OBJECTIVE: To investigate the protective effect of arctiin with anti-inflammatory bioactivity against triptolide-induced nephrotoxicity in rats and explore the underlying mechanism. METHODS: Forty SD rats were divided into 4 groups for gastric lavage of normal saline, arctiin (500 mg/kg), triptolide (500 μg/kg), or both arctiin (500 mg/kg) and triptolide (500 μg/kg). Blood samples were collected for analysis of biochemical renal parameters, and the renal tissues were harvested for determining the kidney index and for pathological evaluation with HE staining. In the RESULTS: In SD rats, arctiin significantly antagonized triptolide-induced elevation of BUN, Scr and kidney index ( CONCLUSIONS Arctiin can protect the kidney from triptolide-induced damages in rats possibly through the anti-inflammatory pathway.
Animals ; Anti-Inflammatory Agents ; Diterpenes/toxicity* ; Epoxy Compounds/toxicity* ; Furans ; Glucosides ; Kidney/drug effects* ; Phenanthrenes/toxicity* ; Rats ; Rats, Sprague-Dawley

Triptolide (TP) from Tripterygium wilfordii has been demonstrated to possess anti-inflammatory, immunosuppressive, and anticancer activities. TP is specially used for the treatment of awkward rheumatoid arthritis, but its clinical application is confined by intense side effects. It is reported that licorice can obviously reduce the toxicity of TP, but the detailed mechanisms involved have not been comprehensively investigated. The current study aimed to explore metabolomics characteristics of the toxic reaction induced by TP and the intervention effect of licorice water extraction (LWE) against such toxicity. Obtained urine samples from control, TP and TP + LWE treated rats were analyzed by UPLC/ESI-QTOF-MS. The metabolic profiles of the control and the TP group were well differentiated by the principal component analysis and orthogonal partial least squares-discriminant analysis. The toxicity of TP was demonstrated to be evolving along with the exposure time of TP. Eight potential biomarkers related to TP toxicity were successfully identified in urine samples. Furthermore, LWE treatment could attenuate the change in six of the eight identified biomarkers. Functional pathway analysis revealed that the alterations in these metabolites were associated with tryptophan, pantothenic acid, and porphyrin metabolism. Therefore, it was concluded that LWE demonstrated interventional effects on TP toxicity through regulation of tryptophan, pantothenic acid, and porphyrin metabolism pathways, which provided novel insights into the possible mechanisms of TP toxicity as well as the potential therapeutic effects of LWE against such toxicity.
Animals ; Biomarkers ; Chromatography, High Pressure Liquid ; methods ; Diterpenes ; toxicity ; Epoxy Compounds ; toxicity ; Glycyrrhiza ; Male ; Metabolomics ; Phenanthrenes ; toxicity ; Plant Extracts ; therapeutic use ; Principal Component Analysis ; Rats ; Rats, Sprague-Dawley ; Spectrometry, Mass, Electrospray Ionization ; methods

Tripterygium wilfordii multiglycoside( GTW),an extract derived from T. wilfordii,has been used for rheumatoid arthritis and other immune diseases in China. However its potential hepatotoxicity has not been investigated completely. Firstly,the content of triptolid( TP) in GTW was 0. 008% confirmed by a LC method. Then after oral administration of GTW( 100,150 mg·kg-1) and TP( 12 μg·kg-1) in female Wistar rats for 24 h,it was found that 150 mg·kg-1 GTW showed more serious acute liver injury than 12 μg·kg-1 TP,with the significantly increased lever of serum ALT,AST,TBA,TBi L,TG and bile duct hyperplasia even hepatocyte apoptosis. The expression of mRNA and proteins of liver bile acid transporters such as BSEP,MRP2,NTCP and OATP were down-regulated significantly by GTW to inhibit bile acid excretion and absorption,resulting in cholestatic liver injury. Moreover,GTW was considered to be involved in hepatic oxidative stress injury,although it down-regulated SOD1 and GPX-1 mRNA expression without significant difference in MDA and GSH levels. In vitro,we found that TP was the main toxic component in GTW,which could inhibit cell viability up to 80% in Hep G2 and LO2 cells at the dose of 0. 1 μmol·L-1. Next a LC-MS/MS method was used to detect the concentration of triptolid in plasma from rats,interestingly,we found that the content of TP in GTW was always higher than in the same amount of TP,suggesting the other components in GTW may affect the TP metabolism. Finally,we screened the substrate of p-glycoprotein( p-gp) in Caco-2 cells treated with components except TP extrated from GTW,finding that wilforgine,wilforine and wilfordine was the substrate of p-gp. Thus,we speculated that wilforgine,wilforine and wilfordine may competitively inhibit the excretion of TP to bile through p-gp,leading to the enhanced hepatotoxity caused by GTW than the same amount of TP.
Animals ; Caco-2 Cells ; Chemical and Drug Induced Liver Injury ; pathology ; Chromatography, Liquid ; Diterpenes ; toxicity ; Drugs, Chinese Herbal ; toxicity ; Epoxy Compounds ; toxicity ; Female ; Glycosides ; toxicity ; Humans ; Liver ; drug effects ; Phenanthrenes ; toxicity ; Plant Extracts ; toxicity ; Rats ; Rats, Wistar ; Tandem Mass Spectrometry ; Tripterygium ; toxicity

