Métodos de análisis del polietileno en la investigación del material y su aplicación en artroplastias | Revista Española de Cirugía Ortopédica y Traumatología

Información del artículo

Introducción

El polietileno de ultra-alto peso molecular (UHMWPE) es el material más utilizado como interposición en la mayoría de los sistemas de artroplastia total. Su desgaste y fractura propició gran controversia durante los últimos años, por lo que los centros de investigación y la industria profundizaron en su análisis a la búsqueda de mecanismos de fallo y mejoras del material.

Revisión de la bibliografía

En la revisión presentada, se han recogido diferentes técnicas para caracterizar mejor el polietileno utilizado en implantes ortopédicos. En los diferentes grupos de técnicas, algunas ofrecen datos más básicos y generales, mientras otras, las experimentales, son fases terminales de un estudio concreto, previos al ensayo clínico. Lógicamente, el diseño de un estudio de investigación requiere precisar unos objetivos y situar las técnicas más apropiadas para verificar si existen o no las diferencias que plantea la hipótesis.

Conclusiones

Se presentan los análisis utilizados para progresar en el conocimiento del polietileno utilizado en cirugía ortopédica. Esta visión también puede servir para que la propuesta de nuevos materiales tenga una investigación sistemática, evitando las aproximaciones ensayo-error que, si bien han permitido grandes avances en el pasado, hoy serían difícilmente aceptables.

Palabras clave:

polietileno

artroplastias

desgaste

biomateriales

Introduction

Ultra-high molecular weight polyethylene (UHMWPE) is the most common bearing material used in joint replacement systems. Its wear and fracture have given rise to controversy in the past, motivating research and industrial centers to carry out a thorough analysis of the material in search of failure mechanisms and ways to improve the material.

Literature review

Different techniques for characterizing the polyethylene used in orthopedic implants are reviewed. Among the different groups of techniques, some obtain more basic and general data while more experimental techniques obtain information in the final stage of specific studies preceding the clinical trial. Logically, the design of a research study requires the establishment of objectives and the use of the most appropriate techniques for verifying whether the differences proposed by the hypothesis exist or not.

Conclusions

The analyses used to advance our understanding of the polyethylene used in Orthopedic Surgery are presented. This approach is also useful for the systematic investigation of new materials, avoiding trial and error approaches that, although they made major advances possible in the past, would now be unacceptable.

Key words:

polyethylene

arthroplasties

wear

biomaterials

El Texto completo está disponible en PDF

Bibliografía

[1.]

E. Gómez-Barrena, J.D. Chang, S. Li, C.M. Rimnac, E.A. Salvati.

The role of polyethylene properties in osteolysis after total hip replacement.

Instr Course Lect, 45 (1996), pp. 187-197

Medline

[2.]

S.M. Kurtz, O.K. Muratoglu, M. Evans, A.A. Edidin.

Advances in the processing, sterilization, and crosslinking of ultra-high molecula weight polyethylene for total joint arthroplasty.

Biomaterials, 20 (1999), pp. 1659-1688

Medline

[3.]

www.uhmwpe.org (30/09/03)

[4.]

A.S. Shanbhag, F.S. Pettit, J.C. Rendón, T.C. Doehring, K. Xu, H.E. Rubash, et al.

Analysis of the ultrastructure of UHMWPE utilizing the atomic force microscope.

Trans Orthop Res Soc, 21 (1996), pp. 494

[5.]

A.M. Gillis, B.D. Furman, S. Li.

Influence of UHMWPE resin type and manufacturing method on real time oxidation.

Trans Orthop Res Soc, 23 (1998), pp. 60

[6.]

O.K. Muratoglu, D.O. O'Connor, C.R. Bragdon, J. Delaney, M. Jasty, W.H. Harris, et al.

Gradient crosslinking of UHMWPE using irradiation in molten state for total joint arthroplasty.

Biomaterials, 23 (2002), pp. 717-724

Medline

[7.]

