Safety evaluations of the processed lateral root of Aconitum carmichaelii Debx. And its hepatotoxicity mechanisms in rats.

ETHNOPHARMACOLOGICAL RELEVANCE: The processed lateral root of Aconitum carmichaelii Debx. is known as Fuzi, an extensively used Traditional Chinese Medicine to treat cardiovascular diseases, rheumatism arthritis, bronchitis, pains, and hypothyroidism, etc. Although Chinese Pharmacopeia regulates the safe clinical dosage of Fuzi at 3-15 g/person/day, such recommendation not only lacks bench evidence but also does not differentiate Fuzi with different processing types, such as Heishunpian and Paofupian. AIM OF THE STUDY: The current study aimed to 1) determine No-Observed-Adverse-Effect-Levels of Heishunpian and Paofupian in rats and 2) investigate the related toxicity mechanisms for their safe clinical use. MATERIALS AND METHODS: After giving clinically relevant dosing regimen of Heishunpian/Paofupian to rats, we conducted toxicity assessments including ECG monitoring, histopathological changes and serum biomarkers to detect organ injury. Metabolomic study in the liver revealed changes in endogenous metabolite levels after two-week treatment of Fuzi preparations or its corresponding six toxic alkaloids mixtures. RESULTS: The NOAEL for both bolus and two-week treatments of Heishunpian and Paofupian in rats was designated to be 7.5 g/kg and 15 g/kg, respectively. Corresponding recommended doses in humans were 7.5-25 g/person/day for Heishunpian and 15-50 g/person/day for Paofupian. Metabolic profiles revealed more significant alterations in endogenous substances from rats receiving the two Fuzi preparations than their corresponding toxic alkaloids mixtures. Upregulation of bile acid pathway could be responsible for Fuzi induced liver injury. CONCLUSIONS: Compared to the current maximum recommended dose, our suggested upper limit of guided dose for Heishunpian was comparable, whereas that for Paofupian could be further elevated. Both C19-diterpenoid alkaloids and co-occurring components in Fuzi preparations contributed to their hepatotoxicity via upregulation of bile acid pathway.

Metabonomic approaches investigate diosbulbin B-induced pulmonary toxicity and elucidate its underling mechanism in male mice.

Air Potato Yam is widely used in the treatment of many conditions such as cancer, inflammation, and goiter. Diosbulbin B (DIOB) is the primary active component of Air Potato Yam, and it exhibits anti-tumor and anti-inflammatory properties. The main purpose of this study was to determine the mechanism by which DIOB induces lung toxicity, using metabonomics and molecular biology techniques. The results showed that the lung toxicity induced by DIOB may occur because of a DIOB-induced increase in the plasma levels of long-chain free fatty acids and endogenous metabolites related to inflammation. In addition, treatment with DIOB increases the expression of the cyp3a13 enzyme, which leads to enhanced toxicity in a dose-dependent manner. The molecular mechanism underlying toxicity in mouse lung cells is the DIOB-mediated inhibition of fatty acid ß-oxidation, partial glycolysis, and the TCA cycle, but DIOB treatment can also compensate for the low Adenosine triphosphate (ATP) supply levels by improving the efficiency of the last step of the glycolysis reaction and by increasing the rate of anaerobic glycolysis. Using metabonomics and other methods, we identified the toxic effects of DIOB on the lung and clarified the underlying molecular mechanism.

Systems Toxicology Approaches Reveal the Mechanisms of Hepatotoxicity Induced by Diosbulbin B in Male Mice.