Recent studies indicate that beta-amyloid (Abeta) is the key factor to cause neuronal degeneration in Alzheimer's disease (AD). In the present study, we set up an Abeta induced PC12 cell damage modle and studied the protective effect and related mechanisms of T(10), monomer extracted from Chinese herb Tripterygium wilfordii Hook F. PC12 cells were treated with different concentrations of Abeta (5x10(-4), 5x10(-3), 5x10(-2), 5x10(-1), 5, 50 micromol/L) for 48 h, cell viability was detected by MTT conversion. The apoptotic rate of PC12 cells was quantitatively determined using FACS assay. After PC12 cells were treated with 1x10(-11) mol/L T(10) for 48 h and then co-treated with 50 micromol/LAbetafor 48 h, the apoptotic rate and the change in intracellular Ca(2+) concentration of PC12 cells were analyzed by FACS assay and confocal, respectively. It was found that 5 micromol/L Abeta decreased the cell viability to 66.3% and 50 micromol/L Abeta decreased it to 55.1%, significantly different from that of the control group. After treatment with 50 micromol/L Abeta for 48 h, the apoptotic rate of PC12 cells increased obviously. The apoptotic rate was 5.37% in the control group, while after treatment with 0.5, 5 and 50 micromol/L Abeta for 48 h, the apoptotic rate of PC12 cells went up to 10.19%, 8.02% and 16.63%, respectively. At the same time, the concentration of intracellular Ca(2+) increased greatly after treatment with 50 micromol/L Abeta for 48 h. At the concentration of 1x10(-11) mol/L T(10) remarkably inhibited the apoptosis induced by 50 micromol/L Abeta. In the naive group, the apoptotic rate was 4.83%. The apoptotic rate went up to 17.24% after treatment with 50 micromol/L Abeta for 48 h. After co-treatment with 1x10(-11) mol/L T(10) and 50 micromol/L Abeta, the apoptotic rate decreased to 8.91%, significantly different from that of the control group. At the same time, at the concentration of 1x10(-11 )mol/L T(10) remarkably inhibited the increase of intracellular Ca(2+) concentration induced by Abeta. The results indicate that T(10) has obvious protective effect on PC12 cells, which may be related to the inhibition of the cell apoptosis and increment of intracellular Ca(2+) concentration induced by Abeta.
Alzheimer Disease ; pathology ; Amyloid beta-Peptides ; toxicity ; Animals ; Apoptosis ; drug effects ; Calcium ; metabolism ; Diterpenes ; pharmacology ; Epoxy Compounds ; Neuroprotective Agents ; pharmacology ; PC12 Cells ; Peptide Fragments ; toxicity ; Phenanthrenes ; pharmacology ; Rats ; Tripterygium ; chemistry

To further understand triptolide, this paper has introduced the pharmacology, pharmacokinetics, toxicity, the clinic application and semi-synthesis of triptolide on basis of importance and significant contents of reference which have been consulted in the past twenty years. Presently triptolide and Tripterygium wilfordii have been a hot spot of modernization of Chinese traditional medicine. It is very important to develop a new dosage form of high effect and low toxicity by making use of advanced technology according to its characteristics.
Animals ; Anti-Inflammatory Agents, Non-Steroidal ; pharmacology ; Antineoplastic Agents, Alkylating ; pharmacology ; Antispermatogenic Agents ; pharmacology ; Diterpenes ; chemical synthesis ; isolation & purification ; pharmacology ; toxicity ; Epoxy Compounds ; Humans ; Immunosuppressive Agents ; pharmacology ; Phenanthrenes ; isolation & purification ; pharmacology ; toxicity ; Tripterygium ; chemistry

