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Objective To investigate the curative effects of various infusion volumes on liver-related metabolic mechanism in the treatment of hemorrhagic shock.Methods A severe hemorrhagic shock rabbit model was established in 30 rabbits.The rabbits were randomly divided into three groups:non-infusion group (A), conventional infusion group (B), and excessive infusion group (C) (n=10 in each group).Taking group B as the control, groups A and C were observed for the damage of non-infusion and excessive infusion, respectively.The outcomes in the three groups and their relations with liver tissue metabolism changes were analyzed with gas chromatograph-mass spectrometer (GC-MS).Results The mortality in groups A, B, and C group were 80%, 0%, and 70%, respectively.The liver tissue metabolic profile in group B showed statistically significant difference compared with that in groups A and B.In group C, the levels of 21 metabolites were lower than those in group B, and the levels of8 metabolites were lower than those in group A.The relative contents of various metabolites were correlated with infusion volumes, and the succinic acid content was associated with death events (P<0.05).Conclusion The conventional infusion has significant curative effect on hemorrhagic shock.The metabolites of liver tissues with excessive infusion are generally decompensated and have longer survival time than those in non-infusion group, which may caused by the excessive infusion-induced blood volume increase after hemorrhagic shock.Tissue fluid dilution is an important cause of death.
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Objective To explore the mechanisms of different cholic acid for reducing damage to human liver cells lines L-O2 induced by amanita toxic peptides (amataxins).Methods According to different concentrations of amataxins,the experiment was conducted with different dosages in 5 groups:0.00 g/L,0.26 g/L,0.40 g/L,1.40 g/L and 2.80 g/L.The human liver cells lines L-O2 in the exponential growth phase were cultured into 96-well plates,1 ×103 cells per well After 24 hours,the concentrations of amanita toxic peptides mentioned above were added.The minimum concentration of mushroom toxins keeping the liver cells alive was determined after 24,48 and 72 hours,respectively,and MTT method was used to test each group's liver cell activity.The experiment included 3 groups:the control group,the damage group,and the cholic acid group.Each group had 3 time points:24,48 and 72 hours after being attacked.Twenty four hours after attack,in cholic acid group,cholic acid drugs including taurocholic acid gca,goose deoxycholic acid,gansu ammonia goose deoxycholic acid and bovine goose deoxycholic acid were given,respectively,to protect the injured liver cells.Cells' morphology changes were observed under the inverted phase contrast microscope,living cells were counted by using MTT method,and aspartate aminotransferase (AST) and alanine aminotransferase (ALT) activities in the culture supernatant were tested by the biochemical method.Results The minimum attack concentration of lamanita toxic peptides keeping liver cell survival in vitro was 1.40 g/L.Seventy-two hours after attack by amanita toxic peptides,the absorbance value was 0.812 ± 0.035,0.345 ± 0.021,0.363 ± 0.018,0.387 ± 0.027,0.431 ± 0.018,0.465 ± 0.015 and 0.452 ± 0.030,respectively in the control group,the damage group,the taurocholic acid group,the goose deoxycholic acid group,the glycocholic acid group,the glycochenodeoxycholic acid group and the sodium deoxycholic acid group.Compared with the damage group,absorbance value 72 hours after attack in each cholic acid group gradually increased,and compared with damage group,the differences were statistically significant among goose deoxycholic acid group,glycocholic acid group,glycochenodeoxycholic acid group and sodium deoxycholic acid group(P < 0.05).AST and ALT activity in each cholic acid group declined,and that in glycochenodeoxycholic acid group was the lowest.Compared with the damage group,the difference was statistically significant (P < 0.01).Conclusions Cholic acid can protect human liver cells from the damage induced by amanita toxic peptides.Such effect may be related to the fact that both amanita toxic peptides and cholic acid are the substrates of NTCP and OATP.
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<p><b>OBJECTIVE</b>Salvia miltorrhiza Bunge (SMB) is a traditional Chinese herb, which is considered to promote blood flow and remove blood stasis. This study examined whether SMB can alleviate injury induced by hypoxia/reoxygenation (H/R) in human kidney proximal tubular cells-2 (HK-2 cells).</p><p><b>METHODS</b>There were 3 experimental groups: control, H/R injury and SMB-treated H/R injury. H/R injury of HK-2 cells was induced by first covering the cells with and then removing liquid paraffin wax. Different concentrations of compound SMB solution (0.05%, 0.10%, 0.15% or 0.20%) were administered to the SMB-treated H/R injury group before the hypoxic injury. After 4, 12 and 24 hrs of hypoxia and 4, 12, 24 and 48 hrs of reoxygenation, morphologic changes of HK-2 cells were observed under an inverted microscope. Cell viability was measured by the MTT method. Lactate dehydrogenase (LDH) activity in the culture supernatants was assayed using biochemical methods; TNF-alpha levels were determined by radioimmunoassay (RIA).</p><p><b>RESULTS</b>The number of HK-2 cells was significantly reduced in the H/R injury group after hypoxia, and reached a nadir 24 hrs after hypoxia treatment. Various concentrations of SMB-treated groups showed significantly greater number of HK-2 cells than the H/R injury group. SMB solution (0.10%) produced the best effect. The levels of LDH and TNF-alpha in the H/R injury group were significantly increased, and reached a peak between 24 hrs of hypoxia and 4 hrs of reoxygenation when compared to the control group. Pre-treating with 0.10% SMB resulted in significantly lower levels of LDH and TNF-alpha than in the untreated H/R injury group at various time points of H/R.</p><p><b>CONCLUSIONS</b>SMB has protective effects against H/R injury of HK-2 cells, possibly through inhibition of inflammatory cytokines.</p>