Diosbulbin B (DIOB) is an effective component of air potato yam with antitumor and anti-inflammatory activities, and it is the main toxic component leading to hepatotoxicity. However, the mechanism of its hepatotoxicity remains unclear. In this study, we aimed to systematically elucidate the molecular action of DIOB on liver metabolic function through systems toxicology approaches. C57BL/6 mice were orally treated with DIOB (10, 30, 60 mg/kg) for 28 days, and the liver metabonomics and histopathology, molecular docking, mRNA expression levels, and activities of enzymes were analyzed. The results illustrated that DIOB could affect fatty acid and glucose metabolism, block the TCA cycle, and DIOB also could disorder bile acid synthesis and transport and promote the occurrence of hyperbilirubinemia. In addition, DIOB increased Cyp3a11 expression in a dose-dependent manner. Thus, these results provide new insights into the mechanism of hepatotoxicity caused by DIOB.

Metabonomics reveals bisphenol A affects fatty acid and glucose metabolism through activation of LXR in the liver of male mice.

Bisphenol-A (BPA) is a representative environmental endocrine disrupting chemical that is widely used in the production of polycarbonate plastics and epoxy resins. Many studies have confirmed BPA to be closely associated with metabolic diseases, reproductive system diseases, and sex hormone-dependent cancers. In this study, we aimed to systematically elucidate the molecular action of BPA on liver fatty acid and glucose metabolism and the reasons for BPA-induced hypoglycemia through a metabonomics approach. C57BL/6 mice were orally treated with BPA (1, 10, 50, 250 µg/kg) for 35 days and the liver metabonomics and histopathology, molecular docking, mRNA expression levels and activities of enzymes were analyzed. Based on the high-resolution mass spectrometry (MS) for metabonomics and on various software and bioinformatic analysis methods, we found that BPA could affect fatty acid and glucose metabolism, block the TCA cycle, and BPA also regulated the nuclear receptor LXR caused hypoglycemia, thereby affecting the normal metabolic functions of the liver.

Untargeted LC-MS-based metabonomics revealed that aristolochic acid I induces testicular toxicity by inhibiting amino acids metabolism, glucose metabolism, ß-oxidation of fatty acids and the TCA cycle in male mice.

As the main toxic component of aristolochic acid, aristolochic acid I (AAI) is primarily found in Aristolochiaceae plants such as Aristolochia, Aristolochia fangchi and Caulis aristolochiae manshuriensis. AAI has been proven to be carcinogenic, mutagenic and nephrotoxic. Although the role of AAI in testicular toxicity has been reported, its mechanism of action is unknown. Using metabonomics and molecular biology techniques, we tried to identify the differential endogenous metabolites of AAI that may affect the changes in testicular function in mice, map the network of metabolic pathways, and systematically reveal the molecular mechanism of AAI-induced testicular toxicity. We found that AAI inhibited amino acid metabolism in mouse testicular cells, impeded the uptake and oxidative decomposition of fatty acids, prevented normal glucose uptake by testicular cells, which inhibited glycolysis and gluconeogenesis, affected the mitochondrial tricarboxylic acid (TCA) cycle, which impaired the ATP energy supply, decreased the number of spermatogenic cells and sperm in the testes, induced changes in the mitochondrial state of spermatogonial cells, and ultimately led to physiological and pathological changes in the testes. AAI also regulated the testicular physiological activity by regulating the androgen receptor and hormone levels. This study used metabonomics and other methods to elucidate the mechanism of AAI-induced testicular toxicity from a new angle.

Quadrupole Orbitrap Mass Spectrometer-Based Metabonomic Elucidation of Influences of Short-Term Di(2-ethylhexyl) phthalate Exposure on Cardiac Metabolism in Male Mice.

Di(2-ethylhexyl) phthalate (DEHP) can cause severe environmental pollution. Effects of DEHP on cardiac metabolism have been reported, but its mechanism(s) of action is not fully clear. Here, we used high-resolution mass spectrometry for metabonomics and molecular biological methods to identify the different endogenous metabolites affected by DEHP that might cause changes in cardiac metabolism in mice, map the network of metabolic pathways, and reveal (at the molecular level) how DEHP affects cardiac metabolism. The results showed that DEHP could inhibit the ß-oxidation of fatty acids and gluconeogenesis, promote glycolysis, and inhibit the tricarboxylic acid cycle in cardiomyocytes. DEHP caused mitochondrial dysfunction by inhibiting the synthesis and transport of fatty acids and, thus, inhibiting the synthesis and breakdown of adenosine triphosphate in mitochondria. Pathology revealed that DEHP could change the normal structures and functions of the heart and bodies of mice. DEHP can interfere with the physiological and metabolic function of the heart in mice by disrupting the endogenous metabolite and gene levels.

