Amorphous and crystalline polyetheretherketone: Mechanical properties and tissue reactions during a 3‐year follow‐up

Nieminen, Tuomo; Kallela, Ilkka; Wuolijoki, Erkki; Kainulainen, Heikki; Hiidenheimo, Ilmari; Rantala, Immo

doi:10.1002/jbm.a.31310

Cited by 102 publications

(82 citation statements)

References 13 publications

(25 reference statements)

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“…Interest in improving PEEK's osseointegration has accelerated in recent years after numerous reports have described its inability in smooth form to facilitate bone apposition [9,23,25,34,51]. Reasons why this interest persists (as opposed to abandoning PEEK altogether) are often attributed to the other qualities of PEEK that make it favorable in orthopaedic and spinal applications, mainly its radiolucency, MRI compatibility, high strength, and fatigue resistance.…”

Section: Discussionmentioning

confidence: 99%

“…However, attributable in part to PEEK's relatively inert and hydrophobic surface, recent evidence has demonstrated that smooth PEEK can exhibit poor osseointegration [9,25] and fibrous capsule formation around the implant [23,34]. Lack of bone-implant contact can induce micromotion and inflammation that leads to fibrous layer thickening, osteolysis, and implant loosening [2,13,29,37,48].…”

Section: Introductionmentioning

confidence: 99%

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Do Surface Porosity and Pore Size Influence Mechanical Properties and Cellular Response to PEEK?

Torstrick

Evans

Stevens

et al. 2016

Clinical Orthopaedics &Amp; Related Research

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Background Despite its widespread use in orthopaedic implants such as soft tissue fasteners and spinal intervertebral implants, polyetheretherketone (PEEK) often suffers from poor osseointegration. Introducing porosity can overcome this limitation by encouraging bone ingrowth; however, the corresponding decrease in implant strength can potentially reduce the implant's ability to bear physiologic loads. We have previously shown, using a single pore size, that limiting porosity to the surface of PEEK implants preserves strength while supporting in vivo osseointegration. However, additional work is needed to investigate the effect of pore size on both the mechanical properties and cellular response to PEEK. Questions/purposes (1) Can surface porous PEEK (PEEK-SP) microstructure be reliably controlled? (2) What is the effect of pore size on the mechanical properties of PEEK-SP? (3) Do surface porosity and pore size influence the cellular response to PEEK? Methods PEEK-SP was created by extruding PEEK through NaCl crystals of three controlled ranges: 200 to 312, 312 to 425, and 425 to 508 lm. Micro-CT was used to characterize the microstructure of PEEK-SP. Tensile, fatigue, and interfacial shear tests were performed to compare the mechanical properties of PEEK-SP with injectionmolded PEEK (PEEK-IM). The cellular response to PEEK-SP, assessed by proliferation, alkaline phosphatase activity, vascular endothelial growth factor production, and calcium content of osteoblast, mesenchymal stem cell, and preosteoblast (MC3T3-E1) cultures, was compared with that of machined smooth PEEK and Ti6Al4V. Results Micro-CT analysis showed that PEEK-SP layers possessed pores that were 284 ± 35 lm, 341 ± 49 lm, and 416 ± 54 lm for each pore size group. Porosity and

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Do Surface Porosity and Pore Size Influence Mechanical Properties and Cellular Response to PEEK?

Torstrick

Evans

Stevens

et al. 2016

Clinical Orthopaedics &Amp; Related Research

View full text Add to dashboard Cite

show abstract

“…In addition to its excellent mechanical properties, PEEK is chemically inert and resistant to sterilization. [1][2][3][4][5][6][7][8] These features may be of great advantage for a biomaterial. PEEK has been used in orthopedic applications for decades and in the late 1990s, became widely used as a substitute for metal implants in spinal surgery.…”

Section: Introductionmentioning

confidence: 99%

Biomechanical evaluation and surface characterization of a nano-modified surface on PEEK implants: a study in the rabbit tibia

Johansson¹,

Jimbo²,

Kjellin³

et al. 2014

IJN

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Polyether ether ketone (PEEK) is today frequently used as a biomaterial in different medical operations due to its excellent mechanical and chemical properties. However, the untreated surface of PEEK is bioinert and hydrophobic, and it does not osseointegrate in its pure form. The aim of this study was to evaluate a unique nano-modified surface of PEEK with respect to osseointegration. Forty-eight threaded, non-cutting PEEK implants were inserted bilaterally in the tibia of 24 rabbits. Half of the implants (n=24) were coated with nanocrystalline hydroxyapatite (test) and the remaining implants (n=24) were left uncoated (control). Half of the animals (n=12) were euthanized after 3 weeks of healing and the remaining (n=12) after 12 weeks. The implant retention was measured with a removal torque apparatus. Surface analysis was performed with interferometry, scanning electron microscopy, and X-ray photon spectroscopy to relate the removal torque to the applied surface. The test implants revealed a significantly higher retention after 3 weeks ( P =0.05) and 12 weeks ( P =0.028) compared to controls. The result of the present study proves that the addition of nanocrystalline hydroxyapatite coating to PEEK surfaces significantly increases its removal torque and biocompatibility.

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“…Conrad et al [26] demonstrated that this increased mould temperature may also increase the compressive modulus, yield strength and strain of the traditional PEEK/HA composites. Working temperatures greater than 380℃ have been shown to reduce crystallinity, which is known to be beneficial for ductility and toughness [27,28] , with no adverse effect on biocompatibility in vivo [27] . Given the positive effects described on both shear viscosity and mechanical properties of the resulting PEEK samples, a mould temperature of 400℃ was selected for this study.…”

Section: Resultsmentioning

confidence: 99%

A novel bioactive PEEK/HA composite with controlled 3D interconnected HA network

Vaezi¹,

Yang²

2024

IJB

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Polyetheretherketone (PEEK) is a high-performance thermoplastic biomaterial which is currently used in a variety of biomedical orthopaedic applications. It has comparable tensile and compressive strength to cortical bone with favourable biocompatibility. However, natural grade PEEK-OPTIMA has shown insufficient bioactivity and limited bone integration. Bioactive PEEK composites (e.g., PEEK/calcium phosphates or Bioglass) and porous PEEK have been used to improve bone-implant interface of PEEK-based devices, but the bioactive phase distribution or porosity control is poor. In this paper, a novel method is developed to fabricate a bioactive PEEK/hydroxyapatite (PEEK/HA) composite with a unique configuration in which the HA (bioactive phase) distribution is computer-controlled within a PEEK matrix. This novel process results in complete interconnectivity of the HA network within a composite material, representing a superior advantage over alternative forms of product. The technique combines extrusion freeforming, a type of additive manufacturing (AM), and compression moulding. Compression moulding parameters, including pressure, temperature, dwelling time, and loading method together with HA microstructure were optimized by experimentation for successful biocomposite production. PEEK/HA composites with a range of HA were produced using static pressure loading to minimise air entrapment within PEEK matrix. In addition, the technique can also be employed to produce porous PEEK structures with controlled pore size and distribution.

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Amorphous and crystalline polyetheretherketone: Mechanical properties and tissue reactions during a 3‐year follow‐up

Cited by 102 publications

References 13 publications

Do Surface Porosity and Pore Size Influence Mechanical Properties and Cellular Response to PEEK?

Do Surface Porosity and Pore Size Influence Mechanical Properties and Cellular Response to PEEK?

Biomechanical evaluation and surface characterization of a nano-modified surface on PEEK implants: a study in the rabbit tibia

A novel bioactive PEEK/HA composite with controlled 3D interconnected HA network

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