水溶性壳聚糖包覆多西他赛纳米脂质体的制备及性能研究

目的:制备羧甲基壳聚糖包衣多西他赛纳米脂质体,并考察其体外释放度。方法:采用薄膜分散法制备多西他赛阳离子脂质体,并用不同浓度的羧甲基壳聚糖包覆阳离子脂质体;用超滤法测定其包封率;用激光电位粒径测定仪分别测定其Zeta电位和粒径大小,并用透射电镜观察其形态;用透析法考察其体外释药性质。结果:所制的羧甲基壳聚糖包覆的脂质体包封率达99.98%;Zeta电位为-12.8 mV,平均粒径为(150±17)nm。结论:本实验制备的羧甲基壳聚糖包衣多西他赛纳米脂质体具有高包封率,粒径大小均匀,体外能显著延缓药物释放的性质。     

光敏性多西他赛脂质体的制备、处方优化和体外释放度研究

目的：以富勒烯丙二酸衍生物（DMA-C60）-多西他赛为模型药物,构建光敏性脂质体,增强抗肿瘤效果。系统研究脂质体（LP）的制备工艺、理化性质、处方优化和体外释放特性。方法：采用Bingle环加成反应和酯水解反应合成了DMA-C60,采用傅立叶变换红外光谱（FT-IR）对产物表征定性;采用薄膜法制备DMA-C60-DTX脂质体;超滤离心法测量DTX包封率和载药量;采用激光纳米粒度测定仪测定粒径、粒径分布和Zeta电位;透射电镜测定脂质体外观形态;利用差示扫描量热法（DSC）考察LP中原料药DTX及脂质材料的晶形存在状态;采用透析袋法测量体外释放度并拟合释放模型。结果：采用FT-IR表征定性DMA-C60合成成功。最优处方得到的DMA-C60-DTX-LP,平均粒径约为170 nm,Zeta电位约为-30 mV,DTX包封率（85.76±2.60）%,DMA-C60包封率约为89%;透射电镜观察DMA-C60-DTX-LP呈类球形,粒径大小约为170 nm,分布均匀且与所测粒径大小相符;DSC显示DTX原料药几乎以无定型的状态存在于脂质内核中;DMA-C60的加入并不影响DTX的释放,60 h内累计释放百分数为80%,DTX在LP中体外释放行为可用Ritger-Peppas释放动力学方程进行描述。结论：光敏性多西他赛脂质体载药量和包封率较高、脂质体外观呈类球形,粒径较小且分布均匀,体外释放具有一定的缓释作用。     

多西他赛脂质体冻干粉的制备及质量评价

采用薄膜分散法结合冷冻干燥工艺制备多西他赛脂质体冻干品.采用正交试验,以包封率为指标优化处方,并考察了形态、粒径、包封率、体外释放和稳定性.结果表明,按优化处方制得的脂质体冻干品复溶后颗粒呈球形,平均粒径为(167.1±71.2)nm,平均包封率为(85.9±0.6)%;24h累积释放70.3%,释放曲线符合Weibull方程.多西他赛脂质体冻干品4℃放置3个月稳定性良好.     

不同粒径多西他赛固体脂质纳米粒制剂及其细胞毒活性

目的制备不同粒径的多西他赛(docetaxel,DTX)固体脂质纳米粒,考察多西他赛固体脂质纳米粒理化性质,研究粒径对体外释放行为以及细胞毒作用的影响。方法通过热熔超声法制备不同粒径多西他赛固体脂质纳米粒,观察纳米粒形态,测定其包封率、粒径、Zeta电位。考察粒径因素对固体脂质纳米粒体外释放行为、体外细胞毒性的影响。结果制备的纳米粒均为球形及类球形,3种粒径的多西他赛固体脂质纳米粒平均粒径分别为(83.7±8.4)、(162.7±11.9)、(232.1±26.4)nm;Zeta电位分别为-24.19、-23.67、-23.19 mV;包封率分别为98.03%、97.84%、97.92%。60 h粒径分别为83、16、232 nm的多西他赛固体脂质纳米粒在释放介质中分别累计释放86.34%、76.98%、67.14%。3种不同粒径多西他赛固体脂质纳米粒(DTX-SLN-83,DTX-SLN-162,DTX-SLN-232),多西他赛原料药(DTX solutions)以及空白SLN溶液与多西他赛的混合溶液(physi-calm ixture)对MCF-7细胞作用24 h的IC50值分别为3.36、6.20、9.74、13.15、12.92 mg.L-1;48 h的IC50值分别为0.93、2.01、4.35、9.48、9.21 mg.L-1;72 h的IC50值分别为0.30、0.91、1.67、7.36、7.82 mg.L-1。随着多西他赛固体脂质纳米粒粒径的减小,其肿瘤细胞杀伤力逐渐增强。结论热熔超声法可用于制备不同粒径多西他赛固体脂质纳米粒。降低固体脂质纳米粒粒径有利于药物更完全地释放,同时增强其对肿瘤细胞的杀伤能力。     

