High performance organic solar cells through improved electrode designs and active layer morphology

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"Idealized" vs. "true" learning curves: The case of laparoscopic liver resection

Background Learning curves are believed to resemble an "idealized" model, in which continuous improvement occurs until a plateau is reached. We hypothesized that this "idealized" model would not adequately describe the learning process for a complex surgical technique, specifically laparoscopic liver resection (LLR). Methods We analyzed the first 150 LLRs performed by a surgeon with expertise in hepatobiliary/laparoscopic surgery but with no previous LLR experience. We divided the procedures performed in 5 consecutive groups of 30 procedures, then compared groups in terms of complications, operative time, length of stay, and estimated blood loss. Results We observed an increase in operative complexity (3.3% major operations in Group 1 vs. 23.3% in Group 5, p = 0.05). Complications decreased from Group 1 to Group 2 (20%-3%), but increased again as more complex procedures were performed (3% in Group 2-13% in Group 5). Similar improvement/regression patterns were observed for operative time and EBL. Discussion The "true" learning curve for LLR is more appropriately described as alternating periods of improvement and regression until mastery is achieved. Surgeons should understand the true learning curves of procedures they perform, recognizing and mitigating the increased risk they assume by taking on more complex procedures

The gracilis myocutaneous free flap in swine: An advantageous preclinical model for vascularized composite allograft transplantation research

Vascularized composite allotransplantation (VCA) has become a clinical reality, prompting research aimed at improving the risk‐benefit ratio of such transplants. Here, we report our experience with a gracilis myocutaneous free flap in Massachusetts General Hospital miniature swine as a preclinical VCA model. Fourteen animals underwent free transfer of a gracilis myocutaneous flap comprised of the gracilis muscle and overlying skin, each tissue supplied by independent branches of the femoral vessels. End‐to‐end anastomoses were performed to the common carotid artery and internal jugular vein, or to the femoral vessels of the recipients. Thirteen of fourteen flaps were successful. A single flap was lost due to compromise of venous outflow. This model allows transplantation of a substantial volume of skin, subcutaneous tissue, and muscle. The anatomy is reliable and easily identified and harvest incurs minimal donor morbidity. We find this gracilis myocutaneous flap an excellent pre‐clinical model for the study of vascularized composite allotransplantation

Vascularized composite allograft transplant survival in miniature swine: Is mhc tolerance sufficient for acceptance of epidermis

BACKGROUND: We have previously reported that MGH miniature swine which had accepted class-I mismatched kidneys long-term (LT) following 12 days of high dose Cyclosporine (CyA), uniformly accepted donor-MHC matched kidneys without immunosuppression but rejected donor-MHC matched split-thickness skin grafts (STSG) by day 25, without changes in renal graft function or anti-donor in vitro responses. We have now tested whether this “split tolerance” would also be observed for the primarily-vascularized skin of vascularized composite allografts (VCAs). METHODS: Group 1 animals (n=3) received donor-MHC matched VCAs <70 days following primary kidney transplant (KTx). Group 2 animals (n=3) received a second donor-matched t KTx followed by a donor-matched VCA >200 days after primary KTx. RESULTS: Animals in Group 1 lost the epidermis on days 28, 30, and 40, with all other components of the VCAs remaining viable. Histology showed cellular infiltration localized to dermal-epidermal junction. One of 3 recipients of VCAs including epidermis in Group 2 accepted all components of the VCAs (>200 days). The other two recipients lost only the epidermis at day 45 and 85, with survival of the remainder of the VCA long-term. CONCLUSIONS: All tissues of a VCA are accepted long-term on animals tolerant of class-I mismatched kidneys, with the exception of epidermis, the survival of which is markedly prolonged compared to STSG, but not indefinite. Exposure of tolerant animals to second donor-matched kidneys prior to VCA increases the longevity of the VCA epidermis, suggesting an increase in the immunomodulatory mechanisms associated with tolerance of the kidney