Metabonomics reveals that triclocarban affects liver metabolism by affecting glucose metabolism, ß-oxidation of fatty acids, and the TCA cycle in male mice.

This study combined metabonomics with molecular biology techniques to identify differential endogenous substances produced by triclocarban (TCC) that affect plasma and liver metabolism in mice, to map their associated metabolic pathways, and to systematically determine the mechanism of TCC affecting liver metabolism in mice. The results showed that TCC affected liver metabolism by a mechanism involving the inhibition of glucose oxidation in the liver, promotion of anaerobic glycolysis and gluconeogenesis, and accelerated ß-oxidation of liver fatty acids and the TCA cycle, which lead to metabolic disorders of the liver microenvironment in mice. The analysis of endogenous substances in the liver and plasma indicated that TCC caused physiological and pathological changes in the liver, and affected the physiological state of mice and the metabolic balance of endogenous substances. Based on metabonomics and bioinformatics analysis methods, this study elucidated a new mechanism involved in how TCC affects liver metabolism.

Metabonomics Indicates Inhibition of Fatty Acid Synthesis, ß-Oxidation, and Tricarboxylic Acid Cycle in Triclocarban-Induced Cardiac Metabolic Alterations in Male Mice.

Triclocarban (TCC) has been identified as a new environmental pollutant that is potentially hazardous to human health; however, the effects of short-term TCC exposure on cardiac function are not known. The aim of this study was to use metabonomics and molecular biology techniques to systematically elucidate the molecular mechanisms of TCC-induced effects on cardiac function in mice. Our results show that TCC inhibited the uptake, synthesis, and oxidation of fatty acids, suppressed the tricarboxylic acid (TCA) cycle, and increased aerobic glycolysis levels in heart tissue after short-term TCC exposure. TCC also inhibited the nuclear peroxisome proliferator-activated receptor α (PPARα), confirming its inhibitory effects on fatty acid uptake and oxidation. Histopathology and other analyses further confirm that TCC altered mouse cardiac physiology and pathology, ultimately affecting normal cardiac metabolic function. We elucidate the molecular mechanisms of TCC-induced harmful effects on mouse cardiac metabolism and function from a new perspective, using metabonomics and bioinformatics analysis data.

Di(2-ethylhexyl)phthalate Alters the Synthesis and ß-Oxidation of Fatty Acids and Hinders ATP Supply in Mouse Testes via UPLC-Q-Exactive Orbitrap MS-Based Metabonomics Study.

Di(2-ethylhexyl) phthalate (DEHP) is considered to be an environmental endocrine disruptor at high levels of general exposure. Studies show that DEHP may cause testicular toxicity on human being. In this study, metabonomics techniques were used to identify differential endogenous metabolites, draw the network metabolic pathways, and conduct network analysis, to determine the underlying mechanisms of testicular toxicity induced by DEHP. The results showed that DEHP inhibited synthesis and accelerated ß-oxidation of fatty acids and impaired the tricarboxylic acid cycle (TCA cycle) and gluconeogenesis, resulting in lactic acid accumulation and an insufficient ATP supply in the microenvironment of the testis. These alterations led to testicular atrophy and, thus, may be the underlying causes of testicular toxicity. DEHP also inhibited peroxisome proliferator activated receptors in the testis, which may be another potential reason for the testicular atrophy. These findings provided new insights to better understand the mechanisms of testicular toxicity induced by DEHP exposure.

Tributyl phosphate impairs the urea cycle and alters liver pathology and metabolism in mice after short-term exposure based on a metabonomics study.

