Provaggi, Elena;
(2020)
Computational modelling and additive manufacturing to enhance the design process of lumbosacral interbody fusion implants.
Doctoral thesis (Ph.D), UCL (University College London).
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Abstract
Lumbosacral (L5-S1) interbody fusion is a widely applied procedure for the treatment of an array of degenerative spinal conditions, deformities and traumas. Despite the dramatical increase in spinal fusion surgeries over the past two decades, complications such as pseudoarthrosis and subsidence are still frequent. The aim of this research was to enhance the design process of fusion implants by exploring different additively manufactured (AM) and computational modelling methods. This study involved both engineering and clinical studies. First, a combined approach of fused ilament fabrication (FFF) and finite element (FE) modelling was proposed to characterise the influence of material and infill parameters on the performance of a low-density porous implant. AM polyether-ether-ketone (PEEK) was included as a candidate material for implant fabrication. Second, the influence of implant width on clinical outcomes was explored assessing biomechanical stability and subsidence following minimally invasive transforaminal lumbosacral interbody fusion (MI-TLIF). A FE model of an L5-S1 segment instrumented with different implant sizes was developed. Results indicated that the larger implant could be safely implanted without additional complications and reduced risk of subsidence. Third, a statistical shape modelling framework was implemented to a set of L5-S1 vertebral endplates to describe variability in terms of endplate shape and intervertebral alignment, by computing a mean endplate shape along with its deformation models. The results of this study showed that variation in endplate morphology is described by changes in scale, eccentricity and curvature, which can be gender- and disease-specific. As all females with spondylolisthesis fell within the same shape cluster, a pilot study was conducted to design a lumbosacral MI-TLIF implant tailored for this subgroup. Topology optimisation was implemented to increase the hollow space for bone graft material, whilst affording implant stability. This work provides the basis for future investigation of materials and population-based design as alternative solutions for lumbosacral fusion implants.
| Type: | Thesis (Doctoral) |
|---|---|
| Qualification: | Ph.D |
| Title: | Computational modelling and additive manufacturing to enhance the design process of lumbosacral interbody fusion implants |
| Event: | UCL (University College London) |
| Language: | English |
| Additional information: | Copyright © The Author 2020. Original content in this thesis is licensed under the terms of the Creative Commons Attribution 4.0 International (CC BY 4.0) Licence (https://creativecommons.org/licenses/by/4.0/). Any third-party copyright material present remains the property of its respective owner(s) and is licensed under its existing terms. Access may initially be restricted at the author’s request. |
| UCL classification: | UCL UCL > Provost and Vice Provost Offices UCL > Provost and Vice Provost Offices > School of Life and Medical Sciences UCL > Provost and Vice Provost Offices > School of Life and Medical Sciences > Faculty of Medical Sciences UCL > Provost and Vice Provost Offices > School of Life and Medical Sciences > Faculty of Medical Sciences > Div of Surgery and Interventional Sci |
| URI: | https://discovery.ucl.ac.uk/id/eprint/10108950 |
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