Amphiphilic Poly (3-Hydroxy Alkanoate)s: Potential Candidates for Medical Applications

Baki  HAZER

doi:10.4236/epe.2010.21006

Journals by Subject

Journals by Title

EPE Vol.2 No.1 , February 2010

Amphiphilic Poly (3-Hydroxy Alkanoate)s: Potential Candidates for Medical Applications

Baki HAZER

Abstract: Poly (3-hydroxy alkanoate)s, PHAs, have been very attractive as biomaterials due to their biodegradability and biocompatibility. These hydrophobic natural polyesters, PHAs, need to have hydrophilic character particularly for drug delivery systems. In this manner, poly (ethylene glycol) (PEG) and hydrophilic functional groups such as amine, hydroxyl, carboxyl and sulfonic acid have been introduced into the PHAs in order to obtain amphiphilic polymers. This review involves in the synthesis and characterization of the amphiphilic PHAs.

Keywords: poly (3-hydroxy alkanoate), PHA, amphiphilic polymer, biomaterial, chemical modification

Cite this paper: nullB. HAZER, "Amphiphilic Poly (3-Hydroxy Alkanoate)s: Potential Candidates for Medical Applications," Energy and Power Engineering, Vol. 2 No. 1, 2010, pp. 31-38. doi: 10.4236/epe.2010.21006.

References

[1] R. Langer and D. A. Tirrell, “Designing materials for biology and medicine,” Nature, No. 428, pp. 487–492, 2004.

[2] S. Mitragotri and J. Lahann, “Physical approaches to biomaterial design,” Nature Mater, No. 8, pp. 15–23, 2009.

[3] S. P. Valappil, S. K. Misra, A. R. Boccaccini, and I. Roy, “Biomedical applications of polyhydroxyalkanoates, an overview of animal testing and in vivo responses,” Expert Review of Medical Devices, No. 3, pp. 853–868, 2006.

[4] A. J. Anderson and E. A. Dawes, “Occurrence, metabolism, metabolic role, and industrial uses of bacterial polyhydroxyalkanoates,” Microbiological Reviews, No. 54, pp. 450–472, 1990.

[5] R. W. Lenz and R. H. Marchessault, “Bacterial polyesters: Biosynthesis, biodegradable plastics and biotechnology,” Biomacromolecules, No. 6, pp. 1–8, 2005.

[6] B. Hazer and A. Steinbüchel, “Increased diversification of polyhydroxyalkanoates by modification reactions for industrial and medical applications,” Applied Microbiology and Biotechnology, No. 74, pp. 1–12, 2007.

[7] K. Sudesh, H. Abe, and Y. Doi, “Synthesis, structure and properties of polyhydroxy alkanoates: Biological polyesters,” Progress in Polymer Science, No. 25, pp. 1503– 1555, 2000.

[8] A. Steinbüchel and B. Füchtenbusch, “Bacterial and other biological systems for polyester production,” Trends in Biotechnology, No. 16, pp. 419–427, 1998.

[9] D. Y. Kim, H. W. Kim, M. G. Chung, and Y. H. Rhee, “Biosynthesis, modification, and biodegradation of bac-terial medium-chain-length polyhydroxyalkanoates,” Journal of Microbiology, No. 45, pp. 87–97, 2007.

[10] R. H. Marchessault, “Polyhydroxyalkanoate (PHA) history at Syracuse University and beyond cellulose,” Cellulose, No. 16, pp. 357–359, 2009.

[11] W. Orts, G. Nobes, J. Kawada, S. Nguyen, G. Yu, and F. Ravenelle, “Poly (hydroxyalkanoates): Biorefinery polymers with a whole range of applications, the work of Robert H. Marchessault,” Canadian Journal of Chemistry, No. 86, pp. 628–640, 2008.

[12] M. Zinn, B. Witholt, and T. Egli, “Occurrence, synthesis and medical application of bacterial polyhydroxyal- kanoate,” Advanced Drug Delivery Reviews, No. 53, pp. 5–21, 2001.

[13] Q. Wu, Y. Wang, and G. Q. Chen, “Medical application of microbial biopolyesters polyhydroxyalkanoates,” Artificial Cells Blood Substitutes and Biotechnol, No. 37, pp. 1–12, 2009.