As a newly emerging environmental contaminant, tributyl phosphate (TBP) is of increasing concern because of the environmental problems it can cause. Studies have suggested that TBP induces hepatocellular adenomas and has malignant potential for hepatocellular carcinoma. However, the mechanisms of its adverse effects are unclear. In this study, metabonomic techniques were used to identify differential endogenous metabolites, draw network metabolic pathways and conduct network analysis to elucidate the underlying mechanisms involved in TBP induced pathological changes of the liver. The metabonomics study showed that TBP altered endogenous metabolites in the plasma and liver. The number of categories of endogenous metabolites with a VIP >1 were 14 in plasma and 20 in liver. The results also showed that TBP impaired urea synthesis in the liver. In addition, results of both in vitro and in vivo experiments indicated that TBP activated nuclear receptor CAR and inhibited CYP3a11 and CYP2b10 activities in the liver of mice after short-term exposure. These effects may be the underlying causes leading to TBP induced hepatocellular adenomas. This study combined metabonomics and other technical methods to clarify the mechanism of TBP-induced liver tumorigenesis from a new perspective.

Inhibition of P-Glycoprotein and Multidrug Resistance-Associated Protein 2 Regulates the Hepatobiliary Excretion and Plasma Exposure of Thienorphine and Its Glucuronide Conjugate.

Thienorphine (TNP) is a novel partial opioid agonist that has completed phase II clinical evaluation as a promising drug candidate for the treatment of opioid dependence. Previous studies have shown that TNP and its glucuronide conjugate (TNP-G) undergo significant bile excretion. The purpose of this study was to investigate the roles of efflux transporters in regulating biliary excretion and plasma exposure of TNP and TNP-G. An ATPase assay suggested that TNP and TNP-G were substrates of P-gp and MRP2, respectively. The in vitro data from rat hepatocytes showed that bile excretion of TNP and TNP-G was regulated by the P-gp and MRP2 modulators. The accumulation of TNP and TNP-G in HepG2 cells significantly increased by the treatment of mdr1a or MRP2 siRNA for P-gp or MRP2 modulation. In intact rats, the bile excretion, and pharmacokinetic profiles of TNP and TNP-G were remarkably changed with tariquidar and probenecid pretreatment, respectively. Tariquidar increased the Cmax and AUC0-t and decreased MRT and T1/2 of TNP, whereas probenecid decreased the plasma exposure of TNP-G and increased its T1/2. Knockdown P-gp and MRP2 function using siRNA significantly increased the plasma exposure of TNP and TNP-G and reduced their mean retention time in mice. These results indicated the important roles of P-gp and MRP2 in hepatobiliary excretion and plasma exposure of TNP and TNP-G. Inhibition of the efflux transporters may affect the pharmacokinetics of TNP and result in a drug-drug interaction between TNP and the concomitant transporter inhibitor or inducer in clinic.

Characterization of human metabolism and disposition of levo-tetrahydropalmatine: Qualitative and quantitative determination of oxidative and conjugated metabolites.

Levo-tetrahydropalmatine (l-THP) is a tetrahydroprotoberberine isoquinoline alkaloid and has been used as an analgesic agent in China for over 50 years. Recent studies revealed that l-THP was effective in the treatment of drug addiction. However, the plasma metabolic profile, mass balance and clearance pathways of l-THP in human remain unknown. In the present study, an analytical strategy was developed for qualitative and quantitative investigation of metabolism and disposition of l-THP in human. Detection and structural characterization of l-THP metabolites were performed using liquid chromatography-quadrupole time-of-flight mass spectrometry. Selected major metabolites in plasma, urine and feces determined by liquid chromatography with UV detection were further quantified using a triple quadruple mass spectrometry and reference standards. A total of 20 metabolites were identified, most of which were formed via demethylation, mono-hydroxylation, and glucuronidation and sulfonation of desmethyl metabolites. Five major metabolites accounted for over 10% of the parent drug concentration in plasma. Major urinary and fecal metabolites and the parent drug that were monitored for 72h accounted for 46.3% of the dose, while only 0.16% of the dose was the unchanged drug. Multiple demethylations followed by glucuronide and sulfate conjugations and renal excretion were the major drug clearance pathways of l-THP in human.

