Comparison of polyetheretherketone versus silicon nitride intervertebral spinal spacers in a caprine model

Kersten, Roel F. M. R.; Wu, Gang; Pouran, Behdad; Veen, Albert J. van der; Weinans, Harrie; Gast, Arthur de; Öner, F. Cumhur; Gaalen, Steven M. van

doi:10.1002/jbm.b.34162

Cited by 24 publications

(15 citation statements)

References 62 publications

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“…Osteogenic effects of SiN were confirmed in several in vitro tests with different cell types, such as human osteosarcoma SaOS-2 cells ( Pezzotti et al, 2016 ; Pezzotti et al, 2017b ; Zanocco et al, 2019 ), mouse bone marrow stromal cells (BMSCs) ( Pezzotti et al, 2017a ), and human BMSCs ( Amaral et al, 2002 ). The effectiveness of SiN was further confirmed in several in vivo studies using a goat lumbar interbody fusion model ( Kersten et al, 2019 ), a rat calvarial defect model ( Webster et al, 2012 ), and a murine tibial implant model ( Ishikawa et al, 2017 ). However, the brittleness and lack of resilience, common disadvantages of ceramic biomaterials, make it problematic to use SiN alone as a scaffold.…”

Section: Introductionmentioning

confidence: 74%

Silicon Nitride, a Bioceramic for Bone Tissue Engineering: A Reinforced Cryogel System With Antibiofilm and Osteogenic Effects

Lee

Laganenka

et al. 2021

Front. Bioeng. Biotechnol.

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Silicon nitride (SiN [Si3N4]) is a promising bioceramic for use in a wide variety of orthopedic applications. Over the past decades, it has been mainly used in industrial applications, such as space shuttle engines, but not in the medical field due to scarce data on the biological effects of SiN. More recently, it has been increasingly identified as an emerging material for dental and orthopedic implant applications. Although a few reports about the antibacterial properties and osteoconductivity of SiN have been published to date, there have been limited studies of SiN-based scaffolds for bone tissue engineering. Here, we developed a silicon nitride reinforced gelatin/chitosan cryogel system (SiN-GC) by loading silicon nitride microparticles into a gelatin/chitosan cryogel (GC), with the aim of producing a biomimetic scaffold with antibiofilm and osteogenic properties. In this scaffold system, the GC component provides a hydrophilic and macroporous environment for cells, while the SiN component not only provides antibacterial properties and osteoconductivity but also increases the mechanical stiffness of the scaffold. This provides enhanced mechanical support for the defect area and a better osteogenic environment. First, we analyzed the scaffold characteristics of SiN-GC with different SiN concentrations, followed by evaluation of its apatite-forming capacity in simulated body fluid and protein adsorption capacity. We further confirmed an antibiofilm effect of SiN-GC against Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus) as well as enhanced cell proliferation, mineralization, and osteogenic gene upregulation for MC3T3-E1 pre-osteoblast cells. Finally, we developed a bioreactor to culture cell-laden scaffolds under cyclic compressive loading to mimic physiological conditions and were able to demonstrate improved mineralization and osteogenesis from SiN-GC. Overall, we confirmed the antibiofilm and osteogenic effect of a silicon nitride reinforced cryogel system, and the results indicate that silicon nitride as a biomaterial system component has a promising potential to be developed further for bone tissue engineering applications.

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Section: Introductionmentioning

confidence: 74%

Silicon Nitride, a Bioceramic for Bone Tissue Engineering: A Reinforced Cryogel System With Antibiofilm and Osteogenic Effects

Lee

Laganenka

et al. 2021

Front. Bioeng. Biotechnol.

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“…In interbody fusion, another critical determinant is the new bone formation around the intervertebral fusion cage. , A bioactive material should have the capacity to stimulate biological response to realize effective osteogenesis. , The regenerative ability of the material could be improved by optimizing composition or incorporating bioactive ions that play a pivotal role in osteogenic process. In our previous study, we demonstrated that the presence of CS incorporated into PEEK could effectively release the bioactive Ca 2+ and Si 4+ ions which exerted a positive influence on the osteogenic differentiation of preosteoblasts in vitro .…”

Section: Discussionmentioning

confidence: 99%

Highly Effective Bone Fusion Induced by the Interbody Cage Made of Calcium Silicate/Polyetheretherketone in a Goat Model

Chu

Liao

et al. 2019

ACS Biomater. Sci. Eng.

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Interbody fusion surgery is often used to settle matters such as degenerative disc disease or disc herniation in clinical orthopedics. Considering the deficiencies of the current treatment methods, we developed an interbody fusion cage made of calcium silicate (CS)/polyetheretherketone (PEEK) and hoped that the bioactive cage could exhibit great fusion ability and maintain stable mechanical function. In the goat model of cervical interbody fusion, the CS/PEEK cage showed stronger interbody fusion at 12 and 26 weeks compared with pure PEEK cage based on the X-ray analysis. The micro-CT scanning and analysis indicated that the CS/PEEK cage induced more new bone ingrowth than the PEEK cage and led to nearly complete interbody fusion at 26 weeks. Moreover, the CS/PEEK group showed excellent mechanical stability and stiffness as evaluated by the spine kinematic assay at the time points. The histological assessment showed the rapid osseointegration and mineralized bone formation around the CS/PEEK cage. This study confirmed that the bioactive CS/PEEK cage is capable of inducing highly effective bone fusion and has high potential to be used in the clinics of spine surgery.

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“…New medical devices should be compared to the gold standard for their clinical performance. Kersten et al [ 73 ] compared the bone formation ability of Si 3 N 4 and PEEK in lumbar interbody fusion surgeries using a caprine model. The results demonstrated that Si 3 N 4 spacers were not inferior to PEEK in bone-implant contact (BIC) and biodynamic stability, and they were superior in promoting arthrodesis.…”

Section: Medical Application Of Si 3 Nmentioning

confidence: 99%

Silicon Nitride as a Biomedical Material: An Overview

Lee

Blugan

et al. 2022

IJMS

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Silicon nitride possesses a variety of excellent properties that can be specifically designed and manufactured for different medical applications. On the one hand, silicon nitride is known to have good mechanical properties, such as high strength and fracture toughness. On the other hand, the uniqueness of the osteogenic/antibacterial dualism of silicon nitride makes it a favorable bioceramic for implants. The surface of silicon nitride can simultaneously inhibit the proliferation of bacteria while supporting the physiological activities of eukaryotic cells and promoting the healing of bone tissue. There are hardly any biomaterials that possess all these properties concurrently. Although silicon nitride has been intensively studied as a biomedical material for years, there is a paucity of comprehensive data on its properties and medical applications. To provide a comprehensive understanding of this potential cornerstone material of the medical field, this review presents scientific and technical data on silicon nitride, including its mechanical properties, osteogenic behavior, and antibacterial capabilities. In addition, this paper highlights the current and potential medical use of silicon nitride and explains the bottlenecks that need to be addressed, as well as possible solutions.

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Comparison of polyetheretherketone versus silicon nitride intervertebral spinal spacers in a caprine model

Cited by 24 publications

References 62 publications

Silicon Nitride, a Bioceramic for Bone Tissue Engineering: A Reinforced Cryogel System With Antibiofilm and Osteogenic Effects

Silicon Nitride, a Bioceramic for Bone Tissue Engineering: A Reinforced Cryogel System With Antibiofilm and Osteogenic Effects

Highly Effective Bone Fusion Induced by the Interbody Cage Made of Calcium Silicate/Polyetheretherketone in a Goat Model

Silicon Nitride as a Biomedical Material: An Overview

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