Nowadays,the advantages of traditional Chinese medicine(TCM) for treatment of tumors are increasingly prominent.Triptolide shows wide-spectrum and highly effective anti-tumor activity. Moreover,nano-carrier-based triptolide drug delivery system is more powerful in improving water solubility and pharmacokinetic behavior of the drug,but it is easy to cause toxic and side effects that should not be neglected on human body. Because of tumor vascular heterogeneity and PEGylation dilemma,nanoparticulate drug delivery systems need to overcome multiple physiological and pathological barriers from drug administration to functioning. It is difficult for traditional triptolide nanoparticulate drug delivery systems to achieve active accumulation of nano-drug in tumor tissues and specific drug release in tumor target site solely relying on enhanced permeability and retention effect of solid tumor,limiting their application and clinical transformation in treatment of tumors. Based on the traditional nano-preparation system,the new functionalized nano-drug delivery system further enhances the nano-drug enrichment,penetration and controlled release at the tumor sites,which is of great significance in improving bioavailability,anti-tumor efficacy and reducing the side effects of drugs. In this paper,we summarized and analyzed the researches on new triptolide functionalized nano-drug delivery system from four perspectives,including tumor active targeting,tumor microenvironment response,polymer-drug conjugates,and multidrug co-delivery for tumor treatment,expecting to provide ideas for in-depth research and clinical application of triptolide and some other active anti-tumor TCM ingredients.
Diterpenes/chemistry* ; Drug Delivery Systems ; Epoxy Compounds/chemistry* ; Humans ; Nanoparticles ; Phenanthrenes/chemistry*

Our previous work has indicated that enzymatic resolution of glycidyl butyrate are strongly affected by many factors, including concentration of substrate, amount of lipase, the temperature, pH, shaking speed and reaction time. In this study, Plackett-Burman design was undertaken to evaluate the effects of the six factors. By regression analysis, concentration of substrate, amount of lipase and the temperature were found to be important for enzymatic resolution of glycidyl butyrate. In the second phase of the optimization process, a response surfacemethodology (RSM) was used to optimize the above critical factors, and to find out the optimal concentration levels and the relationships between these factors. By solving the quadratic regression model equation using appropriate statistic methods, the optimal parameter of the variables were determined as: 0.499 mol/L glycidyl butyrate, 30.23 mg/g lipase and 29.68 degrees C. In the optimum condition, the value of enantiomeric excess(ee%) was 93.28%. Compared to 84.65% which was the maximum ee% under the non-optimized condition, this study has a significant advancement. The experimental data under various conditions have validated the theoretical values.
Butyrates ; chemistry ; Catalysis ; Enzyme Activation ; Epoxy Compounds ; chemistry ; Lipase ; metabolism ; Molecular Conformation ; Propanols ; chemistry ; Regression Analysis ; Stereoisomerism ; Substrate Specificity ; Temperature

Using Sepharose CL-6B as support, 3-Chloro-1, 2-epoxypropane as activated agent, carboxymethylated aspartate (CM-Asp) as chelating ligand, A chelate affinity chromatographic medium based on Co2+, named Co-CM-Asp-Sepharose, was prepared and used to purify 6 x His-tagged fusion proteins. The amount of Co-CM-Asp-Sepharose reacted with 200 microL of lysate, the incubation time, wash condition and the imidazole concentration in the elution buffer were optimized. The purification results using Co-CM-Asp-Sepharose and Ni-NTA-Agarose (product of Qiagen) were compared. The CD155D1 fusion protein was also purified from 5mL of lysate and the amount of protein was determined by Bradford method. The results show that 60 microL of Co-CM-Asp-Sepharose (50% suspension) was suitable for the protein purification from 200 microL of lysate, the optimal incubation time of medium and lysate was 30 min, the optimal imidazole concentration in the eluting buffer was 200 mmol/L, and 200 microg of fusion protein was obtained. In a big scale experiment, 4.6 mg of fusion protein was obtained from 5 mL of lysate using 1.5 mL of Co-CM-Asp-Sepharose (50% suspension). Compared with Ni-NTA-Agarose, the Co-CM-Asp-Sepharose medium exhibits higher selectivity and the protein possesses higher purity.
Aspartic Acid ; chemistry ; Chelating Agents ; chemistry ; Chromatography, Affinity ; methods ; Epoxy Compounds ; chemistry ; Histidine ; biosynthesis ; chemistry ; genetics ; Polymers ; chemistry ; Recombinant Fusion Proteins ; isolation & purification ; Sepharose ; chemistry

In this work, the surface activity of block copolymer nonionic surfactants (RPE) has been determined, i.e., critical micelle concentration (CMC), surface excess concentration (gamma), surface area demand per molecule (A), surface tension at CMC (gamma(CMC)). A linear decrease of ln[CMC] vs number of oxypropylene units in copolymer molecule was observed. The change in the work of cohesion per oxypropylene group when passing from molecular into micellar state, calculated from the Shinoda equation, was 0.43 kT for the studied compounds.
Colloids ; chemistry ; Epoxy Compounds ; chemistry ; Ethylene Oxide ; chemistry ; Materials Testing ; Micelles ; Molecular Structure ; Polymers ; chemistry ; Structure-Activity Relationship ; Surface Tension ; Surface-Active Agents ; chemistry

OBJECTIVETo develop a HPLC method for determination of triptolide in tripterygium total terpenoids tablets.