Single and 14-day repeated dose inhalation toxicity studies of hexabromocyclododecane in rats.

Limited toxicological information is available for hexabromocyclododecane (HBCD),a widely used additive brominated flame retardant. Inhalation is a major route of human exposure to HBCD. The aim of this study was to determine the acute inhalation toxicity and potential subchronic inhalation toxicity of HBCD in Sprague-Dawley rats exposed to HBCD only through inhalation. The acute inhalation toxicity of HBCD was determined using the limit test method on five male and five female Sprague-Dawley rats at a HBCD concentration of 5000 mg/m(3). Repeated-dose toxicity tests were also performed, with 20 males and 20 females randomly assigned to four experimental groups (five rats of each sex in each group). There were three treatment groups (exposed to HBCD concentrations of 125,500, and 2000 mg/m(3)) and a blank control group (exposed to fresh air). In the acute inhalation toxicity study, no significant clinical signs were observed either immediately after exposure or during the recovery period. Gross pathology examination revealed no evidence of organ-specific toxicity in any rat. The inhalation LC50(4 h) for HBCD was higher than 5312 ± 278 mg/m3 for both males and females. In the repeated dose inhalation study, daily head/nose-only exposure to HBCD at 132 ± 8.8, 545.8 ± 35.3, and 2166.0 ± 235.9 mg/m(3) for 14 days caused no adverse effects. No treatment-related clinical signs were observed at any of the test doses. The NOAEL for 14-day repeated dose inhalation toxicity study of HBCD is 2000 mg/m(3).

CYP450 Enzyme-Mediated Metabolism of TCAS and Its Inhibitory and Induced Effects on Metabolized Enzymes in Vitro.

In this study, we investigated the enzymes catalyzing the phase I metabolism of thiacalixarene (TCAS) based on in vitro system including cDNA-expressed P450 enzymes, human liver microsomes plus inhibitors and monoclonal antibodies. In addition, the inhibitory potential of TCAS on major CYP450 drug metabolizing enzymes (CYP1A2, CYP2C9, CYP2B6, CYP2D6 and CYP3A4) was assessed. The results showed that CYP1A2 and CYP2C9 mediated TCAS hydroxylation. IC50 values for TCAS in rat and human liver microsomes were greater than 50 µM, and it demonstrated a weak inhibition of rat and human CYP450 enzymes. Finally, sandwiched hepatocytes were used to evaluate the induction of CYP1A and CYP3A to define the function of TCAS in vivo. The results showed that incubation of TCAS at different concentrations for 72 h failed to induce CYP1A and CYP3A. However, incubation of the cells with 50 and 100 µM TCAS caused a profound decrease in the activities of CYP1A and CYP3A, which was probably due to cytotoxic effects, suggesting that exposure to TCAS might be a health concern.

Role of CYP3A in regulating hepatic clearance and hepatotoxicity of triptolide in rat liver microsomes and sandwich-cultured hepatocytes.

Triptolide (TP) is an active component of Tripterygium wilfordii Hook. F and widely used to treat autoimmune and inflammatory diseases. It has been demonstrated that cytochrome P450 (CYP) are involved in the metabolism of TP. However, the underlying mechanisms of TP-induced toxicity mediated by hepatic CYP have not been well delineated. In this study, rat liver microsomes (RLM) and sandwich-cultured rat hepatocytes (SCRH) were used to identify the mechanism involving the CYP3A inhibition by TP and to evaluate TP-induced liver damage after CYP3A modulation by the known inhibitor, ketoconazole, and the known inducer, dexamethasone. The results showed that TP itself had a time- and concentration-dependent inhibitory effect on CYP3A. When the CYP3A inhibitor and inducer were added, the enzyme activity and hepatotoxicity changed significantly. The enzyme inducer increased CYP3A activity and decreased the metabolic half life (t1/2) of TP when compared to the control group, while the enzyme inhibitor had an opposite effect. Our findings reveal that TP is a weak CYP3A inhibitor involving the time-dependent inhibition mechanism. The induction or inhibition of CYP3A played an important role in TP-induced hepatotoxicity. Clinicians should be aware of the metabolic characteristics of TP to maximize therapeutic efficacy and reduce TP-induced toxicity.

