Endoscopic aortic valve surgery in isolated and concomitant procedures.

OBJECTIVES: To evaluate early outcomes of endoscopic aortic valve replacement (AVR) and risks of concomitant procedures done through the same working port. METHODS: At our institution, we performed a data analysis of 342 consecutive patients (from July 2013 to May 2021) who underwent endoscopic AVR with or without associated major procedure. Preoperative, intraoperative, postoperative data were evaluated. Subsequently, we perform a comparative analysis between the isolated and concomitant surgery group. The surgical access was a 3- to 4-cm working port in the second right intercostal space and 3 additional 5-mm mini-ports for the introduction of the thoracoscope, the transthoracic clamp and the vent line. Cardiopulmonary by-pass was achieved through peripheral cannulation. RESULTS: 105 patients (30.7%) underwent combined procedure: 2 coronary artery bypass (1.9%), 21 ascending aorta replacement (19.6%), 41 mitral surgery (38.3%), 16 mitral and tricuspid surgery (15%) and 25 other procedure (27%). Death occurred in 1 patient (0.4%) in the isolated group versus 2 patients (1.9%) in the combined group (P = 0.175). Seven strokes were observed, 4 in isolated procedures (1.7%) and 3 in the concomitant ones (2.85%) (P = 0.481). Surgical revision for bleeding was performed always through the same access in 13 patients (5.4%) versus 11 patients (10.4%) (P = 0.096). Pacemaker implantation was necessary in 5 patients (2.1%) versus 8 patients (7.6%) (P = 0.014). Median intubation time was 5 (2) h vs 6 (8) (P < 0.080). CONCLUSIONS: Through a single working port made for endoscopic AVR, a concomitant procedure may be done without affecting in-hospital mortality and postoperative stroke rate.

Minimally Invasive Endoscopic Aortic Valve Replacement: Operative Results.

To describe our endoscopic aortic valve replacement (E-AVR) technique and to evaluate its early results regardless of the type of prosthetic valve implanted and the patients' characteristics. From July 2013 to September 2018, 125 patients (76 males, mean age 68.8 ± 10.9 years, mean EuroScore II 1.51 ± 1.39) underwent isolated E-AVR due to a severe stenosis in 99 cases and insufficiency in 26 cases. The surgical access was a 3-4 cm working port in the second right intercostal space with no rib-spreading and 3 additional 5 mm miniports for the introduction of a 30-degree thoracoscope, the Chitwood clamp, and the vent line. Cardiopulmonary bypass (CPB) was achieved through a femoro-femoral cannulation. All patients successfully underwent E-AVR. Stended bioprostheses were implanted in 56 cases, Rapid Deployment and Sutureless valves in 23 and 46 cases, respectively. Mean cross-clamping and CPB times were 87.5 ± 22.1 and 126.1 ± 28.4 minutes, respectively, and a significant difference between the types of prostheses was observed: 69.1 ± 15.1 and 106.2 ± 21.8 minutes (Sutureless) vs 93.2 ± 15.1 and 135.5 ± 21.8 minutes (Rapid Deployment) vs 100.6 ± 17.2 and 138.9 ± 21.9 minutes (Stented). Mean ventilation and ICU times and hospital stay were 10.9 ± 39.3 hours, 45.9 ± 58.4 hours, and 8.3 ± 9.3 days, respectively. Thirty-day mortality was 0.8%. One patient (0.8%) needed a re-exploration for bleeding and 3 patients (2.4%) required a new permanent pacemaker implantation. No major neurologic events were observed. No paravalvular leakage was detected at discharge. E-AVR is associated with low mortality and few complications. Sutureless bioprostheses significantly reduce cross-clamping and CPB times. In dedicated centers, this approach may become a valid alternative to other minimally invasive techniques.

Spatio-temporal population structuring and genetic diversity retention in depleted Atlantic bluefin tuna of the Mediterranean Sea.

Fishery genetics have greatly changed our understanding of population dynamics and structuring in marine fish. In this study, we show that the Atlantic Bluefin tuna (ABFT, Thunnus thynnus), an oceanic predatory species exhibiting highly migratory behavior, large population size, and high potential for dispersal during early life stages, displays significant genetic differences over space and time, both at the fine and large scales of variation. We compared microsatellite variation of contemporary (n = 256) and historical (n = 99) biological samples of ABFTs of the central-western Mediterranean Sea, the latter dating back to the early 20th century. Measures of genetic differentiation and a general heterozygote deficit suggest that differences exist among population samples, both now and 96-80 years ago. Thus, ABFTs do not represent a single panmictic population in the Mediterranean Sea. Statistics designed to infer changes in population size, both from current and past genetic variation, suggest that some Mediterranean ABFT populations, although still not severely reduced in their genetic potential, might have suffered from demographic declines. The short-term estimates of effective population size are straddled on the minimum threshold (effective population size = 500) indicated to maintain genetic diversity and evolutionary potential across several generations in natural populations.