Abstract
The use of nanocarriers composed of polyethylene glycol- and polyvinyl alcohol-coated vesicles encapsulating active molecules in place of conventional chemotherapy drugs can reduce many of the chemotherapy-associated challenges because of the increased drug concentration at the diseased area in the body. The present study investigated the structure and magnetic properties of iron oxide nanoparticles in the presence of polyvinyl alcohol and polyethylene glycol as the basic surface coating agents. We used superparamagnetic iron oxide nanoparticles (FNPs) as the core and studied their effectiveness when two polymers, namely polyvinyl alcohol (PVA) and polyethylene glycol (PEG), were used as the coating agents together with magnesium–aluminum-layered double hydroxide (MLDH) as the nanocarrier. In addition, the anticancer drug sorafenib (SO), was loaded on MLDH and coated onto the surface of the nanoparticles, to best exploit this nano-drug delivery system for biomedical applications. Samples were prepared by the co-precipitation method, and the resulting formation of the nanoparticles was confirmed by X-ray, FTIR, TEM, SEM, DLS, HPLC, UV–Vis, TGA and VSM. The X-ray diffraction results indicated that all the as-synthesized samples contained highly crystalline and pure Fe3O4. Transmission electron microscopy analysis showed that the shape of FPEGSO-MLDH nanoparticles was generally spherical, with a mean diameter of 17 nm, compared to 19 nm for FPVASO-MLDH. Fourier transform infrared spectroscopy confirmed the presence of nanocarriers with polymer-coating on the surface of iron oxide nanoparticles and the existence of loaded active drug consisting of sorafenib. Thermogravimetric analyses demonstrated the thermal stability of the nanoparticles, which displayed enhanced anticancer effect after coating. Vibrating sample magnetometer (VSM) curves of both produced samples showed superparamagnetic behavior with the high saturation magnetization of 57 emu/g for FPEGSO-MLDH and 49 emu/g for FPVASO-MLDH. The scanning electron microscopy (SEM) images showed a narrow size distribution of both final samples. The SO drug loading and the release behavior from FPEGSO-MLDH and FPVASO-MLDH were assessed by ultraviolet–visible spectroscopy. This evaluation showed around 85% drug release within 72 h, while 74% of sorafenib was released in phosphate buffer solution at pH 4.8. The release profiles of sorafenib from the two designed samples were found to be sustained according to pseudo-second-order kinetics. The cytotoxicity studies confirmed the anti-cancer activity of the coated nanoparticles loaded with SO against liver cancer cells, HepG2. Conversely, the drug delivery system was less toxic than the pure drug towards fibroblast-type 3T3 cells.
Highlights
There are many treatments to minimize cancer cell p ropagation[1], such as surgery, chemotherapy and radiation therapy[2,3]
Rather sharp peaks related to magnesium–aluminum-layered double hydroxide (MLDH) at the 2θ positions of 11.5°, 23.2° and 34.8° and sorafenib at the 2θ angles between 10° to 35° were present besides the iron oxide nanoparticles patterns in the final synthesized samples[43]
It should be noted that MLDH and sorafenib peaks overlap in the synthesized samples E and G because their 2θ positions are near to each other
Summary
There are many treatments to minimize cancer cell p ropagation[1], such as surgery, chemotherapy and radiation therapy[2,3]. The major disadvantage of most chemotherapy drugs is the lack of selectivity, which has potential side effects on healthy tissues and cells To solve this problem, targeting magnetic medication using the absorption property of magnetic nanoparticle carriers through an external magnetic field is used to increase the delivery of active molecules to specific sites in the b ody[9−12]. Iron oxide nanoparticles as nanocarriers with various biomedical applications; targeted drug delivery to tumors and cancer treatment These applications are possible due to their simple separation by the external magnetic field, magnetic properties and capability to carry therapeutic agents. The effects of these 2 types of nanoparticles on normal fibroblast 3T3 and liver cancer HepG2 cell lines will be described
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