Kirk C McGilvray1, Erik I Waldorff2, Jeremiah Easley3, Howard B Seim3, Nianli Zhang2, Raymond J Linovitz2, James T Ryaby2, Christian M Puttlitz4. 1. Orthopaedic Bioengineering Research Laboratory, Department of Mechanical Engineering, Colorado State University, 1374 Campus Delivery, Fort Collins, CO 80523, USA. Electronic address: kirkmcgilvray@gmail.com. 2. Spine Fixation, Orthofix, Inc., 3451 Plano Parkway, Lewisville, TX 75056, USA. 3. Preclinical Surgical Research Laboratory (PSRL), Colorado State University Veterinary Teaching Hospital, 300 W Drake Rd, Fort Collins, CO 80525, USA. 4. Orthopaedic Bioengineering Research Laboratory, Department of Mechanical Engineering, Colorado State University, 1374 Campus Delivery, Fort Collins, CO 80523, USA.
Abstract
BACKGROUND CONTEXT: The most commonly used materials used for interbody cages are titanium metal and polymer polyetheretherketone (PEEK). Both of these materials have demonstrated good biocompatibility. A major disadvantage associated with solid titanium cages is their radiopacity, limiting the postoperative monitoring of spinal fusion via standard imaging modalities. However, PEEK is radiolucent, allowing for a temporal assessment of the fusion mass by clinicians. On the other hand, PEEK is hydrophobic, which can limit bony ingrowth. Although both PEEK and titanium have demonstrated clinical success in obtaining a solid spinal fusion, innovations are being developed to improve fusion rates and to create stronger constructs using hybrid additive manufacturing approaches by incorporating both materials into a single interbody device. PURPOSE: The purpose of this study was to examine the interbody fusion characteristic of a PEEK Titanium Composite (PTC) cage for use in lumbar fusion. STUDY DESIGN/ SETTING: Thirty-four mature female sheep underwent two-level (L2-L3 and L4-L5) interbody fusion using either a PEEK or a PTC cage (one of each per animal). Animals were sacrificed at 0, 8, 12, and 18 weeks post surgery. MATERIALS AND METHODS: Post sacrifice, each surgically treated functional spinal unit underwent non-destructive kinematic testing, microcomputed tomography scanning, and histomorphometric analyses. RESULTS: Relative to the standard PEEK cages, the PTC constructs demonstrated significant reductions in ranges of motion and a significant increase in stiffness. These biomechanical findings were reinforced by the presence of significantly more bone at the fusion site as well as ingrowth into the porous end plates. CONCLUSIONS: Overall, the results indicate that PTC interbody devices could potentially lead to a more robust intervertebral fusion relative to a standard PEEK device in a clinical setting.
BACKGROUND CONTEXT: The most commonly used materials used for interbody cages are titanium metal and polymer polyetheretherketone (PEEK). Both of these materials have demonstrated good biocompatibility. A major disadvantage associated with solid titanium cages is their radiopacity, limiting the postoperative monitoring of spinal fusion via standard imaging modalities. However, PEEK is radiolucent, allowing for a temporal assessment of the fusion mass by clinicians. On the other hand, PEEK is hydrophobic, which can limit bony ingrowth. Although both PEEK and titanium have demonstrated clinical success in obtaining a solid spinal fusion, innovations are being developed to improve fusion rates and to create stronger constructs using hybrid additive manufacturing approaches by incorporating both materials into a single interbody device. PURPOSE: The purpose of this study was to examine the interbody fusion characteristic of a PEEK Titanium Composite (PTC) cage for use in lumbar fusion. STUDY DESIGN/ SETTING: Thirty-four mature female sheep underwent two-level (L2-L3 and L4-L5) interbody fusion using either a PEEK or a PTC cage (one of each per animal). Animals were sacrificed at 0, 8, 12, and 18 weeks post surgery. MATERIALS AND METHODS: Post sacrifice, each surgically treated functional spinal unit underwent non-destructive kinematic testing, microcomputed tomography scanning, and histomorphometric analyses. RESULTS: Relative to the standard PEEK cages, the PTC constructs demonstrated significant reductions in ranges of motion and a significant increase in stiffness. These biomechanical findings were reinforced by the presence of significantly more bone at the fusion site as well as ingrowth into the porous end plates. CONCLUSIONS: Overall, the results indicate that PTC interbody devices could potentially lead to a more robust intervertebral fusion relative to a standard PEEK device in a clinical setting.
Authors: Dominik Adl Amini; Manuel Moser; Lisa Oezel; Jiaqi Zhu; Jennifer Shue; Andrew A Sama; Frank P Cammisa; Federico P Girardi; Alexander P Hughes Journal: Eur Spine J Date: 2021-10-28 Impact factor: 2.721
Authors: Ralph J Mobbs; Tajrian Amin; Kevin Phan; Darweesh Al Khawaja; Wen Jie Choy; William C H Parr; Vedran Lovric; William R Walsh Journal: J Craniovertebr Junction Spine Date: 2022-03-09
Authors: Milan Krticka; Ladislav Planka; Lucy Vojtova; Vladimir Nekuda; Premysl Stastny; Radek Sedlacek; Adam Brinek; Michaela Kavkova; Eduard Gopfert; Vera Hedvicakova; Michala Rampichova; Leos Kren; Kvetoslava Liskova; Daniel Ira; Jana Dorazilová; Tomas Suchy; Tomas Zikmund; Jozef Kaiser; David Stary; Martin Faldyna; Martin Trunec Journal: Biomedicines Date: 2021-06-25