ABSTRACT
Tumor has become the second most serious disease that threatens human health and life. Treating with chemical drugs (referred to as chemotherapy) is the most basic treatment, but most chemotherapeutic drugs cause damage to normal tissues. It is a difficult problem in the field of biomedical research that how to deliver anti-tumor drugs more efficiently, increase the concentration of drugs in tumor tissues, enhance the anti-tumor effect, and decrease the drug distribution in normal tissues to weaken the damage to normal tissues. In order to achieve the goals of accurate delivery of anti-tumor drugs and synergism and attenuation, the researchers used systematic evolution of ligands by exponential enrichment technology (SELEX technology) to screen aptamers that can specifically target tumor markers or tumor cells, and designed the novel liposome targeting drug delivery system with aptamers as targeting molecules (ligands). This paper briefly introduced nucleic acid aptamer technology and common tumor markers, and reviewed the research advances on the antitumor effect of aptamer-liposome drug delivery system. It will provide references for the selection of appropriate tumor markers as targets and the application of aptamer technology in the research and development of high-efficiency and low-toxicity liposome targeting agents of anti-tumor traditional Chinese medicine. Meanwhile, it is of great significance for promoting the application of aptamer technology in targeted drug delivery systems.
ABSTRACT
Objective: To integrate the toxic component of cantharidin (CTD) into a novel nanostructured lipid carrier (NLC) and optimize the cantharidin nanostructured lipid carrier (CTD-NLC) formulation process to reduce the toxicity of CTD and enhance its targeting. Methods: CTD-NLC was prepared by emulsified ultrasonic dispersion method. The encapsulation efficiency was determined by dialysis method. The average particle size, particle size distribution (polydispersity index, PDI), Zeta potential, encapsulation efficiency, and drug loading were taken as indicators. Univariate investigation and central composite design-response surface methodology (CCD-RSM) were used to optimize the prescription process of CTD-NLC. Multivariate quadratic fitting was used to evaluate the model equation between indicators and factors. The fitted equation was analyzed by the variance analysis and the optimal prescription was predicted by the resonse surface. Results: The optimized CTD-NLC prescriptions were as follow: mass of total lipid was 453.66 mg, solid to liquid lipid ratio of 1:2, total stable dose of 16.9 mg/mL, ratio of Pluronic F68 to egg yolk lecithin (Lipoid E PC S) of 3.88:1, with ultrasound for 30 min (working 2 s, stopping 2 s). The prepared CTD-NLC was clear clarification in appearance with light blue opalescence, the average particle size was (85.99 ± 0.49) nm, PDI was 0.280 ± 0.002, Zeta potential was (-8.21 ± 0.24) mV, encapsulation efficiency was (98.57 ± 0.05)%, and drug loading was (0.65 ± 0.01)%. Conclusion: The fitting model established by CCD-RSM is accurate and reliable. The optimized CTD-NLC distribution is concentrated, with high encapsulation efficiency and good physical stability. It lays a foundation for the subsequent in vitro and in vivo studies of CTD-NLC.