星点效应面法对多西他赛他莫昔芬复方脂质体处方的优化

摘要：目的:优化多西他赛他莫昔芬复方脂质体处方。方法:采用单因素试验考察脂药比、大豆磷脂/胆固醇比、枸橼酸他莫昔芬/多西他赛比3个因素对脂质体粒径、ζ电位、分散度指数(PdI)、药物包封率和载药量的影响;采用2因素5水平的星点设计-效应面法,以多西他赛包封率和载药率为评价指标进行处方优化。结果:最优处方为脂药比为19∶1,大豆磷脂/胆固醇比为9∶1,多西他赛的包封率为(82.24±1.41)%,他莫昔芬的包封率为(93.14±2.67)%。结论:优化所得处方为多西他赛他莫昔芬复方脂质体的开发提供了基础保证。     

全反式维甲酸前体脂质体的制备及体外评价

目的:制备维甲酸前体脂质体,并对其体外性质进行考察。方法:采用乙醇注入结合冷冻干燥法制备前体脂质体;微柱离心-高效液相色谱法测定脂质体的包封率;并进一步对其粒径、Zeta电位、血浆释放率及乙醇残留量进行测定。结果:所制备的前体脂质体包封率为95.2%,Zeta电位为-(28.4±17.5)mV,粒径为(170±29)nm,乙醇残留量为3.98%。结论:乙醇注入结合冷冻干燥法制备的维甲酸前体脂质体包封率高,粒径均匀,稳定性好。     

多西他赛普朗尼克P123胶束的制备

摘 要 目的： 优化以普朗尼克P123为载体材料的多西他赛胶束处方工艺。方法: 采用薄膜水化法制备多西他赛普朗尼克P123胶束。采用星点设计 效应面法优化胶束处方工艺,以包封率作为评价指标,考察投药量、有机溶剂体积、水化体积、水化温度。采用透射电镜观察胶束形态,并测定胶束的粒径和Zeta电位,以透析法进行胶束体外释放特性考察。结果: 以多元线性回归和二次、三次多项式拟合指标与因素之间的数学关系,结果表明三次多项式拟合度较好,制备出的胶束形态圆整,平均粒径和Zeta电位分别为108.3 nm和 3.99 mV,多分散指数为0.265,平均包封率和载药率分别为（97.91%±0.28％）和（3.72%±0.12％）,多西他赛胶束120 h的累积释放率达95.03%,具有一定的缓释能力。结论:采用薄膜水化法制备的多西他赛胶束工艺简单可行,具有较高的包封率,在体外具有较好的缓释效果。     

多西他赛纳米脂质载体的制备及其性质考察

目的制备多西他赛纳米脂质载体,并考察其剂型性质及体外释药行为。方法采用薄膜超声法制备多西他赛纳米脂质载体,使用透射电镜观察粒子外观形态,光子相关光谱法测定其粒径和分布,微柱离心法测包封率,透析法测体外释药特性。结果在优化条件下制备的纳米级粒子粒径为(124±16)nm,Zeta电位为-19.57 mV,包封率为95.8%。体外释放符合Weibull释放模型。结论制备的多西他赛纳米脂质载体粒径小,药物包封率高,并可实现药物控释。     

