Detachable Aortic Clamp for Minimally Invasive Cardiac Surgery.

Since its first implementation, minimally invasive cardiac surgery has become more and more popular among surgeons. By avoiding a complete opening of the sternum, this surgery is traditionally associated with a faster recovery, less surgical pain and less postoperative bleeding and transfusions. With its growing popularity, the need for specifically designed surgical instrumentation is evident. Since 2008, the detachable-branch Glauber clamp (Cardiovision-Trytech, Tokyo, Japan) has been used to facilitate aortic cross-clamp during minimally invasive cardiac surgery, to optimize the intraoperative visualization field without the need for adjunctive incisions of the thorax. It has been specifically developed for limited single-access minimally invasive valve surgery. The clamp is introduced through the main access incision (mini-sternotomy or mini thoracotomy) by means of a specifically designed delivery system, which is subsequently removed, leaving inside the thorax only the detachable closed branches on the aorta. Since its first implementation, the clamp has been used in numerous patients at several cardiac surgery centers worldwide. Over the years, attempts have been made to improve its ergonomics and enhance its performance. The G2 detachable-branch Glauber clamp (USB Medical, Hatboro, PA, USA) occupies a smaller space inside the thorax, has a simplified gripping mechanism and comes with detachable arms that enhance versatility with up to 10 possible clamp configurations. This article describes the characteristics of detachable-branch aortic clamps and compares them to other aortic cross-clamps that are currently available for minimally invasive cardiac surgery.

Minimally invasive cardiac surgery for complex procedures: extensive septal myectomy and double valve replacement.

In this video tutorial, we demonstrate that minimally invasive cardiac surgery and all its benefits can be applied even to complex, multiple cardiac procedures. We present a 71-year-old patient with severely obstructive hypertrophic cardiomyopathy, moderate mitral regurgitation for systolic anterior motion of the mitral valve, moderate aortic stenosis and regurgitation and atrial fibrillation. We performed a mitroaortic valve replacement, transmitral and transaortic septal myectomy and left atrial appendage closure through a minimally invasive approach (right anterolateral minithoracotomy). After establishing peripheric cardiopulmonary bypass, aortic cross-clamping and a left atrium opening, the anterior mitral leaflet was incised circumferentially at its insertion on the annulus to allow an optimal transmitral myectomy. Subsequently, mitral valve removal was completed, and a bioprosthesis was implanted. After closure of the left atrium, the left atrial appendage was closed using a 40-mm device (Atriclip). The aorta was then opened, the aortic valve was excised and a transaortic septal myectomy was completed. Finally, a sutureless aortic bioprosthesis was implanted. Postoperative transoesophageal and transthoracic surgery demonstrated a residual left ventricular outflow tract gradient of 14 mmHg and the correct performance of both biological prostheses. Minimally invasive heart surgery can be offered even to patients requiring complex and multiple procedures, including septal myectomy. Combining the benefits of the operation with those of a minimally invasive approach may optimize postoperative and long-term surgical outcomes.

Mitral Valve Re-Repair Due to Chordal Pseudo-Elongation Through Repeated Right Anterior Minithoracotomy.

OBJECTIVE: We aim to show the step-by-step surgical technique of mitral valve re-repair by means of a repeated right anterior minithoracotomy in a case of a procedure-related early mitral valve repair failure due to left ventricular positive remodeling and chordal pseudo-elongation. METHODS: The patient was readdressed to our institution for an early severe mitral valve regurgitation, less than a year after performing a right minithoracotomy mitral valve repair (42-mm annular ring implantation, P2 triangular resection, and P2 neochord positioning). The mechanism was attributed to a positive left ventricle remodeling and neochordal pseudo-elongation. Therefore, we decided to perform a mitral valve re-repair in a redo minimally invasive cardiac surgery. We describe in a video-guided step-by-step fashion the surgical procedure, from the reopening of the right anterior minithoracotomy to the surgical strategy chosen to address the re-repair, guided by the mechanism of the previous repair failure. RESULTS: We replaced the previously implanted ring with a smaller one and positioned a new polytetrafluoroethylene 4-0 neochord at the P2 level. The patient was discharged home on the fifth postoperative day after an uneventful hospital stay. Predischarge echocardiogram demonstrated undetectable residual mitral valve regurgitation. At 3-month follow-up, echocardiographic and clinical data were encouraging. At 9-month follow-up, the patient endorsed no recurrence of cardiologic symptoms. CONCLUSIONS: Redo minimally invasive cardiac surgery is a viable option even in case of a mitral valve re-repair due to previous repair failure, especially when procedure related in degenerative mitral disease. Combining the benefits of mitral valve re-repair with those of a minimally invasive surgery may optimize short-term and long-term outcomes.

