Orthotopic transplantation of the bioengineered lung using a mouse-scale perfusion-based bioreactor and human primary endothelial cells.

Whole lung engineering and the transplantation of its products is an ambitious goal and ultimately a viable solution for alleviating the donor-shortage crisis for lung transplants. There are several limitations currently impeding progress in the field with a major obstacle being efficient revascularization of decellularized scaffolds, which requires an extremely large number of cells when using larger pre-clinical animal models. Here, we developed a simple but effective experimental pulmonary bioengineering platform by utilizing the lung as a scaffold. Revascularization of pulmonary vasculature using human umbilical cord vein endothelial cells was feasible using a novel in-house developed perfusion-based bioreactor. The endothelial lumens formed in the peripheral alveolar area were confirmed using a transmission electron microscope. The quality of engineered lung vasculature was evaluated using box-counting analysis of histological images. The engineered mouse lungs were successfully transplanted into the orthotopic thoracic cavity. The engineered vasculature in the lung scaffold showed blood perfusion after transplantation without significant hemorrhage. The mouse-based lung bioengineering system can be utilized as an efficient ex-vivo screening platform for lung tissue engineering.

A straightforward guide to the swine left upper lobar transplant model: procedures and techniques.

With the rising demand for lung transplants, especially for adults with smaller chest cavities and children, a significant donor-recipient size mismatch challenge exists. A solution is lobar lung transplants from deceased donors with otherwise unsuitable lungs due to local damage. Despite its promise, early post-transplant mortality rates are comparatively high, emphasizing the need for meticulous donor selection and graft evaluation. This video tutorial introduces a detailed methodology for a porcine left upper lobar lung transplant model, from preoperative measures to reperfusion. Steps encompass preoperative measures, donor and recipient preparations, graft procurement and specific anastomosis procedures for the bronchus, pulmonary artery and left atrium. This guidance, derived from rigorous translational research, not only contributes to the knowledge of safe lobar lung transplants in animals but also promises potential implications for clinical practice.

Transanal total mesorectal excision of giant villous tumor of the lower rectum with McKittrick-Wheelock syndrome: a case report of a novel surgical approach.

BACKGROUND: McKittrick-Wheelock syndrome (MKWS) is caused by a villous tumor of the rectosigmoid colon with hypersecretion of mucus containing electrolytes. Complete resection of the tumor is needed to cure this disease. Transanal total mesorectal excision (TaTME) is currently a promising treatment for lower rectal tumor because of the reliability of its resection margin especially in bulky tumor. We present this first case report of a TaTME for MKWS with a lower rectal tumor. CASE PRESENTATION: An 81-year-old woman was admitted to our hospital with diarrhea and acute renal failure. Computed tomography and magnetic resonance imaging examinations revealed an 80-mm-sized enhanced tumor located in her lower rectum without lymph node swelling and distant metastasis. A giant villous tumor secreting mucus was seen in the lower rectum to the anal canal during colonoscopy. The result of tumor biopsy was adenocarcinoma. To preserve the anal function and ensure distal margin, we chose TaTME for curative resection. After improving the electrolyte imbalance, TaTME was performed successfully and R0 resection was achieved. There was no sign of recurrence or electrolyte depletion for 1 year after the surgery. CONCLUSION: TaTME could be a promising surgical approach for giant villous tumor with MKWS in the lower rectum.