Biomechanics of low-modulus and standard acrylic bone cements in simulated vertebroplasty: A human ex vivo study

Ondrej Holub; Alejandro López; Vishal Borse; Håkan Engqvist; Nik Kapur; Richard M. Hall; Cecilia Persson

doi:10.1016/j.jbiomech.2015.06.026

Biomechanics of low-modulus and standard acrylic bone cements in simulated vertebroplasty: A human ex vivo study

Ondrej Holub, Alejandro López, Vishal Borse, Håkan Engqvist, Nik Kapur, Richard M. Hall, Cecilia Persson^*

^*Corresponding author for this work

Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

The high stiffness of bone cements used in vertebroplasty has been hypothesised to contribute to the propensity of adjacent vertebral fractures after treatment. Therefore, new low-modulus cements have been developed; however, there are currently no studies assessing the biomechanical aspects of vertebroplasty with these cements in an ex vivo non-prophylactic model. In this study, we induced wedge fractures through eccentric uniaxial compression to single whole-vertebrae, before and after augmentation with either standard or low-modulus cement. Compressive strength and stiffness of individual vertebrae were measured, on 19 samples from metastatic spines and 20 samples from elderly, osteopenic spines. While both cement types increased the strength of both the metastatic (+34% and +63% for standard and low-modulus cement, respectively) and the elderly vertebrae (+303% and +113%, respectively), none of them restored the initial stiffness of metastatic specimens (-51% and -46%, respectively). Furthermore, low-modulus cement gave a lower total stiffness (-13%) of elderly specimens whereas standard cement increased it above initial levels (+17%). Results show that vertebroplasty with low-modulus cement could provide restoration of the initial stiffness while increasing the strength of fractured elderly vertebrae and hence represent a treatment modality which is closer to pre-augmented behaviour. Also, this study indicates that stiffness-modified cement needs to be optimised for patient/pathology specific treatment.

Original language	English
Article number	7265
Pages (from-to)	3258-3266
Number of pages	9
Journal	Journal of Biomechanics
Volume	48
Issue number	12
DOIs	https://doi.org/10.1016/j.jbiomech.2015.06.026
Publication status	Published - 18 Sept 2015

Bibliographical note

Funding Information:
This work was part funded by the European Union within the projects SPINEFX-ITN and SpineGO-ERG under the FP7 Marie Curie Action (Grant agreements no. PITN-GA-2009-238690-SPINEFX and SpineGO FP7-PEOPLE-2010-268134 ), and VINNOVA ( VINNMER 2010-02073 ).

Publisher Copyright:
© 2015 Elsevier Ltd.

Keywords

Adjacent vertebral fracture
Compression fracture
Low-modulus cement
Metastasis
Osteoporosis
Vertebroplasty

ASJC Scopus subject areas

Biophysics
Biomedical Engineering
Orthopedics and Sports Medicine
Rehabilitation

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10.1016/j.jbiomech.2015.06.026

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title = "Biomechanics of low-modulus and standard acrylic bone cements in simulated vertebroplasty: A human ex vivo study",

abstract = "The high stiffness of bone cements used in vertebroplasty has been hypothesised to contribute to the propensity of adjacent vertebral fractures after treatment. Therefore, new low-modulus cements have been developed; however, there are currently no studies assessing the biomechanical aspects of vertebroplasty with these cements in an ex vivo non-prophylactic model. In this study, we induced wedge fractures through eccentric uniaxial compression to single whole-vertebrae, before and after augmentation with either standard or low-modulus cement. Compressive strength and stiffness of individual vertebrae were measured, on 19 samples from metastatic spines and 20 samples from elderly, osteopenic spines. While both cement types increased the strength of both the metastatic (+34% and +63% for standard and low-modulus cement, respectively) and the elderly vertebrae (+303% and +113%, respectively), none of them restored the initial stiffness of metastatic specimens (-51% and -46%, respectively). Furthermore, low-modulus cement gave a lower total stiffness (-13%) of elderly specimens whereas standard cement increased it above initial levels (+17%). Results show that vertebroplasty with low-modulus cement could provide restoration of the initial stiffness while increasing the strength of fractured elderly vertebrae and hence represent a treatment modality which is closer to pre-augmented behaviour. Also, this study indicates that stiffness-modified cement needs to be optimised for patient/pathology specific treatment.",