兰索拉唑脂质体的制备及其药剂学性质考察

目的:研究兰索拉唑阳离子脂质体的制备方法并考察其药剂学性质。方法:采用正交设计筛选处方,乙醇注入法制备兰索拉唑脂质体;超滤法测定其包封率;用透射电镜观察脂质体的外观形态,并用粒径分析仪和Zeta电位仪分别测定脂质体的粒径和Zeta电位;进一步考察脂质体的释放规律。结果:所得脂质体包封率约为(80±1.23)%;形态为粒径均匀的球形和类球形,粒径为(184±21)nm,Zeta电位为(36.1±5)mV;脂质体的体外释放符合一级方程;具有较好的稳定性。结论:优选得到的脂质体处方和制备工艺合理、稳定,其体外释放具有缓释特点。     

多西紫杉醇脂质体的制备及稳定性考察

目的:制备多西紫杉醇脂质体并对其稳定性进行考察。方法:采用薄膜-超声分散法制备脂质体,利用高效液相色谱法测定其主药含量,并考察其粒径、Zeta电位、包封率等指标及在室温条件下密封放置2wk与4℃下冰箱中保存6mo的稳定性。结果:所得脂质体粒径小而均匀,粒径均值为(138.8±1.1)nm,Zeta电位为(2.25±0.2)mV,包封率均在70%以上;多西紫杉醇检测浓度线性范围为0.0325～2.600mg·mL-1(r=0.9993);平均回收率为100.91%(RSD=1.38%,n=3);稳定性考察各项指标均无明显改变。结论:所制制剂包封率较高,稳定性良好。     

Preparation, characterization and evaluation of docetaxel-loaded, folate-conjugated PEG-liposomes

For the purpose of enhancing the anticancer potency of docetaxel, a novel excipient, cholesterol-PEG-folate (α-(3.beta) cholest-5-en-3-ω-folic acid-poly (oxy-1, 2-ethanediyl)), was synthesized and used for the preparation of liposomes (folate-conjugated PEG-liposomes). The in vitro release properties, in vitro cytotoxicity, in vivo pharmacokinetics and distribution, as well as in vivo potency of the liposomes were evaluated. These liposomes were able to control the release of the loaded drug. Docetaxel-loaded, folate-conjugated PEG-liposomes were more cytotoxic to MCF-7 cells than ordinary PEG-liposomes. The pharmacokinetic parameters of folate-conjugated PEG-liposomes were studied in rats. Compared to docetaxel solution, the folate-conjugated PEG-liposomes enhanced the t(1/2) of docetaxel by 6.74-fold. The biodistributions of docetaxel in the heart, brain and kidneys decreased when delivered in liposomes. The folate-conjugated PEG-liposomes could significantly enhance tumor accumulation of docetaxel and antitumor activity in tumor-bearing mice (p<0.05). The precent results indicate that these folate-conjugated PEG-liposomes might enhance the potency while preventing the side effects of docetaxel.     

Preparation, characterization and pharmacokinetics of N-palmitoyl chitosan anchored docetaxel liposomes

The objective of this work was to investigate the preparation, characterization and pharmacokinetics of N-palmitoyl chitosan anchored docetaxel liposomes. To decrease toxic effects and improve antitumour efficacy of the drug, docetaxel has been incorporated in liposomes; the formulation, stability and pharmacokinetics of plain docetaxel liposomes (PDLs), PEGylated docetaxel liposomes (PEGDLs) and N-palmitoyl chitosan anchored docetaxel liposomes (NDLs) were compared. NDL was more stable than PDL and PEGDL in-vitro, especially in the presence of serum at 37 degrees C. The concentration of docetaxel in the plasma of rats after intravenous administration of docetaxel injection, PDL, PEGDL and NDL was studied by RP-HPLC. The pharmacokinetic behaviour of docetaxel injection, PDL, PEGDL and NDL were significantly different. These findings suggest that anchored liposomes could increase the stability of docetaxel in-vivo, as compared with plain liposomes, but the improvement was not more significant than PEGylated liposomes. N-Palmitoyl chitosan as a new polymeric membrane to anchor liposome was useful to stabilize liposomes containing anti-tumour drug.     