METHODA Lichrospher CN column was used with ethanol and water for gradient elution. The detection wavelength was set at 255 nm.

RESULTThe linear relationship of the concentrations and peak areas was good in range of 0.742-59.4 microg x mL(-1) (r = 0.9998). The average recovery was 99.2%, RSD% = 1.7%.

CONCLUSIONThe method is simple, rapid and accurate and can be used for quality control of the tablets.

Chromatography, High Pressure Liquid ; methods ; Diterpenes ; analysis ; Epoxy Compounds ; Phenanthrenes ; analysis ; Plants, Medicinal ; chemistry ; Quality Control ; Tablets ; Terpenes ; administration & dosage ; chemistry ; isolation & purification ; Tripterygium ; chemistry

Novel solid lipid nanoparticle (SLN) system is prepared with Compritol ATO 888 and tricaprylic glyceride. DSC, XRD, SAXS and NMR are employed to study the novel carrier property and microstructure. When the peak melting point decreased from 70.8 degrees C to 61.4 degrees C, the enthalpy sharply decreased. It could be concluded that the regular crystal lattices in the novel carriers are broken out for the oil joined in them. Melting behavior is occurred at -17.7 degrees C while novel SLN is composed of oil and solid lipid mixture from the DSC measurement. Most alpha phase and least beta' phase are in the nano carrier system whether drug loading or not from the XRD investigation. There is only 0.1 nm change of long space among the novel SLN made of mixture and the lipid matrix and traditional SLN; therefore, it is impossible of the oil molecular insert into the solid glyceride structure. Since the different melting behavior (DSC measurements) and molecular move state (NMR investigations), two lipid matrix are still in two state of liquid and solid lipid in the novel SLN carrier. Presume the microstructure of the novel SLN prepared by our experiment would be that liquid oil has formed superfine nano accommodation encapsulated with solid lipid, but the whole particle is still in nano size range.
Calorimetry, Differential Scanning ; Caprylates ; chemistry ; Diterpenes ; administration & dosage ; chemistry ; Drug Carriers ; chemistry ; Drug Delivery Systems ; Epoxy Compounds ; administration & dosage ; chemistry ; Fatty Acids ; chemistry ; Magnetic Resonance Spectroscopy ; Nanoparticles ; Particle Size ; Phenanthrenes ; administration & dosage ; chemistry ; Triglycerides ; chemistry ; X-Ray Diffraction

OBJECTIVETo establish a method of determinating the plasma concentration about the triptolide in rat in vivo. And to study the pharmacokinetics of triptolide in transdermal drug delivery system of Triptergium wilfordii microemulsion gel.

METHODThe T. wilfordii tablet was regarded as the control, the plasma concentration of triptolide was determined by LC-MS/MS after different route of administration, and the pharmacokinetic parameters were calculated by DAS.

RESULTThe linear relation of triptolide was excellent within the range of 1-200 ng (r = 0.9967). The minimum detectable concentration were 0.5 microg x L(-1). It was the first-order process. And the pharmacokinetic parameters of triptolide in microemulsion gel was as follow: t(1/2) (2.4 +/- 3.00) h,tmax (6.7 +/- 1.63) h, Cmax (82.9 +/- 17.63) microg x L(-1). To compare the tablets, the microemulsion gel has a longer peak time, and maintain a longer stable plasma concentration. The AUC of tablets and microemulsion gel were (2595.3 +/- 551.15) h x microg x L(-1) and (209.9 +/- 25.34) h x microg x L(-1) and it was a significant differences between the tablet and microemulsion gel (P < 0. 01).

CONCLUSIONT. wilfordii has rapid absorption in rat in vivo and a stable and persistent plasma concentration after transdermal drug delivery. Therefore, it is rationality after transdermal drug delivery.

