Shark mouth pancreaticojejunostomy reduced the rate of clinically related pancreatic fistula: a historic cohort comparative analysis.

BACKGROUND: A novel procedure called shark mouth pancreaticojejunostomy (SMP) was developed, for the reconstruction of the pancreatic stump which has a theoretical advantage for anastomosis healing and wide applicability. METHODS: A comparative study of the patients who underwent SMP (SMP cohort) and those who underwent end-to-end dunking pancreaticojejunostomy (historic cohort) at Peking University Third Hospital was conducted. Each group was analyzed for the incidence of clinically relevant postoperative pancreatic fistula (CR-POPF) and morbidities. RESULTS: The clinicopathological data of 151 patients from the SMP cohort and 82 patients from the historic cohort were analyzed. In the SMP group, the rate of CR-POPF was 7.3% (11/151), which was significantly lower than the rate of CR-POPF in the historic group as 19.5% (16/82) (P = 0.005). The primary results were unaffected by sensitivity analyses based on several risk factors for CR-POPF. The rates of morbidities besides CR-POPF were 15.9% (24/151) in the SMP group and 17.1% (14/82) in the historic cohort (P = 0.194). The principal results were not changed by the propensity score matched (PSM) analysis. CONCLUSION: SMP is a safe and simple surgical procedure for the reconstruction of the pancreatic stump compared with end-to-end dunking pancreticojejunostomy.

Biosynthetic Structural Proteins with Super Plasticity, Extraordinary Mechanical Performance, Biodegradability, Biocompatibility and Information Storage Ability.

Degradable bioplastics have attracted growing interest worldwide. However, it is challenging to develop bioplastics with a simple processing procedure, strong mechanical performance, good biocompatibility, and adjustable physicochemical properties. Herein, we introduced structural proteins as building blocks and developed a simple environmentally friendly approach to fabricate diverse protein-based plastics. A cost-effective and high-level production approach was developed through batch fermentation of Escherichia coli to produce the biomaterials. These bioplastics possess super plasticity, biocompatibility, biodegradability, and high resistance to organic solvents. Their structural and mechanical properties can be precisely controlled. Besides, high density information storage and hemostatic applications were realized in the bioplastic system. The customizable bioplastics have great potential for applications in numerous fields and are capable to scale up to the industrial level.