[Investigation of metabolic kinetics and reaction phenotyping of ligustrazin by using liver microsomes and recombinant human enzymes].

The metabolic characteristics of ligustrazin (TMPz) in liver microsomes were investigated in the present study. The reaction phenotyping of TMPz metabolism was also identified by in vitro assessment using recombinant human cytochrome P450 enzymes (CYP) and UDP glucuronosyltransferases (UGT). TMPz was incubated at 37 degrees C with human (HLM) and rat liver microsomes (RLM) in the presence of different co-factors. The metabolic stability and enzyme kinetics of TMPz were studied by determining its remaining concentrations with a LC-MS/MS method. TMPz was only metabolically eliminated in the microsomes with NADPH or NADPH+UDPGA. In the HLM and RLM with NADPH+UDPGA, t1/2, K(m) and V(max) of TMPz were 94.24 +/- 4.53 and 105.07 +/- 9.44 min, 22.74 +/- 1.89 and 33.09 +/- 2.74 micromol x L(-1), 253.50 +/- 10.06 and 190.40 +/- 8.35 nmol x min(-1) x mg(-1) (protein), respectively. TMPz showed a slightly higher metabolic rate in HLM than that in RLM. Its primary oxidative metabolites, 2-hydroxymethyl-3, 5, 6-trimethylpyrazine (HTMP), could undergo glucuronide conjugation. The CYP reaction phenotyping of TMPz metabolism was identified using a panel of recombinant CYP isoforms (rCYP) and specific CYP inhibitors in HLM. CYP1A2, 2C9 and 3A4 were found to be the major CYP isoforms involved in TMPz metabolism. Their individual contributions were assessed b) using the method of the total normalized rate to be 19.32%, 27.79% and 52.90%, respectively. It was observed that these CYP isoforms mediated the formation of HTMP in rCYP incubation. The UGT reaction phenotyping of HTMP glucuronidation was also investigated preliminarily by using a panel of 6 UGT isoforms (rUGT). UGT1A1, 1A4 and 1A6 were the predominant isoforms mediated the HTMP glucuronidation. The results above indicate that the metabolism of TMPz involves multiple enzymes mediated phase I and phase II reactions.

Simultaneous quantification of L-tetrahydropalmatine and its urine metabolites by ultra high performance liquid chromatography with tandem mass spectrometry.

l-tetrahydropalmatine (l-THP) is a tetrahydroprotoberberine isoquinoline alkaloid that has been used as an analgesic agent in China for more than 40 years. Recent studies indicated its potential application in the treatment of drug addiction. In this study, a sensitive and rapid method using ultra high performance liquid chromatography with MS/MS was developed and validated for simultaneous quantitation of l-THP and its desmethyl metabolites. Enzymatic hydrolysis was integrated into sample preparation to enable the quantitative determination of both free and conjugated metabolites. Chromatographic separation was achieved on an Agilent Poroshell 120 EC-C18 column. Detection was performed by MS in the positive ion ESI mode. The calibration curves of the analytes were linear (r(2) > 0.9936) over the concentration range of 1-1000 ng/mL with the lower limit of quantification at 1 ng/mL. The precision for both intra- and interday determinations was <8.97%, and the accuracy ranged from -8.74 to 8.65%. The recovery for all the analytes was >70% without significant matrix effect. The method has been successfully applied to the urinary excretion study of l-THP in rats. The conjugates were found to be the major urine metabolites of the drug.

