Study on the preparation of hyperoside mixed nanomicelles and its intestinal absorption / 中国药房

OBJECTIVE To prepare hyperoside mixed nanomicelles （Hyp-F127/TPGS） and optimize its preparation technology，and to investigate its intestinal absorption characteristics. METHODS Hyp-F127/TPGS was prepared by thin film dispersion method. Based on single factor test and Plackett-Burman design ，combined with Box-Behnken response surface method ， the preparation process was optimized and validated using entrapped efficiency （EE）and drug loading （DL）as evaluation indexes ， F127-TPGS mass ratio ，hydration time and the amount of Hyp as factors. The appearance and microscopic morphology of Hyp-F127/TPGS obtained by the optimal technology were observed ，and the particle size ，polydispersity index （PDI）and Zeta potential were also determined. The critical micelle concentration （CMC）of blank micelle （F127/TPGS），in vitro release behavior and preliminary stability of Hyp-F 127/TPGS were investigated ，and absorption characteristics of Hyp-F 127/TPGS were investigated by in situ unidirectional intestinal perfusion model. RESULTS The optimal preparation technology of Hyp-F 127/TPGS included F127-TPGS mass ratio of 2∶1，hydration time of 2 h，and Hyp amount of 9 mg. Results of three validation tests showed that the EE of Hyp-F 127/TPGS was （87.20±0.99）％，and the DL was （5.02±1.20）％，deviations from predicted values were 0.92％ and 2.39％. The micelles prepared by optimal technology were yellow ，clear and transparent solution ，with good Tyndall effect ；under transmission electron microscope ，they were spherical ，complete and evenly distributed ；the particle size was （15.02±0.16）nm， the PDI was 0.092±0.031，and the Zeta potential was （－6.67±1.47）mV. The CMC of F 127/TPGS was 21 μg/mL，Hyp-F127/ TPGS was stable after 4 weeks of storage at 4 ℃，and the cumulative release rates of Hyp-F 127/TPGS and Hyp control were （66.30±2.93）％（96 h）and（99.24±0.27）％（60 h），respectively. Hyp-F 127/TPGS and Hyp reference were absorbed in each intestinal segment ，and the main absorption sites were jejunum and duodenum respectively ；drug absorption rate constant andapparent absorption coefficient of the former were significantly higher than those of the latter （P＜0.05 or P＜0.01）. E-mail：zhangyuhangxz@163.com CONCLUSIONS The optimized preparation technology of Hyp-F127/TPGS is stable and feasible ；prepared Hyp-F 127/ TPGS shows a sustained -release effect ，which promotes the intestinal absorption of H yp to a certain extent.

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.

Preparation of glycyrrhizic acid-F127/TPGS mixed nanomicelles and its in vivo intestinal absorption in rats / 中草药

Objective: To prepare glycyrrhizic acid (GL)-Pluronic F127 (F127)/polyethylene glycol 1000 vitamin E succinate (TPGS) mixed nanomicelles (MMs) and improve oral absorption of GL. Methods: GL-F127/TPGS-MMs was prepared by thin film dispersion method. The encapsulation efficiency and drug loading of MMs were used as evaluation indexes. The formulation and process, including the ratio of F127 to TPGS, the concentration of polymer and GL, hydration temperature and time, were optimized by the single factor experiment. The morphology of MMs was investigated by transmission electron microscopy. The single-pass perfusion model was established in rats to investigate the intestinal absorption characteristics of GL-F127/TPGS-MMs with absorption rate constant (Ka) and apparent absorption coefficient (Papp) as evaluation indexes. Results: The optimal formulation and process of GL-F127/TPGS-MMs were as follows: TPGS 180 mg, F127 270 mg, GL 70 mg, hydration temperature 50 ℃ and hydration time 3 h. The prepared GL-F127/TPGS-MMs had good clarity and the particle size, polydispersity index, and Zeta potential were (28.20 ± 5.63) nm, 0.20 ± 0.06, and (-5.24 ± 1.55) mV, respectively. The encapsulation efficiency and drug loading were (97.57 ± 5.29) % and (13.13 ± 0.71) %, respectively. The MMs were spherical with distinct vesicle structure. The absorption of GL in the jejunum segment was significantly higher than that in the ileum segment (P < 0.05). Compared with raw GL, GL-F127/TPGS-MMs had a statistically significant higher absorption rate in the intestinal segment (P < 0.05). Conclusion: The prepared GL-F127/TPGS-MMs could significantly improve the absorption of GL in vivo.