[14] K. Ruth, G. de Roo, T. Egli, and Q. Ren, “Identification of two acyl-CoA synthetases from Pseudomonas putida GPo1: One is located at the surface of polyhydroxyal- kanoates granules,” Biomacromolecules, No. 9, pp. 1652–1659, 2008.

[15] A. Steinbuchel and H. E. Valentin, “Diversity of bacterial polyhydroxyalkanoic acids,” FEMS Microbiology Letters, No. 128, pp. 219–228, 1995.

[16] S. Forster and M. Antonietti, “Amphiphilic block copolymers in structure-controlled nanomaterial hybrids,” Advanced Materials, No. 10, pp. 195–217, 1998.

[17] N. Hadjichristidis, M. Pitsikalis, S. Pispas, and H. Iatrou, “Polymers with complex architecture by living anionic polymerization,” Chemical Reviews, No. 101, pp. 3747– 3792, 2001.

[18] K. J. Townsend, K. Busse, J. Kressler, and C. Scholz, “Contact angle, WAXS, and SAXS analysis of poly (3-hydroxybutyrate) and poly (ethylene glycol) block copolymers obtained via azotobacter vinelandii UWD,” Biotechnology Progress, No. 21, pp. 959–964, 2005.

[19] L. J. R. Foster, “Biosynthesis, properties and potential of natural–synthetic hybrids of polyhydroxyalkanoates and polyethylene glycols,” Applied Microbiology and Bio- technology, No. 75, pp. 1241–1247, 2007.

[20] B. Hazer, “Chemical modification of synthetic and biosynthetic polyesters,” in Biopolymers (Editor: A. Steinbuchel), Vol. 10, Chapter 6, pp. 181–208, Wiley- VCH, Weinheim, 2003.

[21] (a) S. Ilter, B. Hazer, M. Borcakli, and O. Atici, “Graft copolymerisation of methyl methacrylate onto a bacterial polyester containing unsaturated side chains,” Macro- molecular Chemistry and Physics, No. 202, pp. 2281– 2286, 2001.

[22] F. Ravenelle and R. H. Marchessault, “One-step synthesis of amphiphilic diblock copolymers from bacterial poly ([R]-3-hydroxybutyric acid),” Biomacromolecules, No. 3, pp. 1057–1064, 2002.

[23] T. D. Hirt, P. Neuenschwander, and U. W. Suter, “Telechelic diols from poly [(R)-3-hydroxybutyric acid] and poly ([(R)-3-hydroxybutyricacid]-co-[(R)-3-hydro- xyvalericacid],” Macromolecular Chemistry and Physics, No. 197, pp. 1609–1614, 1996.

[24] (a) G. R. Saad, “Calorimetric and dielectric study of the segmented biodegradable poly (ester-urethane)s based on bacterial poly [(R)-3-hydroxybutyrate],” Macromolecular Bioscience, No. 1, pp. 387–396, 2001.

[25] H. Erduranli, B. Hazer, and M. Borcakl?, “Post polymerization of saturated and unsaturated poly (3-hy- droxy alkanoate)s,” Macromolecular Symposia, No. 269, pp. 161–169, 2008.

[26] (a) B. Hazer, O. Torul, M. Borcakli, R. W. Lenz, R. C. Fuller, and S. D. Goodwin, “Bacterial production of polyesters from free fatty acids obtained from natural oils by Pseudomonas Oleovorans,” Journal of Environmental Polymer Degradation, No. 6, pp. 109–113, 1998.

[27] M. Y. Lee, W. H. Park, and R. W. Lenz, “Hydrophilic bacterial polyesters modified with pendant hydroxyl groups,” Polymer, No. 41, pp. 703–1709, 2000.

[28] M. Y. Lee and W. H. Park, “Preparation of bacterial copolyesters with improvedhydrophilicity by carboxy- lation,” Macromolecular Chemistry and Physics, No. 201, pp. 2771–2774, 2000.

[29] D. J. Stigers and G. N. Tew, “Poly (3-hydroxyalkanoate)s functionalized with carboxylic acid Groups in the side chain,” Biomacromolecules, No. 4, pp. 193–195, 2003.