The arrenotokous toxicity of triptolide was evaluated, and the rate of sperm abnormality, the changes of the lipid peroxide, the enzyme activity and the hormone in male rats were observed. With the negative and positive control group, the healthy rats were respectively given by gavage triptolide suspension at the dose of 0.025, 0.05, 0.1 mg x kg(-1) for 30 days. Then the rats were killed for the measurement of the indicators in testis and serum, as well as the study on the sperm abnormality. The results showed that the positive control group had significant difference, compared with the negative control group. The content of SOD, LDH, G-6-PD, Na+ -K+ -ATPase, Ca+ -Mg+ -ATPase decreased significantly in 0.05 mg x kg(-1) group, and reduced more obviously with exposure to the dose of 0.1 mg x kg(-1). The levels of GSH-Px and beta-G showed a significant decrease in the testis of rats only at the dose of 0.1 mg x kg(-1). Nevertheless, the MDA levels, the FSH levels and the LH levels showed no significant difference. The deformity rate of sperm increased significantly in 0.05 mg x kg(-1) group and 0.1 mg x kg(-1) group. The results indicated the triptolide had the effect of the lipid peroxidation to damage Spermatogenic cells, Sertolis cells and Leydig cells. At the same time, the triptolide interfered not only with the energy supply process of aerobic and anaerobic glycolysis,but also with the energy utilization in testis by affecting the activities of testis marker enzymes, and produced a damage chain of the male reproductive system
Animals ; Diterpenes ; toxicity ; Drugs, Chinese Herbal ; toxicity ; Epoxy Compounds ; toxicity ; Lipid Peroxidation ; drug effects ; Male ; Organ Size ; drug effects ; Phenanthrenes ; toxicity ; Rats ; Rats, Wistar ; Reproduction ; drug effects ; Spermatozoa ; abnormalities ; drug effects ; metabolism ; Testis ; drug effects ; growth & development ; metabolism ; Tripterygium ; chemistry ; toxicity

The present study was designed to explore the influence of water extracts of Atractylodes lancea rhizomes on the toxicity and anti-inflammatory effects of triptolide (TP). A water extract was prepared from A. lancea rhizomes and co-administered with TP in C57BL/6 mice. The toxicity was assayed by determining serum biochemical parameters and visceral indexes and by liver histopathological analysis. The hepatic CYP3A expression levels were detected using Western blotting and RT-PCR methods. The data showed that the water extract of A. lancea rhizomes reduced triptolide-induced toxicity, probably by inducing the hepatic expression of CYP3A. The anti-inflammatory effects of TP were evaluated in mice using a xylene-induced ear edema test. By comparing ear edema inhibition rates, we found that the water extract could also increase the anti-inflammatory effects of TP. In conclusion, our results suggested that the water extract of A. lancea rhizomes, used in combination with TP, has a potential in reducing TP-induced toxicity and enhancing its anti-inflammatory effects.
Animals ; Anti-Inflammatory Agents ; isolation & purification ; pharmacology ; Atractylodes ; chemistry ; Cytochrome P-450 Enzyme System ; genetics ; Diterpenes ; toxicity ; Edema ; chemically induced ; pathology ; Enzyme Induction ; drug effects ; Epoxy Compounds ; toxicity ; Gene Expression Regulation ; drug effects ; Herb-Drug Interactions ; Liver ; drug effects ; pathology ; Male ; Mice ; Mice, Inbred C57BL ; Phenanthrenes ; toxicity ; Plant Extracts ; isolation & purification ; pharmacology ; Plants, Medicinal ; chemistry ; Rhizome ; chemistry ; Water ; chemistry

OBJECTIVETo explore the protective effect of tanshinone II A on lipopolysaccharide (LPS)-induced lung injury in rats, and possible mechanism.

METHODSLPS (O(111): B4) was used to produce a rat model of acute lung injury. Sprague-Dawley rats were randomly divided into 3 groups (8 in each group): the control group, the model group (ALI group), and the tanshinone II A treatment group. Expression of adhesion molecule CD18 on the surface of polymorphonuclear neutrophil (PMNCD18) in venous white blood cells (WBC), and changes in coagulation-anticoagulant indexes were measured 6 h after injection of LPS or normal saline. Changes in malondialdehyde (MDA) content, wet and dry weight (W/D) ratio and morphometry of pulmonary tissue as well as PMN sequestration in the lung were also measured.

RESULTS(1) When compared with the control group, expression of PMNCD18 and MDA content were enhanced in the ALI group with a hypercoagulable state (all P<0.01) and an increased W/D ratio (P<0.05). Histopathological morphometry in the lung tissue showed higher PMN sequestration, wider alveolar septa; and lower alveolar volume density (V(V)) and alveolar surface density (S(V)), showing significant difference (P<0.01). (2) When compared with the ALI group, the expression of PMN-CD18, MDA content, and W/D ratio were all lower in Tanshinone II A treatment group (P<0.05) with ameliorated coagulation abnormality (P<0.01). Histopathological morphometry in the lung tissue showed a decrease in the PMN sequestration and the width of alveolar septa (both P<0.01), and an increase in the V(V) and S(V) (P<0.05, P<0.01).

CONCLUSIONTan II A plays a protective role in LPS-induced lung injury in rats through improving hypercoagulating state, decreasing PMN-CD18 expression and alleviating migration, reducing lipid peroxidation and alleviating pathological changes.