Mitochondrial targeting function of norcantharidin TPP-PEG-PCL nanomicelles promotes apoptosis of liver tumor cells / 中草药

Objective: To prepare norcantharidin TPP-PEG-PCL nanomicelles and study its release in vitro, intracellular transport and promoting effect on hepatoma cell apoptosis. Methods: Thin film hydration method was used to prepare norcantharidin TPP-PEG-PCL nanomicelles, and the particle size, electric potential and microscopic electron microscopy morphological analysis were measured. At the same time, the nanomicelles were evaluated for stability, in vitro release, pharmacokinetics and critical micelle concentration. Coumarin-6 was used as a fluorescent probe to evaluate the uptake of TPP-PEG-PCL nanomicelles in liver tumor cells, lysosomal escape and mitochondrial targeting function; Under the same dosage conditions, the effect of norcantharidin TPP-PEG-PCL nanomicelles on promoting apoptosis of liver tumor cells was evaluated. Results: The cantharidin TPP-PEG-PCL nanomicelles had a particle size of (16.8 ± 0.2) nm, a Zeta potential of (14.3 ± 0.2) mV, and transmission electron microscopy images showed that nanomicelles had a regular spherical shape. The fluorescence test results showed that TPP-PEG-PCL nanomicelles can promote the cellular uptake of drugs, escape lysosomal capture, and finally target aggregation at the mitochondrial site; Cell survival rate and Hoechst staining results showed that cantharidin TPP-PEG-PCL nanomicelles had a good effect on promoting apoptosis of liver tumor cells. Norcantharidin TPP-PEG-PCL nanomicelles can significantly reduce mitochondrial membrane potential, increase intracellular ROS levels, increase pro-apoptotic protein Bcl-2, and reduce resistance. The expression of apoptotic proteins Bax and these pro-apoptotic related experimental results are significantly better than those of norcantharidin PEG-PCL nanomicelles and norcantharidin, which have statistical significance. Conclusion: Norcantharidin TPP-PEG-PCL nanomicelles have good liver tumor cell mitochondrial targeting and promote tumor cell apoptosis, and it is a potentially effective drug delivery system for targeting tumor cell mitochondria.

Study on L-carnitine modified quercetin-coloading chitosan-stearic acid nanomicelles as oral paclitaxel delivery system: Preparation, characterization and in vivo intestine absorption in rats / 中草药

