When applied to treating diseases such as the hemorrhage in alimentary tract and tumors, LDRF-50 RF curer is effective, safe and easy to operate. There is no pollution, tissue adhesion and damage to the endoscope during the process of treatment.

AIM: To observe the effect of partial liquid ventilation with perfluorocarbon on gas exchange, hemodynamics and lung histological change in the piglets with surfactant depletion-induced acute lung injury. METHODS: 12 piglets were treated by lung lavage to a partial pressure of oxygen in arterial blood (PaO 2) below 100 mmHg for one hour and randomly divided into gas ventilation group (control group) and partial liquid ventilation (PLV) group, in PLV group, piglets received PFC (FC3280) intratracheally at doses of 15 mL/kg. The parameters of gas exchange and hemodynamics were measured before lung lavage, after lung lavage when the acute lung injury (ALI) was established, and 1 hour, 2 hours after ALI. Animals underwent euthanasia at the end of the study, lung histologic analysis followed. RESULTS: Surfactant depletion by lung lavage induced a stable acute lung injury.Gas exchange increased markedly in the animals that underwent PLV, less hemodynamic damage was observed in PLV group compared with the animals in GV group. Lung histologic analysis demonstrated a less lung damage, including atelectasis, neutrophil excudation, intra-alveolar hemorrhage and interstitial edema in PLV group compared with control group. CONCLUSION: In piglets with surfactant depletion-induced acute lung injury, partial liquid ventilation with perfluorocarbon can improve the gas exchange with less adverse hemodynamic effect and less lung injury compared with conventional gas ventilation.

OBJECTIVE: To prepare podophyllotoxin-loaded solid lipid (PPT-SLN) gel and establish its quality control method. METHODS: With stearic acid, stearylamine, soybean lecithin as cosurfactant and PPT as principal agent, PPT-SLN suspension was prepared by the method of emulsion evaporation and solidification at a low temperature, then prepared into PPT-SLN gel with carbomer used as gel matrix. The physicochemical properties of the preparation were investigated, the content and entrapment efficiency of PPT were determinated by high-performance liquid chromatography (HPLC), respectively. The stability of the preparation was investigated as well. RESULTS: PPT-SLN gel appeared as lacte translucent semisolid, with its property and test results all in conformity with the related specification in Chinese Pharmacopoia (2005 edition). The nanoparticles were well-distributed in round or oval shape, with an average particle size of (105.3?34.7) nm, entrapment efficiency of 72.5% and pH value of (7.2?0.3). The preparation was stable within 6 months under room temperature. CONCLUSION: The preparation technology of PPT-SLN gel is feasible and its quality is controlable.