Self-other differences in H1N1 flu risk perception in a global context: a comparative study between the United States and China.

Extending research on self-other differences in perception to a global health risk, this study compares U.S. and Chinese college students' perceived H1N1 flu risk at four levels: personal, group, societal, and global. It also examines how personal experience, interpersonal communication, traditional and Internet-based media, and self-efficacy affect perception at four levels, as well as the self-other differences between the personal level and each of the other three levels. An online survey in both countries reveals an "ascending pattern," showing higher perceived risk for others than for selves. Chinese respondents perceive higher risk than U.S. respondents at all levels. Interpersonal communication predicts risk perception at four levels in the United States and at the group and societal levels in China. New media exposure exerts influence on all but the group level in China, while social networking sites (SNS) exposure predicts group- and societal-level risk perception in the United States. The overall attention paid to H1N1 information in the media affects all levels in both countries. Interaction between media exposure and attention is influential at all levels in the United States. Self-efficacy is negatively associated with risk perception in China except at the global level. Attention to media in the United States, and SNS exposure in China, explain the self-other differences in three comparisons, along with self-efficacy, which decreases the self-other gap in the United States while increasing the gap in China.

Assessment of the roles of P-glycoprotein and cytochrome P450 in triptolide-induced liver toxicity in sandwich-cultured rat hepatocyte model.

Triptolide (TP), a main bioactive component of Tripterygium wilfordii Hook F., is a promising agent for treatment of autoimmune diseases. However, a high incidence of dose-limiting hepatotoxicity was observed in the clinic. Sandwich-cultured rat hepatocyte model was used in this study to identify the involvement of P-glycoprotein (P-gp) in TP disposition and to evaluate TP-induced hepatotoxicity after modulation of P-gp by the known inhibitors, ritonavir and tariquidar, and known inducers, phenobarbital, quercetin, and H(2)O(2). Our data showed that biliary clearance of TP reduced 73.7% and 84.2% upon treatment of ritonavir (25 µM) and tariquidar (5 µM), respectively. In contrast, increases of 346%, 280%, and 273% in biliary clearance of TP were observed with treatment of phenobarbital (1.0 mM), quercetin (20 µM), and H(2)O(2) (0.5 mM), respectively. The TP-induced hepatotoxicity increased by twofold when CYP activity was blocked by 1-aminobenzotriazole, suggesting that CYP and P-gp may both contribute to the detoxification of TP in the SCRH model. In addition, hepatotoxicity and the expression of apoptosis proteins Bax and Bcl-2 were correlated qualitatively with the TP exposure duration and its intracellular concentration, which, in turn, can be modulated by P-gp inhibitors or inducers. Our results for the first time demonstrated that in addition to CYP-mediated metabolism, P-gp also plays an important role in the disposition of TP and TP-induced hepatotoxicity. Thus, the modulation of canalicular P-gp has a potential to cause drug-drug interaction between TP and the coadministered P-gp inhibitors or inducers in the clinic.

[Effect of shenfu injection on CYP450s of rat liver].

The paper is to report the study of the effect of Shenfu injection on the enzyme activity of liver CYP450 and its mRNA level of rat liver. Microsome of rat liver was prepared after intravenous administration of Shenfu injection for 7 days. The enzyme activity was quantified by Cocktail method. Meanwhile, the mRNA expression of CYP1A2, CYP2B1/2, CYP2C11 and CYP3A1 in the liver was detected by RT-PCR. Shenfu injection obviously induced the enzyme activities of CYP2B and CYP2C. Meantime Shenfu injection decreased the enzyme activities of CYP1A2 and CYP3A. The mRNA levels of CYP2B and CYP2C were also induced in rats treated with Shenfu injection. But it obviously inhibited the mRNA level of CYP1A2 and CYP3A. Since the enzyme activity and mRNA level were obviously changed after administration, the potential effect of drug-drug interaction should be concerned.