液相色谱-质谱联用法考察多西他赛脂质体犬体内药动学

目的:研究多西他赛脂质体Beagle犬体内药动学。方法:采用单剂量双周期自身交叉设计, Beagle犬前肢皮下头静脉分别滴注多西他赛脂质体和多西他赛注射液(参比制剂),建立液相色谱-质谱联用(LC-MS)法测定不同时间血浆中多西他赛浓度。结果:多西他赛在0．5～2 000μg·L~(-1)范围内线性关系良好(r＞0．99),提取回收率大于90%,日内、日间精密度RSD＜15%。多西他赛脂质体和多西他赛注射液,CL分别为(11±s 6)和(25±6)L·h~(-1),AUC_(0～∞)分别为(2630±1115)和(1148±310)μg L~(-1)·h,MRT分别为(4．1±2．0)和(2．7±1．3)h,且2种制剂的CL、AUC_(0～∞)和MRT均具有显著或非常显著差异。结论:本方法灵敏度高,准确、可靠。与多西他赛注射液相比,多西他赛脂质体具有一定的缓释和长循环特征。     

多西他赛他莫昔芬脂质体体外释放研究

目的考察多西他赛他莫昔芬复方脂质体体外释放。方法薄膜分散法制备单方和复方脂质体样品,通过透析法进行脂质体体外释放,采用高效液相色谱法测定他莫昔芬和多西他赛药物浓度,并对体外释放曲线进行数学模型拟合。结果单方和复方脂质体中,他莫昔芬和多西他赛均无突释,多西他赛较他莫昔芬释放快,他莫昔芬和多西他赛释放模型符合一级释放方程,他莫昔芬和多西他赛的释放曲线相似。结论他莫昔芬和多西他赛在单方和复方脂质体体外释放并无显著差异。     

Solid dispersion and effervescent techniques used to prepare docetaxel liposomes for lung-targeted delivery system: in vitro and in vivo evaluation

A lung-targeting liposomal docetaxel was developed to improve therapeutic index and to reduce side effects. Docetaxel proliposomes composed of docetaxel/Tween-80/Phospholipon 90H/cholesterol/citric acid at molar ratio of 0.18:0.09:3.78:3.78:91.17 were prepared by solid dispersion technique, and then were hydrated with NaHCO₃ solution to obtain docetaxel liposomes by effervescent technique. The stability of proliposomes containing docetaxel, characterization and evaluation of lung-targeting effect of docetaxel liposomes in rabbit were studied. Docetaxel proliposomes were stable at 6?±?2°C for at least 12 months. The particle size, zeta-potential, and entrapment efficiency of the resulted liposomes were 1011?±?22?nm, ?23.7?±?0.26?mv, and 90.12?±?0.36%, respectively. As far as the targeting parameters are concerned, the relative intake rate (R_e) and the ratio of peak concentration (C_e) of lung were 28.91 and 74.28, respectively. Compared with liver, spleen, and kidney, the ratios of targeting efficacy (T_e)_liposomes to (T_e)_injection of lung were increased by a factor of 3.16, 23.00, and 27.83, respectively. In conclusion, the negatively charged docetaxel liposomes with diameter of about 1 µm described in this study have favorable lung-targeting effect and are a promising lung-targeting carrier.     

Vitamin E TPGS coated liposomes enhanced cellular uptake and cytotoxicity of docetaxel in brain cancer cells

The aim of this work was to develop a drug delivery system of liposomes, which are coated with D-alpha-tocopheryl polyethylene glycol 1000 succinate (TPGS), a PEGylated vitamin E, with docetaxel as a model drug for enhanced treatment of brain tumour in comparison with the nude liposomes as well as with the so-called stealth liposomes, i.e. those coated with polyethylene glycol (PEG), which have been intensive investigated in the literature. Docetaxel or coumarin-6 loaded liposomes were prepared by the solvent injection method and characterized for their particle size, polydispersity, zeta potential and drug encapsulation efficiency. C6 glioma cells were employed as an in vitro model to access cellular uptake and cytotoxicity of the drug or coumarin-6 loaded liposomes. The particle size of the PEG or TPGS coated liposomes was ranged between 126 and 191nm. High-resolution field-emission transmission electron microscopy (FETEM) confirmed the coating of TPGS on the liposomes. The IC50 value, which is the drug concentration needed to kill 50% cells in a designated time period, was found to be 37.04±1.05, 31.04±0.75, 7.70±0.22, and 5.93±0.57μg/ml for the commercial Taxotere(?), the nude, PEG coated and TPGS coated liposomes, respectively after 24h culture with C6 glioma cells. The TPGS coated liposomes showed great advantages in vitro than the PEG coated liposomes.     