Animals ; Biological Availability ; Diterpenes ; pharmacokinetics ; Emulsions ; pharmacokinetics ; Epoxy Compounds ; pharmacokinetics ; Female ; Male ; Phenanthrenes ; pharmacokinetics ; Plant Extracts ; pharmacokinetics ; Rats ; Rats, Sprague-Dawley ; Tripterygium ; chemistry

Tumors are major chronic diseases and seriously threaten human health all over the world. How to effectively control and cure tumors is one of the most pivotal problems in the medical field. At present,surgery,radiotherapy and chemotherapy are still the main treatment methods. However,the side effects of radiotherapy and chemotherapy cannot be underestimated. Therefore,it is of great practical significance to find new anti-cancer drugs with low toxicity,high efficiency and targeting to cancer cells. With the increasing incidence of tumor,the anti-tumor effect of traditional Chinese medicine has increasingly become a research hotspot. Triptolide,which is a natural diterpenoid active ingredient derived from of Tripterygium wilfordii,as one of the highly active components,has anti-inflammatory,immunosuppressive,anti-tumor and other multiple effects. A large number of studies have confirmed that it has good anti-tumor activity against various tumors in vivo and in vitro. It can play an anti-tumor role by inhibiting the proliferation of cancer cells,inducing apoptosis of cancer cells,inducing autophagy of cancer cells,blocking the cell cycle,inhibiting the migration,invasion and metastasis of cancer cells,reversing multidrug resistance,mediating tumor immunity and inhibiting angiogenesis. On the basis of literatures,this paper reviews the anti-tumor effect and mechanism of triptolide,and analyzes the current situation of triptolide combined with other chemotherapy drugs,in order to promote deep research and better clinical application about triptolide.
Antineoplastic Agents, Phytogenic ; pharmacology ; Apoptosis ; Autophagy ; Cell Cycle Checkpoints ; Diterpenes ; pharmacology ; Epoxy Compounds ; pharmacology ; Humans ; Neoplasms ; drug therapy ; Phenanthrenes ; pharmacology ; Tripterygium ; chemistry

OBJECTIVETo study the content variation of triptolide in medicinal material of Tripterygium and provide theoretical basis for the hereditary improvement, the gathering and process, the quality evaluation and the provenance division in medicinal material of Tripterygium.

METHODHPLC method was used to determine the content of triptolide.

RESULTThe relations between triptolide and germplasm, growth year, gathering season were found out basically.

CONCLUSIONThe triptolide contents in xylem are affected by hereditary factors remarkably. While the triptolide contents in phloem are not affected obviously. The accumulation of triptolide needs the certain growth years. However when growth is beyond certain years, the triptolide content decreases with the disintegration of secondary metabolism in xylem. The triptolide in xylem is highest in winter and decreasing in growing season. The triptolide in phloem is less affected by the season.

Chromatography, High Pressure Liquid ; Diterpenes ; analysis ; metabolism ; Ecosystem ; Epoxy Compounds ; analysis ; metabolism ; Phenanthrenes ; analysis ; metabolism ; Plant Roots ; anatomy & histology ; chemistry ; Plants, Medicinal ; anatomy & histology ; chemistry ; growth & development ; Seasons ; Species Specificity ; Time Factors ; Tripterygium ; anatomy & histology ; chemistry ; growth & development ; Xylem ; chemistry

The adventitious root of Tripterygium wilfordii was used as experiment material to study effects of various concentration of aspartic acid, isoleucine, cysteine and arginine in MS medium on the growth and triptolide, wilforgine, wilforine contents of the adventitious roots. The results showed that compared with the control, supplemented with 0.25 mmol x L(-1) aspartic acid at 3rd week, the growth of the adventitious roots only accounted for 80%, but the content of triptolide of the adventitious roots and the medium was 1.36, 1.30 times, the content of wilforgine was 1.16, 1.37 times, the content of wilforine was 1.22, 1.63 times, respectively. At 3rd week 0.05 mmol x L(-1) isoleucine, the growth of adventitious roots was 97.3%, wilforgine of adventitious roots and medium 1.02, 1.27 times, wilforine 1.36 times and 1.15 times. At 1st week 0.25 mmol x L(-1) cysteine, the growth of the adventitious roots comprised 77.5% of the control, while content of triptolide of adventitious roots reached 1.87 times. At 2nd week 1.00 mmol x L(-1) cysteine, the growth of adventitious roots was 44.6% of the control, the content of wilforine in medium was 2.97 times. At 3rd week 0.50 mmol x L(-1) arginine, the growth of adventitious roots was 124.2%, the content of wilforgine and wilforine was 1.3, 1.4 times, respectively.
Amino Acids ; analysis ; metabolism ; Diterpenes ; analysis ; Epoxy Compounds ; analysis ; Lactones ; analysis ; metabolism ; Phenanthrenes ; analysis ; Plant Roots ; chemistry ; growth & development ; metabolism ; Pyridines ; analysis ; metabolism ; Secondary Metabolism ; Tripterygium ; chemistry ; growth & development ; metabolism