Allogeneic Left Atrial and Pulmonary Vein Transplant for Pulmonary Vein Stenosis

Techniques for harvest of the posterior left atrium and pulmonary veins from a suitable organ donor have been well established as this is currently accomplished during every harvest of lungs for lung transplantation. The difference in this therapy is that the lung parenchyma will not be utilized. However, the harvest from the donor will be exactly the same with the full lung block typically harvested for lung transplant removed and transported back to the site of implantation. The exact extent of pulmonary vein utilization from the lung block will be determined at the time of implantation based on the exact anatomy and location of the pulmonary vein disease of the recipient. As this represents a new transplantation approach, this program has been discussed with the United Network for Organ Sharing (UNOS) and the New England Organ Bank (NEOB). UNOS identified this as a new area of transplantation related to but separate from heart or lung transplantations. Eventually if this progresses to a national phase, it will require creation of a new patient waiting list and all the policies that accompany a new area of transplantation. Although there is enthusiasm at UNOS for this approach, they recommended that it be pursued as a regional research program as an initial step. The NEOB also has voiced support for this program in a meeting with them including their medical director. They are interested in supporting this program as a Region 1 research program and will perform a full evaluation for approval once local IRB approval has been granted. The Children's team will work closely with NEOB to create a list of potential patients and identify suitable donors. Utilizing standardized harvesting techniques will minimize any changes to the current harvest approach and definition of tissue allocation during the harvest procedure. As the lung parenchyma is unnecessary, it is expected that suitable donors for left atrial transplant would come from two sources: The first source is brain dead donors in whom the lungs are not allocated for transplantation based on rejection of the lungs for quality or no matching donors. The second source is donors after cardiac death (DCD) which are utilized in the adult population for kidney, liver and lung transplantation. DCD organs are not currently utilized pediatric lung transplantation. However, as the viability of these tissues, including the entire lung block is well established, these represent a potential donor pool for left atrial transplant patients. Certainly experience with preservation of the kidney grafts for hours or days with integrated perfusion systems has demonstrated the successful implantation of vascularized tissues appropriately preserved can be extended beyond the traditional four hour window targeted for lung transplantation. Kidney transplants are commonly done within 24 hours without evidence of impact on the vascular patency these grafts. In addition, only vascular tissue is being transplanted that has no effect on gas exchange or contractility. Accordingly it is expected that the goal implantation time for left atrial transplants after harvest will not need to be within the four to six hour window used for lung transplant but can be safely extended to 24 hours. This window extends the donor pool for left atrial transplants to the entire country. Excision of recipient left atrium and stenotic pulmonary veins and implantation of left atrial graft The set up for the operation will be identical to all major cardiopulmonary bypass cardiac cases. The surgical approach for the recipient will likely be a clamshell incision that crosses the sternum in the fourth interspace. This is the same incision used for lung transplant. The patient will be cannulated for cardiopulmonary bypass in the distal aorta, SVC and low in the IVC. Cardiopulmonary bypass will be initiated and the patient will be cooled to 18°C. Prior to arresting the heart, the donor left atrium and pulmonary veins will be inspected in the lung block. The pulmonary veins from the donor will be mobilized and prepared for resection from the lung block. The cross clamp will be applied and the heart arrested. The pulmonary veins of the recipient will be mobilized and transected beyond the level stenoses. The left atrium and pulmonary vein graft then be brought to the field and positioned in the orthotopic position. The anastomosis of the pulmonary veins will be completed with a generous diameter of the anastomotic area to minimize any risk of late anastomotic narrowing even in the smallest of pulmonary vein segments. The donor left atrium will be anastomosed to the posterior left atrial cuff of the heart. Only the affected pulmonary veins with stenosis will be transplanted. This may be one or up to all 4 main pulmonary veins. If an individual pulmonary vein or side of pulmonary veins are unaffected, they will not have any manipulation or intervention on them. A formal atrial fenestration will be created. Post-bypass evaluation with transesophageal echocardiogram will assess pulmonary vein velocities and flow. The chest will be closed and patient transferred intubated to the ICU. In the initial clinical experience with these transplants, a traditional immunosuppression protocol for heart transplants will be followed. Over time new protocols will be developed and tested which focused on minimizing the long-term immunosuppression regimens.