Objective: To prepare a drug delivery system based on L-carnitine modified and quercetin (QUE)-coloading chitosan-stearic acid (LC-SA/CS-SA) nanomicelles, investigate the properties of micelles, and evaluate the enhanced absorption effect of the micelles by in vivo intestinal absorption in rats. Methods: The CS-SA copolymer was synthesized by the amidation of free amino groups on CS. The chemical structure of CS-SA was characterized by Fourier transform-infrared spectroscopy (FT-IR) and nuclear magnetic resonance spectroscopy (NMR). Taking PTX was the main drug and quercetin as the auxiliary drug, the particle size distribution, Zeta potential, drug loading and entrapment efficiency of the micelles were investigated. The micromorphology of the micelles was observed by transmission electron microscope (TEM). The critical micelle concentration (CMC) of LC-SA/CS-SA micelles was measured by fluorescent probe method. The in vitro release of paclitaxel from polymeric micelles was evaluated by dialysis method. The absorption rate coefficient (Ka) of paclitaxel (PTX)-loaded micelles was assessed by in vivo intestine absorption in rats. Results: The results of FT-IR and 1HNMR indicated that the copolymer (CS-SA) was synthesized. The LC-SA/CS-SA@ QUE+PTX micelles showed regular spherical shapes with particle size of (148.3 ± 1.7) nm, PDI of 0.16 ± 0.07, Zeta potential of (24.600 ± 0.167) mV and CMC of 14.31 µg/mL. Compared to the commercial formulation of PTX, LC-SA/CS-SA@QUE+PTX micelles and LC-SA/CS-SA@PTX micelles showed significantly sustained release behaviors. The enhanced absorption effect of PTX in the micelle system was confirmed by intestine absorption test in rats. Conclusion: The LC-SA/CS-SA@QUE+PTX micelles, as a potential oral absorption promoter, enhanced the intestinal absorption of PTX in rats.

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 of docetaxel-loaded nanomicelles and their anti-Lewis lung cancer effect in vitro / 中国中药杂志

Docetaxel-loaded nanomicelles were prepared in this study to improve the solubility and tumor targeting effect of docetaxel(DTX),and further evaluate their anticancer effects in vitro. PBAE-DTX nanomicelles were prepared by film-hydration method with amphiphilic block copolymer polyethyleneglycol methoxy-polylactide(PELA) and pH sensitive triblock copolymer polyethyleneglycol methoxy-polylactide-poly-β-aminoester(PBAE) were used respectively to prepare PELA-DTX nanomicelles and PBAE-DTX nanomicelles. The nanomicelles were characterized by physicochemical properties and the activity of mice Lewis lung cancer cells was studied. The results of particle size measurement showed that the blank micelles and drug-loaded micelles had similar particle sizes, ranging from 10 to 100 nm. The particle size of PBAE micelles was changed under weak acidic conditions, with good pH response. The encapsulation efficiency of the above two types of DTX-loaded nanomicelles determined by HPLC was(93.8±1.70)% and(87.2±4.10)%, and the drug loading amount was(5.3±0.10)% and(4.9±0.05)%,respectively. Furthermore,the DTX micelles also showed significant inhibitory effects on Lewis lung cancer cells by MTT assay, and pH-sensitive PBAE-DTX showed better cytotoxicity. The results of flow cytometry indicated that,the apoptosis rate of lung cancer Lewis cells was(20.72±1.47)%,(29.71±2.38)%,and(40.91±1.90)%(P<0.05) at 48 h after treatment in DTX,PELA-DTX,and PBAE-DTX groups. The results showed that different docetaxel preparations could promote the apoptosis of Lewis cells, and PBAE-DTX had stronger apoptotic-promoting effect. The pH-sensitive DTX-loaded micelles are promising candidates in developing stimuli triggered drug delivery systems in acidic tumor micro-environments with improved inhibitory effects of tumor growth on Lewis lung cancer.

Study on Preparation and in vitro Release Characteristic of Ursolic Acid/PF 127/TPGS-doxorubicin Mixed Nanomicelles / 中国药房

