Synthesis of supperparamagnetic CoFe2O4 with chitosan-g-PEG copolymer coating for the biomedical applications

4^th World Congress on Cancer Science & Therapy

October 20-22, 2014 DoubleTree by Hilton Hotel Chicago-North Shore Conference Center, USA

Narges Pourbagher

Accepted Abstracts: J Cancer Sci Ther

Abstract :

Background: Nowadays, applications of magnetic nanoparticles have developed in today?s treatments, such as gene therapy,chemotherapy, protein therapy, imaging and magnetic hyperthermia therapy. In this work, we preparedsuperparamagnetic ferrite nanocrystals with polymer coating as new candidate for cancer diagnosis, staging, and treatment (Magnetic fluid hyperthermia). Methods: Nano-CoFe2O4 particles with diameter of 12 nm were synthesized,by Chemical Coprecipitation methodby using inorganic base. Surface modifications of NPs were done by electrostatic bond between NPs and the trimethylchitosan (TMC). Then the grafts of PEG ontonanocomposites were rapidly formed by covalentbond between TMC-NPs and PEG. Result: Monodisperse particles, high colloidal stability and superparamagneticproperties were observed, by using the simple method with the certain molar concentration of Co2+ in 3M NaOH at 100°C. The design of NP surface was done by grafting an appropriate amount of PEG onto the TMC backbone based on structure and physiology of tumor cells. In vivo, thetherapeutic success of magnetic NPs relies on thehydrodynamic sizes of NPs between 10 and 100 nm and maximize blood half-life of NPs. The hydrodynamic diameters of synthesized PEG-g-TMC-CoFe2O4 NPs were between 50-80 nm by DLS. Also, the negative and positive charge of copolymer coating improves the uptake of cationic nanoparticles in cancer cells and increases the distribution of anionic nanoparticles throughout the tumor environment. The properties of CoFe2O4 and PEG-g-TMCCoFe 2O4 NPs were analyzed by TEM, DLS, XRD, IR and VSM. Conclusion: Results showed that,CoFe2O4with 12 nm were synthesized by appropriate anisotropy and coercivity instead of iron-oxide NPs with low coercivity in the same size. Also, the amino and hydroxyl groups of copolymer can be utilized as a linker for the protein and drug conjugationby covalent bonds or by weak interactions. So, this polymer nanocomposites canbe apply for selective and targeted delivery of drugs or a targeted antibody (nanobody) that recognize tumor antigens on the cancer cells in cancer and radio therapy.

Biography :

Narges Pourbagher is an MSc student of Cellular & Molecular Biology at Islamic Azad University of Iran. She is currently research assistant at Biosensor Research Center, Endocrinology and Metabolism Molecular-Cellular Sciences Institute, Tehran University of Medical Sciences, Tehran, Iran. She has experience in synthesis of magnetic NPs and the design of biosensor. Now, she is studying targeted therapy with NPs for imaging and thermal therapy.