CT-based structural analyses of vertebral fractures with polymeric augmentation: A study of cadaveric three-level spine segments

Pathologic vertebral fractures due to metastasis can occur under normal physiologic activities, leading to pain and neurologic deficit. Prophylactic vertebroplasty is a technique used to augment vertebral strength and reduce the risk of fracture. Currently, no technique is available to objectively a...

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Bibliographic Details
Published in:Computers in biology and medicine 2021-06, Vol.133, p.104395-104395, Article 104395
Main Authors: Rezaei, Asghar, Giambini, Hugo, Miller II, Alan L., Xu, Hao, Xu, Haocheng, Li, Yong, Yaszemski, Michael J., Lu, Lichun
Format: Article
Language:English
Subjects:
Augmentation
Biomechanical Phenomena
Biomechanics of spine
Bone surgery
Cadaver
Cadavers
Compression
Computational neuroscience
Computed tomography
Defects
Female
Fracture strength
Fractures
Humans
Male
Mechanical properties
Mechanical testing
Mechanical tests
Metastases
Metastasis
Pain
Polymers
Polymethyl methacrylate
Polymethylmethacrylate
Polypropylene fumarate
Rigidity
Rigidity analysis
Segments
Software
Spinal Fractures - diagnostic imaging
Spine
Tomography, X-Ray Computed
Vertebrae
Vertebral augmentation
Vertebral fracture
Vertebroplasty
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Summary:Pathologic vertebral fractures due to metastasis can occur under normal physiologic activities, leading to pain and neurologic deficit. Prophylactic vertebroplasty is a technique used to augment vertebral strength and reduce the risk of fracture. Currently, no technique is available to objectively assess vertebral fracture risk in metastatically-involved vertebral bodies. The aim of the current study was to develop an image-based computational technique to estimate fracture force outcomes during bending. To this end, mechanical testing was performed on intact, simulated defect, PMMA-augmented, and PPF-augmented 3-level spine segments from both sexes under a compression/flexion-type loading condition. The augmentation performance of poly(methyl methacrylate) (PMMA) and poly(propylene fumarate) (PPF) were also evaluated and compared. Cylindrical defects were created in 3-level spine segments with attached posterior elements and ligaments. Using CT images of each segment, a rigidity analysis technique was developed and used for predicting fracture forces during bending. On average, PPF strengthened the segments by about 630 N, resulting in fracture forces similar to those observed in the intact and PMMA-augmented groups. Female spines fractured at about 1150 N smaller force than did male spines. Rigidity analysis, along with age, explained 66% variability in experimental outcomes. This number increased to 74% when vertebral size and age were added to the rigidity analysis as explanatory variables. Both PPF and PMMA similarly increased fracture strength to the level of intact specimens. The results suggest that PPF can be a suitable candidate for augmentation purposes and rigidity analysis can be a promising predicting tool for vertebral fracture forces. •Image-based rigidity analysis is a promising technique to predict fracture forces in augmented spine segments.•Poly(propylene fumarate) (PPF) can be a suitable candidate for augmenting metastatic vertebral bodies.•Female spines fractured at about 1150 N smaller force than did male spines.
ISSN:0010-4825
1879-0534
DOI:10.1016/j.compbiomed.2021.104395