OBJECTIVE： To prepare Ursolic acid （UA）/Pluronic F127 （PF127）/TPGS-doxorubicin （DOX） mixed nanomicelles， and to characterize it and study its in vitro release behavior. METHODS： UA/PF127/TPGS nanomicelles were prepared by thin film hydration method. Using encapsulation efficiency of UA as index， combined with the results of single factor tests， L9（34） orthogonal test was used to optimize drug dosage of UA， molar ratio of PF127 to TPGS， hydration temperature and hydration volume， validation test was performed. On the basis of succinylated TPGS， TPGS-DOX was synthesized and mixed with UA/PF127/TPGS to prepare UA/PF127/TPGS-DOX mixed nanomicelles， the appearance， particle size and critical micelle concentration （PF127/TPGS） were investigated. The drug release behavior was examined by dialysis bag diffusion method. RESULTS： The optimal preparation technology of UA/PF127/TPGS nanomicelles was as follows as drug dosage of UA 8 mg， molar ratio of PF127 to TPGS 3 ∶ 7， hydration temperature 50 ℃， hydration volume 4 mL. Average encapsulation efficiency of UA in nanomicelles was 89.00％ （RSD＝0.43％， n＝3）. The prepared UA/PF127/TPGS-DOX mixed nanomicelles solution was clear with opalescence. The nanomicelles were spherical and uniform in size； average particle size was （115.00±9.42） nm； critical micelle concentration of PF127/TPGS （molecular ratio 3 ∶ 7） was 0.001 3％. The in vitro drug release of UA and DOX in the mixed nanomicelles was significantly slowed down， compared with raw materials or substance control. The drug release process of the two drugs in the nanomicelles conformed to Weibull equation. CONCLUSIONS： UA/PF127/TPGS-DOX mixed nanomicelles are successfully prepared with uniform particle size， good stability and good sustained-release effect.

Study on Preparation ，Characterization and Cytotoxicity of Baicalin PEG-PE Nanomicelles / 中国药房

OBJECTIVE： To prepare Baicalin-loaded Polyethylene glycol-derivatized phosphatidylethanolamine （BAI@PEG-PE） nanomicelles， and to characterize it and study its cytotoxicity. METHODS： BAI@PEG-PE nanomicelles were prepared by film hydration method and their appearance characteristics were observed. The particle size， polydispersity index， Zeta potential， drug-loading amount and encapsulation efficiency of the nanomicelles were detected. Drug release of BAI raw material and BAI@PEG-PE nanomicelles in pH 7.4 phosphate buffer were compared within 1-84 h. Using coumarin 6 as fluorescent probe， the distribution of PEG-PE nanomicelles in H9c2 cardiomyocytes were observed. H9c2 cardiomyocytes were divided into model group， BAI raw material group and BAI@PEG-PE nanomicelles group. After treated with serum-free DMEM medium containing no or corresponding drugs for 0.5 h， isoproterenol was used to induce cardiomyocyte apoptosis. Nuclear morphology， cell apoptosis rate and protein expression of Bcl-2 and Bax were compared with among 3 groups. RESULTS： Prepared BAI@PEG-PE nanomicelles were uniform globular shape. The particle size was （16.7±0.8） nm， PDI was 0.11±0.01 and Zeta-potential was （－18.4±0.6） mV； drug-loading amount was （7.84±0.65）％， encapsulation efficiency was （85.7±4.9）％ （n＝3）. Accumulative release rate was 76.5％ within 84 h. BAI raw material was released completely within 24 h. PEG-PE nanomicelles could strengthen the intake of coumarin 6 in H9c2 cardiomyocytes， mainly gathering around mitochondria. Compared with model group， the apoptosis morphology of cardiomyocytes were improved significantly in BAI raw material group and BAI@PEG-PE nanomicelles group； apoptosis rate was decreased significantly； protein expression of Bcl-2 was increased significantly； protein expression of Bax was decreased significantly with statistical significance （P＜0.05 or P＜0.01）. Above effects of BAI@PEG-PE nanomicelles group were more significant （P＜0.05 or P＜0.01）. CONCLUSIONS： BAI@PEG-PE nanomicelles are prepared successfully， and show significant sustained-release effect and myocardial targeting， and can prevent cardiomyocyte apoptosis.

