20Sep 2019

POLYMER USES IN TISSUE ENGINEERING.

  • Faculty of Engineering, Gharyan University, Ministry of Education ? Libya.
Crossref Cited-by Linking logo

  • Abstract
  • Keywords
  • References
  • Cite This Article as
  • Corresponding Author

The biodegradable polymer, poly(caprolactone) (PCL), was used to dip-coat silicon-stabilized resorbable calcium phosphate ceramic pellets and scaffolds implants. The PCL coatings increased in thickness on the dense ceramic pellets with the number of dipping and did not detach from the ceramic substrates during mechanical testing. The distribution of PCL in the porous scaffolds was not homogeneous, i.e. mostly located along the outer surface areas and at the interconnection of struts. The scaffolds with thick PCL coatings were handled in ways analogous to those that are used in clinical applications, such as drilling, screwing, cutting and grinding, etc.; it was found that this could be done without powdering or shattering. The compressive failure features of the thickly PCL-coated scaffolds were quite different from those of uncoated scaffolds and those with thin PCL coatings. For uncoated scaffolds or those with a thin PCL coating, the compressive strength decreased quickly from the yield point to zero after failure, but for the thick PCL-coated scaffolds, it became nearly constant strength after a quick decrease from the yield point, and started increasing towards the end of a constant strain region.

