Non-Metallic Composite Materials for Bone Surgery
L. RECLARU, R. LERF, P.-Y. ESCHLER, J.-M. MEYER, Corrosion behaviour of a welded stainless-steel orthopaedic implant, Biomaterials, 22, 269–279, 2001.
K.H.KRAMER, Implants For Surgery – A Survey on Metallic Materials, Materials for Medical Engineering EUROMAT 99, 2, 9–29, 1999.
S. RAMAKRISHNA, J. MAYER, E. WINTERMANTEL, K. W. LEONG, Biomedical applications of polymer-composite based materials a review, Composites Science and Technology, 61, 1189–1224, 2001.
S.L. EYANS, P.J. GREGSON, Composite technology in load-bearing orthopaedic implants, Biomaterials, 19, 1329–1342, 1998.
J. CHŁOPEK, Carbon-carbon composites. Manufacturing and applications in medicine, Polish Ceramic Bulletin, Ceramics, 52, Kraków 1997.
F.L. MATTHEWS, R.D. RAWLINGS, Composite materials: Engineering and science, Chapman & Hall, 1993.
D.W. HUTMACHER, Scaffolds in tissue engineering bone and cartilage, Biomaterials, 21, 2529–2543, 2001.
R M. PILLIAR, M.J. FILIAGGI, J.D. WELLS, M.D. GRYNPAS, R.A. KANDEL, Porous calcium polyphosphate scaffolds for bone substitute applications in vitro characterization, Biomaterials, 22, 963–972, 2001.
E. PAMULA, M. BŁAŻEWICZ, M. CHOMYSZYN-GAJEWSKA, B. SZARANIEC, A new material for guided tissue regeneration, Biomineralogy, biotechnologies and biomaterials in medicine, PAN Prace Mineralogiczne, 89, 83–89, 2000.
J.H. KUIPER, R. HUISKES Numerical optimisation of hip-prosthetic stem material, Recent advances in: Computer methods in biomechanics and biomedical engineering, J. MIDDLETON, G. N. PANDE, K. R. WILLIAMS, [Eds.], 76–84, 1992.
L.L. HENCH, Biomaterials: a forecast for the future, Biomaterials, 19, 1419–1423, 1998.
J.C. MIDDLETON, A.J. TIPTON, Synthetic biodegradable polymers as orthopaedic devices, Biomaterials, 21, 2335–2346, 2000.
K. J. L. BURG, S. PORTER, J. F. KELLAM, Biomaterial developments for bone tissue engineering, Biomaterials, 21, 2347–2359, 2000.
M. BŁAŻEWICZ, Carbon grafts produced from polyacryloniryle in treatment of soft tissues, Polymers in Medicine, 1–2, 33–39, 2001.
M. BŁAŻEWICZ, Carbon materials in the treatment of soft and hard tissue injuries, European Cells and Materials, 2, 21–29, 2001.
A. MAJOLA. S. YAINIONPAA. P. ROKKANEN, H.M. MIKKOLA, P. TORMALA, Absorbable self-reinforced polylactide (SR-PLA) composite rods for fracture fixation, strength retention in the bone and subcutaneous tissue in rabbits, J. Mat. Sci. Met. Med. 3, 43–47, 1992.
W. SUCHANEK, M. YASHIMA, M. KAKIHANA, M. YOSHIMURA, Processing and mechanical properties of hydroxyapatite reinforced with hydroxyapatite whiskers, Biomaterials, 17, 1715–1723, 1996.
J. CHŁOPEK, Carbon-carbon composites – rules of designing of their properties, Karbo 4–5, 117–119, 2000.
W.M. KUŚ, [Ed.] Carbon biomaterials in medicine, Karniowice 1994.
J. CHŁOPEK, M. BŁAŻEWICZ, E. PAMULA, W.M. KUŚ, E. STASZKÓW, Carbon fibers-based composites for the treatment of hard tissue injuries, Proceedings of Carbon 2001 Conference, Lexington, USA, 2001.