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 characterization of baicalin PEG-PLGA nanomicelles and tissue distribution in rats with acute myocardial ischemia / 中草药

Objective To prepare baicalin-polyethylene glycol-poly (lactic-co-glycolic acid) copolymer (PEG-PLGA)-loaded nanomicelles, and study its in vitro drug release properties and tissue distributed in rats with acute myocardial ischemia. Methods The preparation process of baicalin PEG-PLGA nanomicelles was optimized by orthogonal test. The optimized baicalin PEG-PLGA nanomicelles were characterized by particle size, Zeta potential, and TEM electron microscopy. The in vitro release assay and tissue distribution of the acute myocardial ischemia rat model were used to evaluate this drug delivery system. Results The preferred preparation conditions for baicalin PEG-PLGA nanomicelles were a mass ratio of baicalin to PEG-PLGA at 1:10 with a rotary evaporator rotation rate of 80 r/min and a hydration temperature of 40 ℃. The optimized baicalin PEG-PLGA nanomicelle particle size was (18.5 ± 0.5) nm, the zeta potential was (-10.9 ± 0.7) mV, the drug loading was (7.9 ± 0.3)%, and the encapsulation efficiency was (86.2 ± 2.5)%. The critical micelle concentration of PEG-PLGA nanomicelles was 3.8 μg/mL by oxime assay. TEM showed that baicalin PEG-PLGA nanomicelles presented a spherical shape with uniform particle size, In vitro release test showed that baicalin PEG-PLGA nanomicelles had obvious sustained release characteristics; Tissue distribution test showed that the order of distribution of baicalin PEG-PLGA nanomicelles in normal rat organs was liver > spleen > heart > kidney > lung > brain, while the distribution of baicalin PEG-PLGA nanomicelles in acute myocardial ischemia model was liver > heart > spleen > kidney > brain. Compared with normal rats, the drug concentration in the heart of rats with acute myocardial ischemia showed a significant increase trend in all time periods, and the highest drug concentration at 120 min could reach (2 897 ± 135) ng/mL, the highest drug concentration of the heart in the normal rats was (2 411 ± 89) ng/mL, which indicated that the baicalin PEG-PLGA nanomicelles had good targeting in the acute myocardial ischemia zone. Conclusion Baicalin PEG-PLGA nanomicelles have good drug-loading properties, slow release in vitro, and can accumulate drugs in the ischemic myocardium, which has good cardiac targeting.

In vitro evaluation of mitochondrial-targeted taxol TPP-PEG-PE nanomicelles and promotion of tumor cell apoptosis / 中草药

Objective To prepare taxol TPP-PEG-PE nanomicelles and study its in vitro release behavior, mitochondrial targeting and pro-apoptosis of A549 lung cancer cells. Methods The taxol TPP-PEG-PE nanomicelles were prepared by membrane hydration method. Based on the drug loading, encapsulation efficiency and particle size, the preparation parameters of taxol TPP-PEG-PE nanomicelles were optimized. The preferred nano-drug delivery system was then characterized. The drug delivery system was evaluated by in vitro drug release, mitochondrial targeting, lung cancer cell toxicity, and apoptosis assay. Results The diameter of taxol TPP-PEG-PE nanomicelles was (18.7 ± 0.8) nm, Zeta potential was (13.4 ± 0.5) mV, and the results of TEM electron microscopy showed that the taxol TPP-PEG-PE nanomicelles were regular spheres of uniform size. Mitochondrial targeting experiments showed that TPP-PEG-PE nanomicelles can promote drug accumulation in mitochondrial sites. Lung cancer cytotoxicity assay showed that taxol TPP-PEG-PE nanomicelles had good anti-apoptotic effect, and Hoechst staining suggested that a large number of morphological changes were observated in apoptotic lung cancer cells. Taxol TPP-PEG-PE nanomicelles could significantly increase the pro- apoptotic Caspase-3 activity and reduce the expression of anti-apoptotic protein Bcl-2 and c-IAP1. They were all significantly superior to that of taxol-PEG-PE nanomicelles and taxol group (P < 0.01). Conclusion The taxol TPP-PEG-PE nanomicelles had good mitochondrial targeting of lung cancer cells and promoted the apoptosis of lung cancer cells. It was a potential and efficient drug delivery system for lung cancer cell mitochondria.

