Abstract

The rapid development in polymer chemistry has, in recent years, led to the introduction of polymeric materials in the field of medicine. Two major groups of polymers are used for medical applications: prosthetic and biologically active materials. We synthesized copolymers with the main chain consisting of poly (methyl methacrylate) and graft chains of poly(ethylene glycol) (COP GRAFT). Changes were made in the graft copolymer chains for a possible incorporation of a drug, such that it may be used for the controlled release of drugs. The synthesis of these new compounds is based on two synthetic routes and FTIR, differential scanning calorimetry (DSC), thermogravimetry (TGA) and X-ray diffraction (XRD) characterized the products formed at the end of each stage. Through FTIR we observed absorption bands characteristic of P-H, P=O and P-O bonds that were inserted into the polymer chain during phosphorylation of the COP GRAFT, beyond the absorption bands characteristic of the copolymer before phosphorylation, such as C=O and C-O. By TGA and DSC we observed that only the diisobutyl copolymer has endothermic transition temperature and degradation behavior consistent with a polymer. XRD results showed a structural and conformational change in crystallinity of modified chains. Molecular weight and polydispersity of COPGRAFT obtained by GPC increased after phosphorylation with diisobutyl group. The phosphorylation reaction was efficient in obtaining diisobutyl copolymer and the applied techniques confirmed the modification of the COPGRAFT chains.

Keywords:
synthesis and modification of copolymer; phosphorylation; characterization by FTIR; DSC; TGA; XRD and GPC