Mouse Models of Nonalcoholic Steatohepatitis: Head-to-Head Comparison of Dietary Models and Impact on Inflammation and Animal Welfare.

A variety of dietary nonalcoholic steatohepatitis (NASH) mouse models are available, and choosing the appropriate mouse model is one of the most important steps in the design of NASH studies. In addition to the histopathological and metabolic findings of NASH, a sufficient mouse model should guarantee a robust clinical status and good animal welfare. Three different NASH diets, a high-fat diet (HFD60), a western diet (WD), and a cafeteria diet (CAFD), were fed for 12 or 16 weeks. Metabolic assessment was conducted at baseline and before scheduled sacrifice, and liver inflammation was analyzed via fluorescence-associated cell sorting and histopathological examination. Clinical health conditions were scored weekly to assess the impact on animal welfare. The HFD60 and WD were identified as suitable NASH mouse models without a significant strain on animal welfare. Furthermore, the progression of inflammation and liver fibrosis was associated with a decreased proportion of CD3+ NK1.1+ cells. The WD represents a model of advanced-stage NASH, and the HFD60 is a strong model of nonalcoholic fatty liver disease (NAFLD) and metabolic syndrome. However, the CAFD should not be considered a NASH model.

Preparation, characterization and catalytic activity of NiOx and NiOx/ZrO2 for oxidation of phenol in aqueous solution.

In the present study bulk NiO(x) and supported NiO(x)/ZrO(2) catalysts have been prepared. The bulk NiO(x) was synthesized using the precipitation-oxidation method with reverse order of precipitation while deposition-precipitation technique was used for the preparation of zirconia supported catalyst. The as-prepared samples were characterized by means of XRD, HRTEM, SAED, IR-spectroscopy, and chemical analyses. It was found that under the applied synthesis procedure nanosized and highly dispersed oxide materials with high active oxygen content were obtained. The catalytic activity and selectivity of these oxide catalysts have been studied in reaction of low-temperature oxidation of phenol in aqueous phase. The effects of several parameters such as catalyst amount, temperature and solution pH on the degradation efficiency of the process were also investigated. Experimental results demonstrated that phenol could be completely degraded under all reaction conditions, except at pH = 12.