Regulatory effects and mechanism about iRGD-functionalized nanomicelles on colorectal cancer multidrug resistance / 中国医师进修杂志

In recent years, conventional targeting of chemotherapeutic drugs on colorectal tumor tissue is poor in the clinical application. Due to the multidrug resistance of colorectal tumors, penetration and cytotoxicity of conventional drugs greatly reduced on tumor tissue. With the advent of tumor-penetrating peptides, a new and highly effective antitumor drug delivery system has become a research topic of international scholars. This article will briefly describe the research progress of iRGD peptides with the modified nanomicelles drug delivery system on targeted drug delivery and resistance to drug-resistant colorectal tumors in recent years. These studies show that iRGD peptide-modified nanomicelles will be a highly potential anti-drug delivery system.

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.

Preparation and in vitro evaluation of ampelopsin-loaded nanomicelles / 中国中药杂志

To improve the solubility and antitumor activity of ampelopsin, ampelopsin-loaded nanomicelles from the mixture of pluronic F127 and D-α-tocopheryl polyethylene glycol 1000 succinate (TPGS1000) were prepared by film-thin hydration method, in order to optimize the process conditions and physicochemical properties. The antitumor activities against MCF-7 cells between ampelopsin and nanomicelles were compared by MTT method, respectively. The results showed that the optimal nanomicelles were round with the nanometric size of (22.6±0.5) nm, encapsulation efficiency rate of (80.42±1.13)%, and drug-loading rate of (4.41±0.26)%. The solubility of ampelopsin in mixed nanomicelles significantly increased by 16 times. In different release media, the mixed nanomicelles could release more than 90% of drug in 8 h, and showed stronger cytotoxicity and inhibition against MCF-7 cells (P<0.01). The mixed nanomicelles can be used as new drug delivery system of ampelopsin.

Study on doxoru bicin-loaded star-shaped multi-arm PLGA-PEG-NH2 nanomicelles / 国际生物医学工程杂志

ObjectiveTo develop doxorubicine-loaded nanomicelles based on a type of novel starshaped 4-arm PLGA-PEG-NH2 amphiphilic block copolymers.Methods 4s-(PLGA-PEG-NH2) synthesized by 4s-PLGA and (H2N-PEG-NH2) according to N,N'-dicyclohexylcarbodiimide(DCC) condensation reaction was demonstrated by 1H NMR spectroscopy and gel permeation chromatography(GPC); DOX-loaded 4s-(PLGA-PEG-NH2) nanomicelles were self-assembled by doxorubicin(DOX) and 4s-(PLGA-PEG-NH2) via emulsion-solvent evaporation method and characterized in terms of morphology,particle size and size distribution,drug loading,encapsulation efficacy,cell uptake and cytotoxicity studies.Results4s-(PLGA-PEG-NH2) were capable of selfassembling intocore-shell nanomicelles structure and encapsulating DOX into their hydrophobic cores.The mean size of DOX-loaded 4s-(PLGA-PEG-NH2) was nanometer size; drug loading and encapsulation efficacy were around 7.5％ and 75.2％,respectively.Mean surface charge of the micelles was around -17.6 mV.In vitro cell uptake and cytotoxicity studies indicated that comparing to the DOX-loaded linear-(PLGA-PEG-PLGA)nanomicelles,DOX-loaded 4s-(PLGA-PEG-NH2) nanomicelles showed better performance in uptaking by HeLa cells and higher cytotoxicity to cancer cells.Conclusion4s-(PLGA-PEG-NH2) amphiphilic block copolymers can be successfully used in encapsulating DOX,self-assemblingcore-shell nanomicelles in aqueous solvent.Therefore,4s-(PLGA-PEG-NH2) copolymers can be considered as a promising drug carrier in effectively carrying hydrophobic drug,improving the efficacy while reducing the side effect.

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.