Preparation，characterization and in vitro anti-inflammatory activity of tetrandrine-loaded chitosan-stearic acid nano micelles modified with folic acid / 中国药房

OBJECTIVE To prepare tetrandrine （TET）-loaded chitosan（CS）-stearic acid （SA） nano micelles modified with folic acid （FA）（ FA-CS-SA/TET nano micelles）， characterize them and study the anti-inflammatory effect in vitro. METHODS FA- CS-SA/TET nano micelles were prepared by ultrasonic method； the preparation technology was optimized by orthogonal test and validation test was also performed with the mass ratio of FA-CS-SA to TET， ultrasound power and ultrasound times as the factors， using the comprehensive score of entrapment efficiency （EE）， drug loading （DL） and particle size as evaluation index. FA-CS-SA/ TET nano micelles prepared by the optimal technology were characterized， and their release performance in vitro was investigated. RAW264.7 cells were used as subjects to investigate their anti-inflammatory activity in vitro. RESULTS The optimal preparation technology included that the mass ratio of FA-CS-SA to TET was 2∶1， ultrasonic power was 200 W， and the ultrasonic frequency was 200 times. The parameters of FA-CS-SA/TET nano micelles prepared by optimized technology included that EE was （98.86± 0.30）%， DL was （28.57±0.34）%， the average particle size was （227.0±9.4） nm， polydispersity index was 0.42±0.04， and the Zeta potential was（12.6±2.3）mV， respectively. The nano micelles were uniform in appearance and round in shape. The nano micelles were released quickly in 0.5% sodium dodecyl sulfate solution， with a cumulative release rate of （79.49±3.43）% within 72 hours， and its anti-inflammatory effect was stronger than that of TET raw materials. CONCLUSIONS FA-CS-SA/TET nano micelles are prepared successfully in the study， with good drug loading performance， uniform particle size， and good in vitro anti-inflammatory activity.

Preparation of paclitaxel-loaded and folic acid-modified poly (lactic-co-glycolic acid) nano-micelles and in vitro anticancer effect on cervical cancer HeLa cells / 中国中药杂志

The paclitaxel-loaded and folic acid-modified poly(lactic-co-glycolic acid) nano-micelles(PTX@FA-PLGA-NMs) were prepared by the emulsion solvent evaporation method, and the parameters of paclitaxel-loaded nano-micelles were optimized with the particle size and PDI as evaluation indexes. The morphology of the nano-micelles was observed by transmission electron microscopy(TEM), and the stability, drug loading and encapsulation efficiency were systematically investigated. In vitro experiments were performed to study the cytotoxic effects of nano-micelles, apoptosis, and cellular uptake. Under the optimal parameters, the nano-micelles showed the particle size of(125.3±1.2) nm, the PDI of 0.086±0.026, the zeta potential of(-20.0±3.8) mV, the drug loading of 7.2%±0.75%, and the encapsulation efficiency of 50.7%±1.0%. The nano-micelles were in regular spherical shape as observed by TEM. The blank FA-PLGA-NMs exhibited almost no inhibitory effect on the proliferation and growth of tumor cells, while the drug-loaded nano-micelles and free PTX exhibited significant inhibitory effects. The IC_(50) of PTX@FA-PLGA-NMs and PTX was 0.56 μg·mL~(-1) and 0.66 μg·mL~(-1), respectively. The paclitaxel-loaded nano-micelles were potent in inhibiting cell migration as assessed by the scratch assay. PTX@FA-PLGA-NMs had good pro-apoptotic effect on cervical cancer HeLa cells and significantly promoted the uptake of HeLa cells. The results of in vitro experiments suggested that PTX@FA-PLGA-NMs could target and treat cervical cancer HeLa cells. Therefore, as nanodrug carriers, PTX@FA-PLGA-NMs with anti-cancer activity are a promising nano-system for improving the-rapeutic effects on tumors.

pH responsive docetaxel micelles with improved therapeutic efficacy on mice xenograft tumor / 药学学报