The anti-tumor performance of docetaxel liposomes surface-modified with glycyrrhetinic acid

Purpose: Anti-tumor performance of docetaxel liposomes surface-modified with glycyrrhetinic acid (GA-DX-Lip) as a new hepatocytes-targeted delivery vehicle was investigated, unmodified docetaxel liposome (DX-Lip) was chosen as a comparison.

Methods: GA-DX-Lip was prepared by film dispersion method. The physicochemical properties were characterized. The cellular uptake mechanism of GA-modified liposomes was studied in hepatocytes and nonparenchymal cells. Pharmacokinetics and the anti-tumor activity in vitro and in vivo of GA-DX-Lip were investigated.

Results: The size of GA-DX-Lip was about 90 nm with negative charge and the entrapment efficiency was more than 95%. GA-modified liposomes had the specific receptor-mediated cellular endocytosis to hepatocytes, and the uptake ratio of hepatocytes to nonparenchymal cells was 2.28 times. The tumor inhibitory ratio of GA-DX-Lip in vitro was 2.03 times of DX-Lip, the T/C of GA-DX-Lip was 20.14%, better than the 33.27% of DX-Lip. There was no obvious difference in pharmacokinetics parameters.

Discussion and Conclusion: The preliminary cellular uptake test showed the receptor-mediated endocytosis and enhanced hepatocytes-target for GA-modified liposomes. Compared with the unmodified liposome, GA-DX-Lip possessed better anti-tumor activity and unchanged pharmacokinetic behavior. The present results suggest that the GA-modified liposomes may be a promising delivery system for hepatocytes-target.     

甘草次酸修饰多西紫杉醇脂质体的制备和体外抑瘤效果

目的:制备甘草次酸(GA)修饰的多西紫杉醇脂质体,并初步考察其体外抗肿瘤效果.方法:化学合成甘珀酸十八醇酯(18-GA-Suc)作为修饰材料,采用薄膜分散法制备甘草次酸修饰的多西紫杉醇脂质体,考察影响脂质体包封率的因素.采用MTT法评价脂质体对HepG2细胞的体外抑瘤效果.结果:18-GA-Suc修饰的DX脂质体的体外抑瘤效果强于未修饰的DX脂质体,并且抑瘤效果随着载体中18-GA-Suc的增加而增强.结论:甘草次酸修饰的脂质体有望成为新型肝靶向的抗肿瘤载体.     

Evaluation of glycosylated docetaxel-encapsulated liposomes prepared by remote loading under solubility gradient

Docetaxel comprises one of the most effective anti-cancer drugs despite of serious side effects. Liposomes encapsulation is practically feasible to deliver the drug. However, due to the significant hydrophobicity, docetaxel will be integrated into the lipid bilayer resulting in poor encapsulation capacity. Here, we evaluated a remote loading strategy using a solubility gradient made between the two solvents for 7-glucosyloxyacetyldocetaxel, which has enhanced water solubility of docetaxel with a coupled glucose moiety. Therefore, 7-glucosyloxyacetyldocetaxel was more effectively encapsulated into liposomes with 71.0% of encapsulation efficiency than docetaxel. While 7-glucosyloxyacetyldocetaxel exhibited 90.9% of tubulin stabilisation activity of docetaxel, 7-glucosyloxyacetyldocetaxel encapsulated in liposomes significantly inhibited the growth of tumour in vivo with side effects less than unencapsulated drug. Collectively, the encapsulation of 7-glucosyloxyacetyldocetaxel into liposomes by remote loading under the solubility gradient is considered to be a promising application to prepare practical drug delivery system.     

叶酸受体介导多西他赛长循环脂质体与肿瘤细胞结合机理的研究

目的研究叶酸受体介导多西他赛长循环脂质体与肿瘤细胞的结合机理。方法采用薄膜分散法制备脂质体,采用荧光法、流式细胞仪和荧光显微镜检测脂质体与MCF-7细胞、Hela细胞的结合。结果叶酸受体介导多西他赛长循环脂质体与MCF-7细胞的结合量大于Hela细胞;游离叶酸可竞争抑制叶酸受体介导多西他赛长循环脂质体与MCF-7细胞的结合;荧光显微镜下,MCF-7细胞可见明亮绿色荧光,而Hela细胞中只有微弱绿色荧光。结论叶酸受体介导多西他赛长循环脂质体是通过叶酸介导的细胞内化而进入细胞。