J.P. Collier, D.K. Sperling, J.H. Currier, L.C. Sutula, K.A. Saum, M.B. Mayor.

Impact of gamma sterilization on clinical performance of polyethylene in the knee.

J Arthropl, 11 (1996), pp. 377-389

[8.]

S. Li, J.D. Chang, E.G. Barrena, B.D. Furman, T.M. Wright, E.A. Salvati.

Non-consolidated polyethylene particles and oxidation in Charnley acetabular cups.

Clin Orthop, 319 (1995), pp. 54-63

Medline

[9.]

E. Gómez-Barrena, S. Li, B.S. Furman, B.A. Masri, T.M. Wright, E.A. Salvati.

Role of polyethylene oxidation and consolidation defects in cup performance.

Clin Orthop, 352 (1998), pp. 105-117

Medline

[10.]

F. Medel, E. Gómez-Barrena, F. García-Álvarez, J.A. Puértolas.

Ultrastructural effects of irradiation and aging on UHMWPE.

13rd Annual Meeting EORS, (2003),

[11.]

J.A. Puértolas, A. Larrea, E. Gómez-Barrena.

Fracture behavior of UHMWPE in non-implanted, shelf aged knee prostheses after gamma irradiation in air.

Biomaterials, 22 (2001), pp. 2107-2114

Medline

[12.]

Medel F, Gómez-Barrena E, García-Álvarez F, Ríos R, Gracia-Villa L, Puértolas JA. Fractography evolution in UHMWPE accelerated aging after gamma irradiation in air [en prensa]. Biomaterials.

[13.]

B. Wunderlich, C.M. Cormier.

Heat of fusion of polyethylene.

J Polymer Sci Part A, 25 (1967), pp. 987-988

[14.]

A.S. Shanbhag, C. Mevellec, H.E. Rubash, F.S. Pettit.

Origins of submicron UHMWPE wear debris.

Trans Orthop Res Soc, 22 (1997), pp. 118

[15.]

C.M. Rimnac, R.W. Klein, F. Betts, T.M. Wright.

Postirradiation aging of UHMWPE.

J Bone Joint Surg Am, 76A (1994), pp. 1052-1056

[16.]

L. Costa, M.P. Luda, L. Trossarelli, E.M. Brach del Prever, M. Crova, P. Gallinaro.

Oxidation in orthopaedic UHMWPE sterilized by gamma-radiation and ethylene oxide.

Biomaterials, 19 (1998), pp. 659-668

Medline

[17.]

Urriés I, Medel FJ, Ríos R, Gómez-Barrena E, Puértolas JA. Comparative fatigue resistance study of electron beam and gamma irradiated UHMWPE [en prensa]. J Biomed Mater Res.

[18.]

S.M. Kurtz, J.R. Foulds, C.W. Jewett, S. Srivastav, A.A. Edidin.

Validation of a small punch testing technique to characterize the mechanical behavior of UHMWPE.

Biomaterials, 18 (1997), pp. 1659-1663

Medline

[19.]

M.L. Villarraga, S.M. Kurtz, M.P. Herr, A.A. Edidin.

Multiaxial fatigue behavior of conventional and highly crosslinked UHMWPE during cyclic small punch testing.

J Biomed Mater Res, 66A (2003), pp. 298-309

[20.]

H. McKellop, F.W. Shen, B. Lu, P. Campbell, R. Salovey.

Effect of sterilization method and other modifications on the wear resistance of acetabular cups made of ultra-high molecular weight polyethylene. A hip-simulator study.

J Bone Joint Surg Am, 82A (2000), pp. 1708-1725

[21.]

Y.S. Liao, H. McKellop, Z. Lu, P. Campbell, P. Benya.

The effect of frictional heating and forced cooling on the serum lubricant and wear of UHMW polyethylene cups against cobalt-chromium and zirconia balls.

Biomaterials, 24 (2003), pp. 3047-3059

Medline

Indexada en:

Síguenos:

Indexada en:

Síguenos:

Suscríbase a la newsletter