ABSTRACT
To reduce the problems of poor solubility, high in vivo dosage requirement, and weak targeting ability of paclitaxel (PTX), a hyaluronic acid-octadecylamine (HA-ODA)-modified nano-structured lipid carrier (HA-NLC) was constructed. HA-ODA conjugates were synthesized by an amide reaction between HA and ODA. The hydrophobic chain of HA-ODA can be embedded in the lipid core of the NLC to obtain HA-NLC. The HA-NLC displayed strong internalization in cluster determinant 44 (CD44) highly expressed MCF-7 cells, and endocytosis mediated by the CD44 receptor was involved. The HA-NLC had an encapsulation efficiency of PTX of 72.0%. The cytotoxicity of the PTX-loaded nanoparticle HA-NLC/PTX in MCF-7 cells was much stronger than that of the commercial preparation Taxol®. In vivo, the HA-NLC exhibited strong tumor targeting ability. The distribution of the NLCs to the liver and spleen was reduced after HA modification, while more nanoparticles were aggregated to the tumor site. Our results suggest that HA-NLC has excellent properties as a nano drug carrier and potential for in vivo targeting.
ABSTRACT
To reduce the problems of poor solubility, high in vivo dosage requirement, and weak targeting ability of paclitaxel (PTX), a hyaluronic acid-octadecylamine (HA-ODA)-modified nano-structured lipid carrier (HA-NLC) was constructed. HA-ODA conjugates were synthesized by an amide reaction between HA and ODA. The hydrophobic chain of HA-ODA can be embedded in the lipid core of the NLC to obtain HA-NLC. The HA-NLC displayed strong internalization in cluster determinant 44 (CD44) highly expressed MCF-7 cells, and endocytosis mediated by the CD44 receptor was involved. The HA-NLC had an encapsulation efficiency of PTX of 72.0%. The cytotoxicity of the PTX-loaded nanoparticle HA-NLC/PTX in MCF-7 cells was much stronger than that of the commercial preparation Taxol®. In vivo, the HA-NLC exhibited strong tumor targeting ability. The distribution of the NLCs to the liver and spleen was reduced after HA modification, while more nanoparticles were aggregated to the tumor site. Our results suggest that HA-NLC has excellent properties as a nano drug carrier and potential for in vivo targeting.
ABSTRACT
Objective The paclitaxel loaded solid lipid nanoparticles (PTX-SLNs) were prepared by an ultrasonic-dispersion emulsification technique. The stability of PTX-SLNs was investigated in this study. Methods The technology was preferenced by stability, Zeta potential, particle diameter, and entrapment efficiency as indexes. The doses of lipid materials and coemulsifier, the ultrasonic time, and the ultrasonic power were investigated in detail. Results The optimum prescriptions were definited by one-factor and orthogonal test. The adjuvant: glyceryl monostearate (100/150 mg), Fabaceous Lecithin (100 mg), coemulsifier Pluronic F68∶Tween 80 (2∶1). The samples were sonicated with an energy output of 300 W in 20 min after emulsified at (75?5) ℃. Conclusion The PTX-SLNs are successfully prepared and PTX-SLNs with high stability are fairly dispersed in colloidal solution. This technology has a nice prospect with safety and reliability.