M. BŁAŻEWICZ, A. ŚLÓSARCZYK, J. CHŁOPEK, B. SZARANIEC, Carbon-phosphate composites for bone surgery, Proceedings of Tenth International Conference on Biomedical Engineering, 221–222, 6–9 December 2000, Singapore.
B. SZARANIEC, J. CHŁOPEK, M. BŁAŻEWICZ, Variations of the mechanical properties of carbon-phosphate composites tested "in vitro", Engineering of Biomaterials 17–19, 70–72, 2001.
M.S. HUNT, Development of carbon fibre/polysulfone orthopaedic implants, Materials and Design, 8, 2, 113–119, 1987.
G. PAGANETTO, S. MAZULLO, A. DELOLLIIS, S. BUSCAROLI, M. ROCCA, M. FINI, R. GIARDINO, Poly-L-lactid acid: biointeraction and processing variable relationship, Biomaterials, 5, 2, 179–186, 1991.
J. CHŁOPEK, New materials for orthopaedic screws, Acta Montana, 10, 115, 1–11, 2000.
M. FUCHS, G. KÖSTER, T. KRAUSE, H.-A. MERTEN, A. SCHMID, Degradation of and intraosseous reactions to biodegradable poly-L-lactide screws: a study in minipigs, Arch. Orthop. Trauma Surg., 118, 140–144, 1998.
E. PAMULA, J. CHŁOPEK, M. BŁAŻEWICZ, K. MAKINEN, P. DOBRZYŃSKI, J. KASPERCZYK, M. BERO, Composite materials from a new biodegradable glycolide-lactide co-polymer for medical applications, Engineering of Biomaterials, 12, 23–28, 2000.
A. STOCH, A. BROŻEK, A. ADAMCZYK, Electrocrystallization of hydroxyapatite coatings on carbon biomaterials, Engineering of Biomaterials, 17–19, 19–20, 2001.
J. CHŁOPEK, S. BŁAŻEWICZ, E. PAMULA, M. BŁAŻEWICZ, C. WAJLER, E. STASZKÓW, Carbon and polymer composites in bone surgery, Materials for Medical Engineering EUROMAT 99, 2, 103–109, 1999.
T.Y. KUO, J.G. SKEDROS, R.D. BLOEBAUM, Comparison of human, primate and canine femora, Implications for biomaterials testing in total hip replacement, J. Biomed. Mat. Res. 40, 3, 1998.
J.H. KUIPER, R. HUISKES, Mathematical optimisation of elastic properties: applications to cementless hip stem design, J. Biomechanical Engineering, 119, 166–174, 1997.
I. KNETS, M. CIRULIS, G. ANDERSONE, Stress distribution in the bone with the implant at different healing stages, Recent advances [in:] Computer methods in biomechanics and biomedical engineering, J. MIDDLETON, G.N. PANDE, K.R. WILLIAMS [Eds.], 127–135, 1992.
F.K. CHANG, J.L. PEREZ, J.A. DAYIDSON, Stiffness and strength tailoring of hip prostheses made of advanced composite materials, J. Biomed. Mat. Res., 24, 873–899, 1990.
J. CHŁOPEK, B. DEGÓRSKA, A. STOCH, W. KMIECIŃSKI, A. BROŻEK, G. KMITA, Composite stems for dog's hip joint endoprosthesis, Engineering of Biomaterials, 10, 8–17, 2000.
A. WANG, R. LIN, V.K. POLINENI, A. ESSNER, C. STARK and J.H. DUMBLETON, Carbon fiber reinforced polyetheretherketone composite as a bearing surface for total hip replacement, Tribology International, 31, 11, 661–667, 1998.
A. STOCH, A. BROŻEK, G. KMITA, J. STOCH, W. JASTRZEBSKI, A. RAKOWSKA, Electrophoretic coating of hydroxyapatite on titanium implants, J. Molecular Structure, 596, 191–200, 2001.
W. R. LACEFIELD, Hydroxylapatite coatings, [in:] P. Ducheyene et al, Bioceramics: Materials Characteristics Versus In Vivo Behavior, 523, New York Academy of Science, New York, 73–80, 1988.
Copyright © 2014 by Institute of Fundamental Technological Research
Polish Academy of Sciences, Warsaw, Poland