  1. Khan SN, Bostrom MPG, Lane JM, Tissue engineering in orthopedic surgery; bone growth factors, Orthopedic Clinics of North America, volume 31, number 3, (2000) 1-16.
  2. S Langstaff, et al., Resorbablebioceramics based on stabilized calcium phosphates. Part I: rational design, sample preparation and material characterization, Biomaterials 20(1999)1727-1741.
  3. S Langstaff, et al., Resorbablebioceramics based on stabilized calcium phosphates. Part II: evaluation of biological response, Biomaterials 22 (2001)135-150
  4. Q Qiu, P Vincent, B Lowenberg, M Sayer, J Davies, Bone growth on sol-gel calcium phosphate thin films in vitro, Cell Mater 3(1993)351-360.
  5. RuggeroBosco,Jeroen Van Den Beucken,SanderLeeuwenburghandJohn Jansen, Surface Engineering for Bone Implants: A Trend from Passive to Active Surfaces, Coatings 2012, 2(3), 95-119
  6. M Fabbri, GC Gelotti, A Ravaglioli, Granulates based on calcium phosphate with controlled morphology and porosity for medical applications: physico-chemical parameters and production technique, Biomaterials 6 (1994) 474-477.
  7. Hench LL, Bioceramics. J Am Ceram Soc 1998, (2005), 81:1705-1728.
  8. J. Klawitter, S.F. Hulbert, Application of porous ceramics for the attachment of load bearing orthopedic applications, J Biomed Mater Res 2(1971, (2004),161-172.
  9. Amass W, Amass A, Tigle B, A review of biodegradable polymers: uses, current developments in the synthetic and characterization of biodegradable polyesters, blends of biodegradable polymers and recent advances in biodegradation studies, Polymer International 47 (1998) 89 ? 144.
  10. Isabelle Vroman and LanTighzert, Biodegradable Poly. Mat. (Basel). (2009); 2(2): 307?344.
  11. Tampieri, G. Celloti, S. Sprio, A. Delcogliano, S. Franzese, Porosity-graded hydroxyapatite ceramics to replace natural bone, Biomaterials 22 (2001), 1265-1370.
  12. Lui Y.L., Schoenaers J., de Groot K., Bone healing in porous implants: a histological and histometrical comparative study, J. Mater. Sci.: Mater. Med., 11 (1), 2000, 711-717.
  13. Lu X.J., Flautre B., and Anselme K., Role of interconnections in porous bioceramics on bone recolonization in vitro and in vivo, J. Mater. Sci.: Mater. Med., 10 (2), 1999, 111-120.
  14. MaddalenaMastrogiacomo et al., Role of scaffold internal structure on in vivo bone formation in macroporous calcium phosphate bioceramics, Biomaterials, V. 27, Issue 17, (2006), 3230-3237
  15. Ozgur O.N., Tas A.C., Manufacture of macroporous calcium hydroxyapatite bioceramics, J. Euro. Ceram. Soc. Vol. 19,(1999), 2569-2572.
  16. NecatAltinkoo, RasitKoker, Mixture and pore volume fraction estimation in Al2O3/SiC ceramic cake using artificial neural networks, Materials and Design, V. 26, Issue 4, (2005), 305-311
  17. Hench L.L., Bioceramics: from concept to clinic, J.Amer.Ceram.Soc., 74-7,(1991),1487-1510.
  18. Heur A.H., et al., Innovative Materials Processing Strategies: A biomimetic Approch, Science, 225, (1992), 1098-1105.
  19. K Schwartzwalder, H Somers, AV Somers, US Patent 3,090,094 (1963).
  20. T, Ph.D. Thesis, Queen?s University, Kingston, Ontario, Canada, (2002).
  21. AF Tencer, V Mooney, KL Brown, PA Silva, Compressive properties of polymer coated synthetic hydroxyapatite for bone grading, J Biomed Mater Res 19,(1985),957-969.
  22. Sandra S?nchez-Salcedo, Daniel Arcos, Maria Vallet-Reg?, Upgrading Calcium Phosphate Scaffolds for Tissue Engineering Applications, Key Engineering Materials, V. 377, 19-42, (2008).
  23. Lias Brannon-Peppas, Polymer in controlled drug delivery, Biomaterials, devicelink.com/mpb/archive/97/11/003.html.
  24. Brekke JH, A rational for delivery of osteoinductive proteins, Tissue engineering, V. 2, number 2, (1996), 97 ? 114.
  25. Howard Seehderman, John M. Wozney, Delivery of bone morphogenetic proteins for orthopedic tissue regeneration, Cytokine & Growth Factor Reviews, V. 16, Issue 3, (2005), 329-345.
  26. CM Flahiff, AS Blackwell, JM Hollis, DS Feldman, Analysis of a biodegradable composite for bone healing, J Biomed Mater Res 31,(1996), 419-424.
  27. Aziz Nather and Sharnaz Aziz, Scaffolds in Bone Tissue Engineering, Bone Grafts and Bone Substitutes, (2005),357-365
  28. SR Jameela, N Suma, A Jayakrishnan, Protein release from poly(-caprolactone) microspheres prepared by melt encapsulation and solvent evaporation techniques: a comparative study, J Biomaterials Science Polymer, Ed 8,(1997), 457-466.
  29. R.Sinha, K.Bansal, R.Kaushik, R.Kumria, A.Trehan, Poly-ϵ-caprolactone microspheres and nanospheres: an overview, International Journal of Pharmaceutics, V. 278, N. 1, (2004) 1-23.
  30. Joshua R. Porter Timothy T. RuckhKetul C. Popat, Bone tissue engineering: A review in bone biomimetics and drug delivery strategies, Biotechnology Progress, https://doi.org/10.1002/btpr.246, (2009).
  31. AV Daniels, MKO Chang, KP Andrians, J Heller, Mechanical properties of biodegradable polymers and composites proposed for internal fixation of bone, J ApplBiomater 1,(1990),57-78.
  32. C. P. M. Verheyen J. R. De Wijn? C. A. Van Blitterswijk? K. De Groot, Evaluation of hydroxylapatite/poly(l‐lactide) composites: Mechanical behavior, Journal of Biomedical Materials Research, https://doi.org/10.1002/jbm.820261003, (2004).
  33. A Aushern, W Horn, Some properties of polymer-impregnated comments and concretes, J Am CeraSoc 54,(1971), 282-285.
  34. PriyaNairDu Hyun KuChul Woo LeeJung Soon ParkHun Young ParkWonMook Lee, Mechanical properties and durability of PMMA impregnated mortar, Korean Journal of Chemical Engineering ,V. 27, Issue 1, (2010), 334?339.
  35. S Salib, C Vipulanandan, Property-porosity relationships for polymer-impregnated superconducting ceramic composite, J Am Ceram Soc 73,(1990), 2323-29.
  36. AI Slutsker, VI Betekhtin, AB Sinani, Porosity of silicon carbide Ceramics, J. Science of Sintering, (2002), 143 ? 156.
  37. N Gupta, Kishore, E Woldesenbet, S Sankaran, Studies on compressive failure features in syntactic foam material, J Mater Sci 36, (2001), 4485-4491.
  38. Erwin M. Woutersona, Freddy Y.C.Boeya, XiaoHua, Shing-ChungWong, Specific properties and fracture toughness of syntactic foam: Effect of foam microstructures, Composites Science and Technology V. 65, Issues 11?12, (2005), 1840-1850.
  39. Ho SungKim, PakornPlubrai, Manufacturing and failure mechanisms of syntactic foam under compression, Composites Part A: Applied Science and Manufacturing V. 35, Issue 9, (2004), 1009-1015.

[Tawfik Taher Ajaal. (2019); POLYMER USES IN TISSUE ENGINEERING. Int. J. of Adv. Res. 7 (Sep). 1042-1051] (ISSN 2320-5407). www.journalijar.com

Tawfik
Prof.

DOI:

Article DOI: 10.21474/IJAR01/9755      
DOI URL: https://dx.doi.org/10.21474/IJAR01/9755

Download Full Paper

Download PDF No. of Downloads: 21 | No. of Views: 59