keywords = "Adjacent vertebral fracture, Compression fracture, Low-modulus cement, Metastasis, Osteoporosis, Vertebroplasty",

author = "Ondrej Holub and Alejandro L{\'o}pez and Vishal Borse and H{\aa}kan Engqvist and Nik Kapur and Hall, {Richard M.} and Cecilia Persson",

note = "Funding Information: This work was part funded by the European Union within the projects SPINEFX-ITN and SpineGO-ERG under the FP7 Marie Curie Action (Grant agreements no. PITN-GA-2009-238690-SPINEFX and SpineGO FP7-PEOPLE-2010-268134 ), and VINNOVA ( VINNMER 2010-02073 ). Publisher Copyright: {\textcopyright} 2015 Elsevier Ltd.",

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AU - Borse, Vishal

AU - Engqvist, Håkan

AU - Kapur, Nik

AU - Hall, Richard M.

AU - Persson, Cecilia

N1 - Funding Information: This work was part funded by the European Union within the projects SPINEFX-ITN and SpineGO-ERG under the FP7 Marie Curie Action (Grant agreements no. PITN-GA-2009-238690-SPINEFX and SpineGO FP7-PEOPLE-2010-268134 ), and VINNOVA ( VINNMER 2010-02073 ). Publisher Copyright: © 2015 Elsevier Ltd.

PY - 2015/9/18

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N2 - The high stiffness of bone cements used in vertebroplasty has been hypothesised to contribute to the propensity of adjacent vertebral fractures after treatment. Therefore, new low-modulus cements have been developed; however, there are currently no studies assessing the biomechanical aspects of vertebroplasty with these cements in an ex vivo non-prophylactic model. In this study, we induced wedge fractures through eccentric uniaxial compression to single whole-vertebrae, before and after augmentation with either standard or low-modulus cement. Compressive strength and stiffness of individual vertebrae were measured, on 19 samples from metastatic spines and 20 samples from elderly, osteopenic spines. While both cement types increased the strength of both the metastatic (+34% and +63% for standard and low-modulus cement, respectively) and the elderly vertebrae (+303% and +113%, respectively), none of them restored the initial stiffness of metastatic specimens (-51% and -46%, respectively). Furthermore, low-modulus cement gave a lower total stiffness (-13%) of elderly specimens whereas standard cement increased it above initial levels (+17%). Results show that vertebroplasty with low-modulus cement could provide restoration of the initial stiffness while increasing the strength of fractured elderly vertebrae and hence represent a treatment modality which is closer to pre-augmented behaviour. Also, this study indicates that stiffness-modified cement needs to be optimised for patient/pathology specific treatment.

AB - The high stiffness of bone cements used in vertebroplasty has been hypothesised to contribute to the propensity of adjacent vertebral fractures after treatment. Therefore, new low-modulus cements have been developed; however, there are currently no studies assessing the biomechanical aspects of vertebroplasty with these cements in an ex vivo non-prophylactic model. In this study, we induced wedge fractures through eccentric uniaxial compression to single whole-vertebrae, before and after augmentation with either standard or low-modulus cement. Compressive strength and stiffness of individual vertebrae were measured, on 19 samples from metastatic spines and 20 samples from elderly, osteopenic spines. While both cement types increased the strength of both the metastatic (+34% and +63% for standard and low-modulus cement, respectively) and the elderly vertebrae (+303% and +113%, respectively), none of them restored the initial stiffness of metastatic specimens (-51% and -46%, respectively). Furthermore, low-modulus cement gave a lower total stiffness (-13%) of elderly specimens whereas standard cement increased it above initial levels (+17%). Results show that vertebroplasty with low-modulus cement could provide restoration of the initial stiffness while increasing the strength of fractured elderly vertebrae and hence represent a treatment modality which is closer to pre-augmented behaviour. Also, this study indicates that stiffness-modified cement needs to be optimised for patient/pathology specific treatment.

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Biomechanics of low-modulus and standard acrylic bone cements in simulated vertebroplasty: A human ex vivo study

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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