a mean age of 58.4 +/-4.8 years (p=0.001), and had undergone OHT for IC (p=0.001). Mean arterial blood pressure and ejection fraction in the AAA patients had increased from pretransplant values of 107 mm Hg and 14.3 +/-5.7% to 142 mm Hg (p=0.017) and 54.1 +/-14.1% (p<0.001), respectively, before aneurysm repair. Mean aneurysm diameter at the time of repair was 6.0 +/-0.8 cm, and the average growth rate was 1.2 +/-0.4 cm/year in the 4 patients in whom it could be measured. Aneurysm repair was performed urgently in 2 patients and electively in 7 patients with 1 early postoperative death (11%). The extent of corticosteroid immunosuppression, corticosteroid pulses, and total corticosteroid dosing did not correlate with the rate of aneurysm growth. Improved hemodynamics and progressive posttransplant hypertension may contribute to aneurysm formation and growth in this group of patients.