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Impact of surface roughness and bulk porosity on spinal interbody implants

Hannah A. Levy, Brian A. Karamian, Goutham R. Yalla, José A. Canseco, Alexander R. Vaccaro, Christopher K. Kepler

2022Journal of Biomedical Materials Research Part B Applied Biomaterials24 citationsDOI

Abstract

Spinal fusion surgeries are performed to treat a multitude of cervical and lumbar diseases that lead to pain and disability. Spinal interbody fusion involves inserting a cage between the spinal vertebrae, and is often utilized for indirect neurologic decompression, correction of spinal alignment, anterior column stability, and increased fusion rate. The long-term success of interbody fusion relies on complete osseointegration between the implant surface and vertebral end plates. Titanium (Ti)-based alloys and polyetheretherketone (PEEK) interbody cages represent the most commonly utilized materials and provide sufficient mechanics and biocompatibility to assist in fusion. However, modification to the surface and bulk characteristics of these materials has been shown to maximize osseointegration and long-term stability. Specifically, the introduction of intrinsic porosity and surface roughness has been shown to affect spinal interbody mechanics, vascularization, osteoblast attachment, and ingrowth potential. This narrative review synthesizes the mechanical, in vitro, in vivo, and clinical effects on fusion efficacy associated with introduction of porosity in Ti (neat and alloy) and PEEK intervertebral implants.

Topics & Concepts

PeekMaterials scienceOsseointegrationSpinal fusionImplantBiomedical engineeringPorosityFusionSurface roughnessTitanium alloyBiocompatibilityComposite materialMedicineSurgeryAlloyLinguisticsMetallurgyPolymerPhilosophyOrthopaedic implants and arthroplastyBone Tissue Engineering MaterialsSpine and Intervertebral Disc Pathology
Impact of surface roughness and bulk porosity on spinal interbody implants | Litcius