RESUMEN
This study aims to synthesize new phospholipids, 1,3-dipalmaminophospholipid(Pad-PC-Pad), and prepare shear-stress sensitive liposomes(SSSL). 1H NMR and MS indicated that Pad-PC-Pad were fully synthesized successfully. SSSL were prepared by filming-rehydration method with Pad-PC-Pad, which loaded calcein with aggregation-caused quenching(ACQ)characteristics to evaluate shear-stress sensitivity of liposomes and release behavior of liposomes in vitro. The results showed that the particle size of liposomes was 106.91 ± 1.24 nm and liposomes had lenticular morphology under transmission electron microscope. The release of calcein was increased with ultrasonic power, which suggests that the liposomes is shear-stress sensitive. Moreover, the liposomes exhibited a releasing effect for obstructed region under high shear-stress in a model system. Therefore, we synthesized quick functional phospholipid Pad-PC-Pad and the liposomes made from Pad-PC-Pad was shear-stress sensitive, which may be used for treatment of thrombosis.
RESUMEN
This study aims to prepare lipid bilayer-coated calcium phosphate core-shell nanoparticles (LCAPNs), which can dissolve in an acidic environment to improve the tumor cell toxicity of antitumor drug. Paclitaxel (PTX) loaded lipid coated calcium phosphate nanoparticles (PTX-LCAPNs) were prepared by thin-film dispersion method. The morphology, particle size and in vitro release behavior were characterized. Meanwhile, the intracellular uptake, intracellular dissolution, cell toxicity of PTX-LCAPNs and intracellular accumulation of PTX were evaluated in human HCC cell line (Huh-7). The results suggested that the mean diameter of the spherical LCAPNs was 124.73±6.41 nm. The PTX-LCAPNs demonstrated little drug leakage in simulated normal physiological conditions, while a rapid release was observed in simulated intracellular condition in vitro. Moreover, the PTX-LCAPNs achieved 1.7 fold improvement in the intracellular PTX concentration leading to 5-fold reduction in half maximal inhibitory concentration (IC50) values of PTX compared with calcium phosphate nanoparticles loaded with PTX (PTX-CAPNs), demonstrating a stronger cancer cell lethality.