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BACKGROUND: Liver transplantation is the only treatment for end-stage and genetic liver diseases. The main burden of this treatment is the shortage of both living and cadaveric liver donors. An alternative treatment is using liver cell transplantation, which can be obtained from unused livers for transplantation. These hepatocytes should be kept ready in viable and functional situation in a frozen state to be instantly used when they would be needed. In our previous experience, we had isolated hepatocytes from unused livers. OBJECTIVE: To find a preserving solution for increasing viability and function of the isolated hepatocytes that are stored to be transplanted. METHODS: 9 cadaveric donor livers, which were not used for transplantation due to various causes such as severe steatosis, were selected to isolate hepatocytes. Various cold storage solutions were tried to find the best temperature for more viability and functionality for preservation of hepatocytes. University of Wisconsin (UW) solution and Williams E media were used as control media. 2 anti-apoptotic and anti-oxidative solutions, i.e., α-lipoic acid and ursodeoxycholic acid (UDCA), were used as cold preservatives solutions. The numbers of viable hepatocytes were estimated by trypan blue method; the functionality was assessed by the cells ability to produce urea. RESULTS: The highest number of viable and functional hepatocytes was obtained from freshly isolated cells. However, after preservation, the number of these viable hepatocytes and their functionality were not significantly different in cold storage solutions comparing to the control media used. Functionality of the isolated hepatocytes stored in UW with and without UCDA solution was similar to freshly isolated hepatocytes. CONCLUSION: Preservatives with anti-apoptotic and antioxidant activity could not increase the number of viable hepatocytes. Functionality of cold storing hepatocytes could be preserved similar to freshly isolated hepatocytes by UW solution with and without UCDA.
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UNLABELLED: Recent investigations have suggested that antimicrobial photodynamic therapy (aPDT) can be an alternative treatment for the management of periodontal infections. However, currently there is very limited data regarding the photocytotoxicity of this method on human gingival fibroblast (HuGu) cells. AIM: The in vitro optimal concentrations of indocyanine green (ICG) and curcumin as photosensitizers (PSs) and the irradiation time of diode laser emission were evaluated by assessing the photocytotoxicity of the treatment on HuGu cells. MATERIALS AND METHOD: Monolayers of HuGu cells were incubated with various final concentrations of ICG (500, 750, 1000, 1250, 1500, 1750, and 2000µg/ml) and curcumin (3, 4, 5, 10, and 20mM). Three exposure times of the diode laser (30s, 60s, and 2×30s irradiation with an interval of 1min between each) and one of exposure time of 5min for LED were tested; cell viability was determined using neutral red assay. Chlorhexidine (CHX) as a gold standard antimicrobial agent for periodontal disease was considered as a control group. RESULTS: ICG and curcumin significantly reduced HuGu cell viability at concentrations below 1000µg/ml and 10mM, respectively (P<0.01). Cytotoxicity was higher when the cells were treated for 2×30s irradiation with an interval of 1min and then again exposed to the laser for 30s (2% and 0.1%). CHX demonstrated no significant reduction in HuGu cell survival. CONCLUSION: Photocytotoxicity is influenced by PS concentration, exposure time of PS, and time of irradiation. High doses of ICG and curcumin with lowest exposure time of light source and without cytotoxic effects may be an effective strategy for aPDT as an alternative treatment for periodontal disease.