Stroke after coronary artery bypass surgery: Can we predict full neurological recovery?

Postoperative stroke is a rare but feared complication after cardiac surgery. The clinical presentation and the evolution of postoperative stroke associated with bypass surgery are extremely heterogeneous and depend on multiple factors, which are not always easy to identify. Computed tomography scan parameters like visual rating scales, in particular, the age-related white matter changes and Mendes Ribero visual rating scale scores, could be used to predict postoperative stroke reconvalescence. Being reproducible and quickly appliable in everyday clinical practice, their implementation results are easy. Further studies are still required to validate these scores, to identify a "cut-off" value for highly likely or unlikely neurological recovery.

Postinfarction ventricular septal defect closure.

After a median full sternotomy, cardiopulmonary bypass is installed in the usual manner. Apical ventriculotomy is performed through the infarcted myocardium. Polypropylene pledgeted mattress sutures are passed from the right to the left ventricular side through the ventricular septal defect, with the pledgets remaining on the right ventricle. Great care must be taken to place the suture on healthy myocardium and away from the edge of the ventricular septal defect; otherwise the chances of a recurrent postoperative ventricular septal defect would increase. The sutures are subsequently positioned through a heterologous patch, previously prepared to be appropriate for the ventricular septal defect closure. A collar of 3 to 4 cm is left on the external side of the patch. A 4-0 polypropylene running suture is placed through this collar and the left ventricle to further reinforce the ventricular septal defect closure. The left ventricular incision is closed with polypropylene 3-0 continuous sutures. For each ventricular edge, the running suture is passed through 2 polytetrafluoroethylene felts: one on the endoventricular side and the other on the epicardial side. Finally, the suture line is reinforced with a continuous 2-0 polypropylene suture, which is passed through the polytetrafluoroethylene felts, the ventricular wall, and the heterologous patch used to close the ventricular septal defect.

Alternative techniques of right ventricular outflow tract reconstruction for surgical repair of truncus arteriosus.

OBJECTIVES: This study aimed to evaluate the outcomes and feasibility of different techniques of reconstruction of the right ventricular outflow tract (RVOT) in surgical repair of truncus arteriosus. METHODS: We retrospectively reviewed all consecutive patients with truncus arteriosus who underwent successful surgical repair in our centre between 1994 and 2017. We analysed late results according to the type of RVOT repair. RESULTS: We collected data from 29 survivors after truncus arteriosus repair. Six (20%) of them were affected by DiGeorge syndrome. The RVOT reconstruction was achieved using a valved conduit in 58.6%, while a direct right ventricle-pulmonary artery (RV-PA) anastomosis, with or without the interposition of the left atrial appendage, was performed in the remaining. At a median follow-up time of 7.9 years (interquartile range 1.8-13.1), 6 patients (3 affected by DiGeorge syndrome) died. Between the 2 groups, there were no differences in terms of the late mortality and onset of adverse events. However, the use of a conduit seemed more prone to reintervention and onset of adverse events. CONCLUSIONS: Different RVOT reconstruction techniques are safe and have similar late outcomes. However, use of a direct RV-PA anastomosis and left atrial appendage interposition may reduce the need for reoperation in the long term.