In contrast to liver cytokines, neither coffee nor its components modulated find more this parameter in this model of NASH, because no difference among treatments was found in HFD-fed rats (HFD + coffee, 291 ± 31.3 ng/mL; HFD + polyphenols, 331 ± 30.7 ng/mL; HFD + melanoidins, 306 ± 33.3 ng/mL; HFD + water, 292 ± 18.0 ng/mL). Clinical studies on coffee have focused almost exclusively on caffeine; however, mounting evidence suggests that other coffee components are responsible for its effects, particularly on the liver. In this study, a
decaffeinated coffee brew was used in parallel with two of its main components—polyphenol and the high molecular weight polysaccharide fraction melanoidin—in a well-known animal model of NASH.4 A prerequisite to explaining epidemiological evidence by way of an intervention study is to use a coffee dosage in the order of magnitude of its dietary intake. We therefore selected a daily dosage of coffee of about 1.5 mL for this study. see more This corresponds to about 6 cups/day of espresso or 2 cups/day of filtered coffee for a 70-kg person. Accordingly,
the doses for polyphenols and melanoidins were fixed at about 4.2 mg/day of polyphenols and 15 mg/day of melanoidins. The first evidence of the study was that the administration of coffee and its components at these physiological dosages has a beneficial effect on the liver functions of HFD-fed rats. Histological evaluations of HFD-fed rat livers showed a picture typical of NASH: presence of intrahepatocyte lipid droplets, widespread inflammatory infiltration, perivenular fibrosis, medchemexpress and the formation of porto-central septa. Necrotic damage was also documented by aminotransferase concentrations that were three-fold
higher than those of control rats. One consequence of NASH is its evolution toward liver fibrosis, which was present in HFD-fed rats, as evidenced by Sirius red–positive staining and increased expression of tTG. The release into the extracellular matrix of tTG activates latent TGF-β, which increases the tTG expression further. The biochemical data showed that, compared with HFD-fed rats drinking water, HFD-fed rats drinking coffee or its components had: (1) reduced fat and collagen deposition as well as reduced serum ALT; (2) reduced expression of TNF-α, tTG, and TGF-β and an increased expression of adipo-R2 and PPAR-α in liver tissue; (3) a two-fold GSH/GSSG ratio in both serum and liver tissue; (4) less systemic lipid peroxidation (−18% malondialdehyde concentration in coffee-treated rats); (5) reduced concentrations of proinflammatory cytokines such as TNF-α and IFN-γ and increase of anti-inflammatory ones (IL-4 and IL-10) in liver tissue. These data provide some indications about the mechanisms through which coffee modulates lipid deposition as well as the antioxidant and inflammatory status of rats fed an HFD.