[30] (a) M. S. Eroglu, B. Hazer, T. Ozturk, and T. Caykara, “Hydroxylation of pendant vinyl groups of poly (3-hydroxy undec-10-enoate) in high yield,” Journal of Applied Polymer Science, No. 97, pp. 2132–2139, 2005.

[31] D. M. Zhang, F. Z. Cui, Z. S. Luo, Y. B. Lin, K. Zhao, and G. Q. Chen, “Wettability improvement of bacterial polyhydroxyalkanoates via ion implantation,” Surface and Coatings Technology, No. 131, pp. 350–354, 2000.

[32] M. Bear, M. Leboucher-Durand, V. Langlois, R. W. Lenz, S. Goodwin, and P. Guerin, “Bacterial poly-3-hydro- xyalkenoates with epoxy groups in the side chains,” Reactive and Functional Polymers, No. 34, pp. 65–77, 1997.

[33] M. Y. Lee, S. Y. Cha, and W. H. Park, “Crosslinking of microbial copolyesters with pendant epoxide groups by daimine,” Polymer, No. 40, pp. 3787–3793, 1999.

[34] J. Sparks and C. Scholz, “Synthesis and Characterization of a Cationic Poly (-hydroxyalkanoate),” Biomacromo- lecules, No. 9, pp. 2091–2096, 2008.

[35] A. H. Arkin, B. Hazer, and M. Borcakli, “Chlorination of poly-3-hydroxy alkanoates containing unsaturated side chains,” Macromolecules, No. 33, pp. 3219–3223, 2000.

[36] A. H. Arkin and B. Hazer, “Chemical modification of chlorinated microbial polyesters,” Biomacromolecules, No. 3, pp. 1327–1335, 2002.

[37] (a) G. Yu, F. G. Morin, G. A. R. Nobes, and R. H. Marchessault, “Degree of acetylation of chitin and extent of grafting PHB on chitosan determined by solid state 15N NMR,” Macromolecules, No. 32, pp. 518–520, 1999.

[38] S. Muthukrishnan, G. Jutz, X. Andre′, H. Mori, and A. H. E. Müller, “Synthesis of hyperbranched glycopolymers via self-condensing atom transfer radical copolymeri- zation of a sugar-carrying acrylate,” Macromolecules, No. 38, pp. 9–18, 2005.

[39] M. Constantin, C. I. Simionescu, A. Carpov, E. Samain, and H. Driguez, “Chemical modification of poly (hydro- xyalkanoates), copolymers bearing pendant sugars,” Macromolecular Rapid Communications, No. 20, pp. 91–94, 1999.

[40] Y. B. Kim, R. W. Lenz, and R. C. Fuller, “Poly (β- hydroxyalkanoate) copolymers containing brominated repeating units produced by Pseudomonas oleovorans,” Macromolecules, No. 25, pp. 1852–1857, 1992.

[41] B. Hazer, R. W. Lenz, B. Cakmakli, M. Borcakli, and H. Kocer, “Preparation of poly (ethylene glycol) grafted poly (3-hydroxyalkanoate)s,” Macromolecular Chemistry and Physics, No. 200, pp. 1903–1907, 1999.

[42] (a) B. Hazer, “Poly (β- hydroxy nonanoate) and poly- styrene or poly (methyl methacrylate) graft copolymers: Microstructure characteristics and mechanical and ther- mal behavior,” Macromolecular Chemistry and Physics, No. 197, pp. 431–441, 1996.

[43] (a) H. W. Kim, C. W. Chung, and Y. H. Rhee, “UV-induced graft copolymerization of monoacrylate- poly(ethylene glycol) onto poly(3-hydroxyoctanoate) to reduce protein adsorption and platelet adhesion,” International Journal of Biological Macromolecules, No. 35, pp. 47–53, 2005.

[44] H. W. Kim, M. G. Chung, Y. B. Kim, and Y. H. Rhee, “Graft copolymerization of glycerol 1,3-diglycerolate diacrylate onto poly(3-hydroxyoctanoate) to improve physical properties and biocompatibility,” International Journal of Biological Macromolecules, No. 43, pp. 307– 313, 2008.

[45] S. Domenek, V. Langlois, and E. Renard, “Bacterial polyesters grafted with poly (ethylene glycol): Behaviour in aqueous media,” Polymer Degradation and Stability, No. 92, pp. 1384–1392, 2007.