Animals ; Blood Coagulation ; drug effects ; CD18 Antigens ; analysis ; Diterpenes, Abietane ; Drugs, Chinese Herbal ; pharmacology ; Female ; Lipopolysaccharides ; toxicity ; Lung ; drug effects ; pathology ; Male ; Malondialdehyde ; analysis ; Phenanthrenes ; pharmacology ; Rats ; Rats, Sprague-Dawley

Polycyclic aromatic hydrocarbons (PAHs) are ubiquitous environmental contaminants present in air and food. Among PAHs, benzo(a)pyrene(BaP), phenanthrene (PH) and pyrene (PY) are considered to be important for their toxicity or abundance. To investigate the changes of biomarkers after PAH exposure, rats were treated with BaP (150 microgram/kg) alone or with PH (4,300 microgram/kg) and PY (2,700 microgram/kg) (BPP group) by oral gavage once per day for 30 days. 7-ethoxyresorufin-O-deethylase activity in liver microsomal fraction was increased in only BaP groups. The highest concentration (34.5 ng/g) of BaP, was found in muscle of rats treated with BaP alone at 20 days of treatment; it was 23.6 ng/g in BPP treated rats at 30 days of treatment. The highest PH concentration was 47.1 ng/g in muscle and 118.8 ng/g in fat, and for PY it was 29.7 ng/g in muscle and 219.9 ng/g in fat, in BPP groups. In urine, 114-161 ng/ml 3-OH-PH was found, while PH was 41-69 ng/ml during treatment. 201-263 ng/ml 1-OH-PY was found, while PH was 9-17 ng/ml in urine. The level of PY, PH and their metabolites in urine was rapidly decreased after withdrawal of treatment. This study suggest that 1-OH-PY in urine is a sensitive biomarker for PAHs; it was the most highly detected marker among the three PAHs and their metabolites evaluated during the exposure period and for 14 days after withdrawal.
Adipose Tissue/chemistry/drug effects ; Animals ; Benzo(a)pyrene/analysis/metabolism/*toxicity ; Biological Markers/metabolism/urine ; Blood Chemical Analysis ; Body Weight/drug effects ; Cytochrome P-450 CYP1A1/metabolism ; Environmental Pollutants/blood/metabolism/*toxicity/urine ; Female ; Liver/drug effects/enzymology ; Lymphocytes/drug effects/metabolism ; Muscle, Skeletal/drug effects/metabolism ; Organ Size/drug effects ; Phenanthrenes/blood/metabolism/*toxicity/urine ; Pyrenes/analysis/metabolism/*toxicity ; Rats ; Rats, Sprague-Dawley ; Time Factors

AIMInvestigations on reducing the toxicity of triptolide through poly(D, L-lactic acid) nanoparticles as a drug carrier by oral administration to Wistar rats.

METHODSTriptolide-loaded poly (D, L-lactic acid) nanoparticles (TP-PLA-NPs) were prepared by modified spontaneous emulsification solvent diffusion (modified-SESD). The shape of nanoparticles was observed by transmission electron microscope (TEM). The size distribution and mean diameter were measured by laser light scattering technique. The entrapment efficiency and contents of drug loading were determined by RP-HPLC. The physical state of drug loaded in nanopartiles were primarily investigated by X-ray powder diffractometry. TP-PLA-NPs release behavior in vitro was carried out. After oral administration of the nanoparticles to Wistar rats in 15d, the toxicity for liver and kidney were studied by determining aspartate transaminase (AST), alanine transaminase (ALT) and blood urea nitrogen in serum and concentration of protein in urine.

RESULTSThe preparation process adapted to the formulation was as follows: the volume ratio of the aqueous and organic phases was 40/15; the surfactant concentration was 1%; the drug concentration was 0.3%; triptolide-PLA was 1:15 (w/w). The mean diameter was 149.7 nm and the polydispersity index was 0. 088 for the nanoparticles prepared by above conditions. The entrapment efficiency and content of drug loading were 74.27% and 1.36%, respectively. The release behavior of drug in vitro showed an initial burst effect, subsequently a slower rate stage. The results indicated that the liver toxicity (P < 0.01) and kidney toxicity (P < 0.05) caused by triptolide could be decreased significantly by nanoparticles carrier.

CONCLUSIONPLA-NPs might be used as a new oral carrier for triptolide.

Alanine Transaminase ; blood ; Animals ; Aspartate Aminotransferases ; blood ; Blood Urea Nitrogen ; Delayed-Action Preparations ; Diterpenes ; administration & dosage ; isolation & purification ; toxicity ; Drug Carriers ; Drug Delivery Systems ; Epoxy Compounds ; Lactic Acid ; Male ; Nanotechnology ; Particle Size ; Phenanthrenes ; administration & dosage ; isolation & purification ; toxicity ; Polyesters ; Polymers ; Proteinuria ; urine ; Rats ; Rats, Wistar ; Tripterygium ; chemistry