The non-specific administration of antitumor drugs is the main cause for the side effects of chemotherapy drugs on normal tissues. The application of nanotechnology in the delivery of anti-tumor drugs is one of the important ways to improve the therapeutic effect and to reduce the side effects. The current study aimed to synthesize pH responsive poly (methoxy-ethylene glycol)-poly(lactic acid)-poly-(β-amino ester) (PBAE) triblock copolymers to deliver docetaxel (DTX) and improve the anti-tumor activity of DTX. PBAE was synthesized by ring opening polymerization and Michael addition reaction, its structure and molecular weight was characterized by 1H NMR, the dissociation constant of base (pKb) were determined by acid-base titration method. The critical micelles concentration (CMC) of copolymers was measured by pyrene fluorescence spectroscopy. DTX loaded copolymer micelles were prepared by membrane hydration method. The size and its distribution as well as the stability of micelles were determined by laser light scattering analysis. The drug loading content (DL), entrapment efficiency (EE) and cumulative drug release from micelles were evaluated by high-performance liquid chromatography (HPLC). The sizes of DTX drug-loaded micelles were in the range of 10 to 100 nm with narrow distribution. DL of DTX in PBAE1 and PBAE2 micelles was (5.3 ± 0.10) % and (4.9 ± 0.05) %, respectively, with EE was (93.8 ± 1.70) % and (87.2 ± 4.10) %, respectively. The drug-loaded micelles showed pH sensitive drug release properties under weak acidic conditions, which showed potential drug release of DTX under mild acidic tumor environment. A mouse Lewis lung carcinoma model was established to evaluate the therapeutic efficacy of micellar DTX formulations. Significant inhibitory effect of the nanodrugs was observed with DTX dosages of 10 and 20 mg·kg-1, respectively. Moreover, the pH responsive PBAE1-DTX micellar drug exhibited stronger therapeutic efficacy on mice xenograft tumor, as compared with the non pH sensitive micellar drug (PELA-DTX) and free DTX. All animal experiments were performed according to the animal ethical standards and approved by the Animal Experiments and Ethical Committee of China Academy of Chinese Medical Sciences (No. 2017090110). The in vivo anti-tumor activity studies showed that the tumor volume growth rates of mice in different drug-administered groups were: PBAE1-DTX 20 mg·kg-1 < PBAE1-DTX 10 mg·kg-1 < PELA-DTX 10 mg·kg-1 < DTX 10 mg·kg-1 < normal saline, with the PBAE1-DTX group as the most potent group for tumor inhibition. The current pH sensitive DTX nano-micelles showed high potential in further studies to promote the application of nano DTX formulations for tumor treatment.

Preparation and properties of paclitaxel-loaded self-assembling nano-micelles of cholesterol-bearing γ-Polyglutamic acid / 生物医学工程学杂志

Paclitaxel (PTX)-loaded self-assembling nano-micelles (PTX/NMs) were prepared based on amphiphilic cholesterol-bearing γ-polyglutamic acid (γ-PGA-graft-CH). The properties of PTX/NMs and were investigated. The results indicated that PTX could be entrapped in -PGA-graft-CH NMs. PTX/NMs was characterized with a size of (343.5 ± 7.3) nm, drug loading content of 26.9% ± 0.8% and entrapment efficiency of 88.6% ± 1.7% at the optimized drug/carrier ratio of 1/10, and showed a pH-sensitive sustainable drug-release and less cytotoxicity . release and the pharmacokinetics study in mice showed that the elimination half-life ( ) and area under curve (AUC) of PTX/NMs were significantly higher than those of PTX/polyoxyethylene castor oil (PTX/PCO), and less clearance (CL) of PTX/NMs was also observed. PTX/NMs were distributed higher in liver and tumor than PTX/PCO, and showed a good tumor-inhibiting activity in tumor-bearing mice. This study would lay a foundation on the potential application of -PGA-graft-CH NMs were the antitumor drug-delivery.

Preparation and evaluation of GEN-VES-TPGS1000 nano-micelles / 中草药

Objective: To prepare GEN-VES-TPGS nano-micelles and improve the oral bioavailability of genistein (GEN). Methods: GEN-VES-TPGS nano-micelles, made by film hydration, were evaluated with particle size, entrapment efficiency, and drug-loading as indexes. Single factor experiment was used to optimize the formulation and productive technology, including dosages of TPGS, VES, GEN, hydration volume, temperature, and time. Morphology of nano-micelles, release rate in vitro, and pharmacokinetics in rat were investigated. Results: The results showed GEN-VES-TPGS nano-micelles presented with good clarity, appropriate particle diameter (43.50 ± 1.65) nm, negative charge, when the dosages of TPGS, VES, GEN were 200, 30, and 6 mg, respectively. Meanwhile, a condition of 15 mL, 50 ℃ at 3 h to hydrate was necessary to prepare. In this setting, the encapsulation efficiency of the nano-micelles was (98.99 ± 0.69)% and drug-loading rate was (2.57 ± 0.04)%. The pharmacokinetic results in rats showed the oral bioavailability of GEN-VES-TPGS nano-micelles was 162.96% of the GEN APIs. Conclusion: The prepared GEN-VES-TPGS nano-micelles have small particle size and good stability, and increase the oral bioavailability of GEN evidently.

Determination of Curdione in Nano-micelles Loaded with Curdione by UV-Vis Spectrophotometry / 中国药房

OBJECTIVE:To establish a UV-Vis spectrophotometric method for content determination of Curdione in Nano-micelles loaded with Curdione.METHODS:Curdione was colored by sulfuric acid-vanillin reagent.The absorbance was measured by visible-spectrophotometry at a wavelength of 500nm.RESULTS:The content of Curdione in the range of 0.050～ 0.400mg? mL-1 was in accordance with the Lambert-Beer law(r=0.999 3).The average recovery was 99.14%,and the RSD was 1.23%(n=9).CONCLUSION:This method is simple,accurate and suitable for the content determination of curdione in Nano-micelles loaded with Curdione.