MP-1™ Polyimide for Medical Devices: 1. Pre Clinical Studies
American Journal of Biomedical and Life Sciences
Volume 7, Issue 3, June 2019, Pages: 42-51
Received: Apr. 30, 2019;
Accepted: Jun. 12, 2019;
Published: Jul. 2, 2019
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Peter James Burn, General Orthopaedics, Royal Australasian College of Surgeons (FRACS), Christchurch, New Zealand
Alisa Buchman, Medical MAterials Technology (MMATECH) Ltd., Nahariya, Israel
Simha Sibony, Medical MAterials Technology (MMATECH) Ltd., Nahariya, Israel
Amir Oron, Orthopedics, Kaplan Medical Centre, Rehovot, Israel
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Due to constant increase in human life expectancy, more people require primary and revision total hip replacement surgeries, costing billions of US$ per year. Currently used ceramic on X-linked Polyethylene appears to be the best choice by default, but it still wears. The wear particles generated, are the major cause of osteolysis and joint failure. During 2011-14, leading orthopedic companies suffered global recalls of their MoM hip systems resulting in thousands of revision surgeries. The search continues for new and more durable materials bearing materials. Developments in medical technology have increased the demand for advanced materials due to aging population, advanced medical procedures and contagious diseases. Metals and ceramics are prevalent in the medical industry. However, the unique properties of polymeric materials exhibit potential as better replacements for conventional materials. MMATECH Ltd. has developed a new articulation liner made of a revolutionary material of the Polyimide family, MP-1™, a spin-off of the Aerospace industry. MP-1™ has proved to be biocompatible, heat-resistant, highly crosslinked, combining unusual strength, toughness, self-lubrication, excellent friction and wear durability, as well as resistance to fatigue, creep, impacts and chemicals. These properties lead to longer life span and safer articulating implanted components. MMATECH received the CE and ISO certificates for its MP-1™ Acetabular liner of hip implant based on a pilot clinical study conducted in New-Zealand with excellent 13y follow-up results. Ethical Committee approval was granted for a clinical study of 100 patients in New Zealand. The results of the first 82 surgeries follow-up demonstrated normal blood parameters, no osteolysis, and improved quality of life. The performance of MP-1™ even at 13 years is very promising and is now being applied to younger patients (~ 40 Y old) in view of the retrieval data. Part 1 of this research will summarize the pre-clinical studies while Part 2 will deal with the clinical studies.
Polyimide, Wear, Hip Replacement, Implants, Mechanical Behavior, Physical Chemical Properties, Clinical Trial, Biocompatibility
To cite this article
Peter James Burn,
MP-1™ Polyimide for Medical Devices: 1. Pre Clinical Studies, American Journal of Biomedical and Life Sciences.
Vol. 7, No. 3,
2019, pp. 42-51.
Copyright © 2019 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/
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Ebru Oral, Orhun K. Muratoglu, Highly Cross-Linked UHMWPE Doped with Vitamin E, Ultra High Molecular Weight Polyethylene in Total Joint Replacement and Medical Devices, P. 307-325 (2016).
Gulraj S. Matharu, Study finds 27% overall all-cause Pinnacle metal-on-metal THR failure rate at 10 years, Orthopedics Today, July 2017.
Dorr L. D, Long W. T. Metal-on-metal: articulations for the new millennium. Instr Course Lect 2005;54:177-82.
Dumbleton J. H, Manley M. T., Metal-on-Metal total hip replacement: what does the literature say?, J Arthroplasty 2005 Feb;20 (2):174-88.
Canadian Institute for Health Information. Canadian Joint Replacement Registry (CJRR) 2004 report: total hip and total knee replacements in Canada. Ottawa (ON): Canadian Institute for Health Information; 2004. P. 59.
Silva M, Heisel C, Schmalzried TP. Metal-on-metal total hip replacement. Clin Orthop Relat Res 2005 Jan; (430):53-61.
Visuri T. I, Pukkala E, Pulkkinen P, Paavolainen P., Cancer incidence and causes of death among total hip replacement patients: a review based on Nordic cohorts with a special emphasis on metal-on-metal bearings, Proc Inst Mech Eng, 2006 Feb;220 (2):399-407.
N. Eliaz, Corrosion of Metallic Biomaterials: A Review, Materials 12, 407-498 (2019).
S. Bsat, A. Speirs, X. Huang, Recent Trends in Newly Developed Plasma-Sprayed and Sintered Coatings for Implant Applications, J. Thermal Spray Technology, August 2016, Volume 25, Issue 6, pp 1088–1110.
S. M. Kurtz, J. N. Devine, PEEK Biomaterials in Trauma, Orthopedic, and Spinal Implants, Biomaterials, November 2007; 28 (32): 4845–4869.
Jae-Hwi Nho, Jong-Seok Park, Ui-Seoub Song, Woo-Jong Kim, and You-Sung Suh, Ceramic Head Fracture in Ceramic-on-Polyethylene Total Hip Arthroplasty, Yonsei Med J 54 (6):1550-1553, 2013.
A. Buchman, S. Sibony, G. R. Payne III, D. G. Mendes, R. G. Bryant, The Next Generation in Medical Implants, Materials World, 12 (2), 26 (2004).
S. Affatato, A. Ruggiero, S. A. Jaber, M. Merola, P. Bracco, Wear Behavior and Oxidation Effects on Different UHMWPE Acetabular Cups Using a Hip Joint Simulator, Materials (Basel). Mar; 11 (3): 433 (2018).
A. Buchman, P. J. Burn, S. Sibony, MP1™ Polyimide for Medical Devices, IPPS, 44th International conf. Jerusalem, Israel, 13 December 2015, P. 43.
K. L. Mittal, Polyimides Synthesis, Characterization, and Applications, Springer US, 2013.
S. Seal, S. Singh, E. Brisbois, Novel polymers for use in total joint arthroplasty, Advanced Mat. and Proc., Oct. 2018, P. 30-33.