Urinary metabolic fingerprinting for amiodarone-induced phospholipidosis in rats using FT-ICR MS.

In the research and development for new therapeutic compounds, there has been a focus on detecting the changes of metabolites induced by drug administration and finding surrogate markers to assess its toxicity. We examined the suitability of urinary metabolic fingerprinting using Fourier transform-ion cyclotron resonance mass spectrometry (FT-ICR MS) for toxicological assessment in the amiodarone (AMD)-induced phospholipidosis (PLD) rat model. There were more than 400 different ion peaks detected in the negative ion mode analysis with FT-ICR MS. About 20% of the detected ions were altered more than 1.5 fold by AMD-treatment. On the scores plot of principal component analysis (PCA), the ion profiles of the treated were separated time-dependently. The loading plot revealed that the metabolites causing PCA results were m/z 178.05101, 191.01979, 192.06676, 212.00239, 258.9944 and 283.0820. The ion at m/z 178.05101 is considered to be hippurate (HA), 192.06676 is phenylacetylglycine (PAG) and 212.00239 is indican (IDN). These results indicate that PAG, IDN and HA are biomarkers for AMD-induced PLD in urinary metabolic fingerprinting using FT-ICR MS. These markers may be useful for evaluation of chemicals, which have the potential to induce PLD.

Maintaining the redox-balance intact: gosha-jinki-gan but not insulin activates retinal soluble guanylate cyclase in diabetic rats.

Strategies to prevent hyperglycemia-induced cytotoxic reactive oxygen species in the retina include the prevention of free radical production, activation of radical-scavenging capacities and inhibition of aldose reductase. This study examined the effect of the standardized Japanese herbal extract product gosha-jinki-gan (GJG) in comparison to insulin treatment in the rat retina. Diabetes was induced in male Wistar rats by single injection of streptozotocin (50 mg/kg i.p.). At 6 and 12 weeks, eye-cups were removed for immunohistochemistry. At 12 weeks, lipid peroxidation (tested with the antiacrolein antibody, Ab5F6) was enhanced significantly in the untreated diabetic group. This effect was absent in both treatment groups, notably in the outer retina. A similar result was obtained for nitrotyrosine overproduction. As an early treatment effect, GJG -- but not insulin -- enhanced soluble guanylate cyclase (sGC) activation (using the function-sensing antibody, MoAb 3221). GJG not only reduces nitroxidative stress and lipid peroxidation in the retina, it also ameliorates glucose metabolism within the cells. We propose that the high glucose turnover in the insulin-treated model disturbs the intracellular redox equilibrium, one result of which might be the impaired sGC activation.