Biomechanical behavior of MRI-signal-inducing bone cements after vertebroplasty in osteoporotic vertebral bodies: An experimental cadaver study

Abstract Background Conventional water-free polymethylmethacrylate cements are not MRI visible due to the lack of free protons. A new MRI-visible bone cement was developed through the addition of a contrast agent and either a saline solution or a hydroxyapatite (Wichlas et al., 2010). The purposes o...

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Published in:Clinical biomechanics (Bristol) 2014-05, Vol.29 (5), p.571-576
Main Authors: Wichlas, Florian, Trzenschik, Heidi, Tsitsilonis, Serafim, Rohlmann, Antonius, Bail, Hermann-Josef
Format: Article
Language:English
Subjects:
Aged
Aged, 80 and over
Biocompatibility
Biomechanical Phenomena - physiology
Biomechanics
Biomedical materials
Bone Cements - chemistry
Bone Cements - therapeutic use
Cadaver
Cementoplasty
Cements
Contrast Media
Elasticity
Female
Humans
Hydroxyapatite
Hydroxyapatites - chemistry
Hydroxyapatites - therapeutic use
Lumbar Vertebrae
Lumbosacral Region
Magnetic Resonance Imaging
MRI-guided surgery
Osteoporosis - therapy
Pathologic spinal fractures
Physical Medicine and Rehabilitation
Polymethyl Methacrylate - chemistry
Polymethyl Methacrylate - therapeutic use
Polymethylmethacrylate cement
Saline solutions
Spinal Fractures - therapy
Stiffness
Surgical implants
Vertebroplasty
Vertebroplasty - methods
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Summary:Abstract Background Conventional water-free polymethylmethacrylate cements are not MRI visible due to the lack of free protons. A new MRI-visible bone cement was developed through the addition of a contrast agent and either a saline solution or a hydroxyapatite (Wichlas et al., 2010). The purposes of the study were to examine the influence of the two MRI-signal-inducing cements on the biomechanical behavior of cadaveric osteoporotic vertebral bodies after vertebroplasty and to compare the performance of the cements with conventional polymethylmethacrylate cement. Methods Three different cements were used: standard polymethylmethacrylate cement and two modified MRI-signal-inducing cements that were mixed with either a 0.9% saline solution or a hydroxyapatite. The modulus of elasticity for the standard polymethylmethacrylate cement was 2040 MPa, and the moduli for the MRI-signal-inducing cements that were mixed with a 0.9% saline solution and a hydroxyapatite were 1477 and 1225 MPa, respectively. The lumbar vertebral bodies from nine osteoporotic spines (mean age = 87 years, range = 78–99 years) of female cadavers were examined. Three groups were formed: polymethylmethacrylate cement with saline solution ( n = 14), polymethylmethacrylate cement with hydroxyapatite ( n = 12) and polymethylmethacrylate cement ( n = 13). The vertebral bodies were biomechanically tested before and after vertebroplasty. Stiffness was chosen as the primary biomechanical parameter. Findings The vertebral body stiffness was nearly two-fold greater after vertebroplasty, and this increase was statistically significant for every group. All the groups had similar vertebral body stiffness value before and after the vertebroplasty. The UNIANOVA test for multivariate analysis of variance showed no influence of lumbar level, injected cement volume and initial vertebral body stiffness. Interpretation The elastic moduli of the cements appear to exert little influence on the biomechanical values when the cement is in the vertebral body. Based on the direct comparison with the classic polymethylmethacrylate cement, we believe that the implementation of such cements for MRI-guided vertebroplasties is feasible.
ISSN:0268-0033
1879-1271
DOI:10.1016/j.clinbiomech.2014.03.002