Resumen
Los tornillos corticales son elementos utilizados en osteosíntesis para la fijación de fracturas, la estabilidad de la fijación del tornillo es principalmente el resultado del anclaje efectivo del tornillo, una mala estabilidad lleva al fracaso de la unión del hueso. Con base en las normas ASTM F543, se diseñó un herramental para la realización de pruebas de la resistencia a la extracción en tornillos corticales, esto con la finalidad de comparar diferentes tornillos médicos utilizados en osteosíntesis. Se identificaron los principales parámetros que influyen en la resistencia a la extracción de los tornillos y se diseñó un herramental para la realización de las pruebas, el cual cumple con los parámetros asignados por la norma ASTM F 543.
Palabras clave:Espuma de poliuretano, fuerza de extracción, tornillo cortical.

Abstract
Cortical screws are elements used in osteosynthesis for the fixation of fractures, the stability of the fixation of the screw is mainly the result of the effective anchoring of the screw, poor stability leads to failure of the bone union. Based on the ASTM F543 standards, a tool was designed to carry out tests of the resistance to extraction in cortical screws, in order to compare different medical screws used in osteosynthesis. The main parameters that influence the resistance to extraction of the screws were identified and a fixture was designed to carry out the tests, which complies with the parameters assigned by the ASTM F 543 standard.
Keywords:Cortical screw, pull-out force, rigid polyurethane foam.

ASTM F543-17, Standard Specification and Test Methods for Metallic Medical Bone Screws, ASTM International, West Conshohocken, PA, 2017, www.astm.org

Koistinen, A., Santavirta, S., & Lappalainen, R. (2003). Apparatus to test insertion and removal torque of bone screws. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine, 217(6), 503–508. doi:10.1243/09544110360729135.

Le Vay, D. (2008). Anatomía y fisiología humana. Editorial Paidotribo.

Lu, W. W., Zhu, Q., Holmes, A. D., Luk, K. D. K., Zhong, S., & Leong, C. Y. (2000). Loosening of sacral screw fixation under in vitro fatigue loading. Journal of Orthopaedic Research, 18(5), 808-814.

Nordin, M., & Frankel, V. H. (Eds.). (2001). Basic biomechanics of the musculoskeletal system. Lippincott Williams & Wilkins.

Öktenoǧlu, B. T., Ferrara, L. A., Andalkar, N., Özer, A. F., Sarioǧlu, A. Ç., & Benzel, E. C. (2001). Effects of hole preparation on screw pullout resistance and insertional torque: a biomechanical study. Journal of Neurosurgery: Spine, 94(1), 91-96.

Roiz Martín, S. (2017). Uso de tornillos bloqueados con tuercas de PEEK (SLEs) para acelerar la consolidación de fracturas: estudio experimental y clínico preliminar (Doctoral dissertation).

Ryken, T. C., Clausen, J. D., Traynelis, V. C., & Goel, V. K. (1995). Biomechanical analysis of bone mineral density, insertion technique, screw torque, and holding strength of anterior cervical plate screws. Journal of neurosurgery, 83(2), 324-329.

Shatzker, J., & Horne, G. (1975). The effect of compression of cortical bones by screw threads, and the effect of movement of screws in bone. Clin. Orth. Relate Res, 39, 65-78.

Thakur, A. J. (2015). Elements of Fracture Fixation-E-book. Elsevier Health Sciences.

Yerby, S. A., Scott, C. S., Evans, N. J., Messing, K. L., & Carter, D. R. (2000, March). The effect of cutting flute design on bone screw insertion and pull-out properties. In 46th Annual Meeting of the Orthopaedic Research Society, poster session, poster (Vol. 875, pp. 2000-12).