Usefulness of laparoscopic subtotal cholecystectomy with operative cholangiography for severe cholecystitis

PURPOSE: Cholecystectomy can become hazardous when inflammation develops, leading to anatomical changes in Calot’s triangle. We attempted to study the safety and efficacy of laparoscopic subtotal cholecystectomy (LSC) to decrease the incidence of complications and the rate of conversion to open surgery. METHODS: Patients who underwent LSC between January 2005 and December 2008 were evaluated retrospectively. The operations were performed laparoscopically irrespective of the grade of inflammation estimated preoperatively. However, patients with severe inflammation of the gallbladder underwent LSC involving resection of the anterior wall of the gallbladder, removal of all stones and placement of an infrahepatic drainage tube. To prevent intraoperative complications, including bile duct injury, intraoperative cholangiography was performed. RESULTS: LSC was performed in 26 elective procedures among 26 patients (eight females, 18 males). The median patient age was 69 years (range 43–82 years). The median operative time was 125 min (range 60–215 min) and the median postoperative inpatient stay was 6 days (range 3–21 days). Cholangiography was performed during surgery in 24 patients. One patient underwent postoperative endoscopic sphincterotomy for a retained common bile duct stone that was found on cholangiography during surgery. Neither complications nor conversion to open surgery were encountered in this study. CONCLUSIONS: LSC with the aid of intraoperative cholangiography is a safe and effective treatment for severe cholecystitis

Flame retardance-donated lignocellulose nanofibers (LCNFs) by the Mannich reaction with (amino-1,3,5-triazinyl)phosphoramidates and their properties

Nitrogen/phosphorus-containing melamines (NPCM), a durable flame-retardant, were prepared by the successive treatment of ArOH (Ar = BrnC6H5−n, n = 0, 1, 2, and 3) with POCl3 and melamine monomer. The prepared flame-retardants were grafted through the CH2 unit to lignocellulose nanofibers (LCNFs) by the Mannich reaction. The resulting three-component products were characterized using FT-IR (ATR) and EA. The thermal behavior of the NPCM-treated LCNF fabric samples was determined using TGA and DSC analyses, and their flammability resistances were evaluated by measuring their Limited Oxygen Index (LOI) and the UL-94V test. A multitude of flame retardant elements in the fabric samples increased the LOI values as much as 45 from 20 of the untreated LCNFs. Moreover, the morphology of both the NPCM-treated LCNFs and their burnt fabrics was studied with a scanning electron microscope (SEM). The heat release lowering effect of the LCNF fabric against the water-based paint was observed with a cone calorimeter. Furthermore, the mechanical properties represented as the tensile strength of the NPCM-treated LCNF fabrics revealed that the increase of the NPCM content in the PP-composites led to an increased bending strength with enhancing the flame-retardance