Summary
Lytic spinal metastases are frequent in cancer patients and can weaken vertebrae, increasing the risk of fracture and leading to spine instability. Qualitative scoring systems are used by oncologists and orthopaedic surgeons to decide if the metastatic vertebrae need to be surgically treated. However these guidelines are not accurate for all those patients with middle-size lesions. An accurate, quantitative and mechanistic computational model would improve the prediction of the risk of fracture in these patients. However, such models need first to be validated against well-controlled expertiments in the laboratory.
METASPINE will deliver for the first time a method to comprehensively understand the effect of the properties of bone lesions on the mechanical competence of metastatic vertebrae.
In this project, lytic defects will be experimentally reproduced in the vertebrae, which will be tested under multi-axial loading conditions in order to evaluate the effect of the lesions on the displacement and strain fields distributions. A combination of state of the art in situ mechanical testing, microCT imaging and Digital Volume Correlation will be used. Simultaneously, subject specific clinical CT based finite element models of the metastatic vertebrae will be generated, validated against the experimental data, and used to simulate scenarios which cannot be reproduced experimentally.
The applicant (Dr Marco Palanca) is a research fellow in the field of experimental spine biomechanics. He will apply his experimental skills to optimise the sample preparation, and mechanical testing. Moreover, the supervision, mentoring, and training provided by the host organization (University of Sheffield, Dr Dall’Ara and Integrative Musculoskeletal Biomechanics group) on imaging and subject-specific finite element modelling will complete his profile as a bioengineer with a specialization in tumour and spine biomechanics.
METASPINE will deliver for the first time a method to comprehensively understand the effect of the properties of bone lesions on the mechanical competence of metastatic vertebrae.
In this project, lytic defects will be experimentally reproduced in the vertebrae, which will be tested under multi-axial loading conditions in order to evaluate the effect of the lesions on the displacement and strain fields distributions. A combination of state of the art in situ mechanical testing, microCT imaging and Digital Volume Correlation will be used. Simultaneously, subject specific clinical CT based finite element models of the metastatic vertebrae will be generated, validated against the experimental data, and used to simulate scenarios which cannot be reproduced experimentally.
The applicant (Dr Marco Palanca) is a research fellow in the field of experimental spine biomechanics. He will apply his experimental skills to optimise the sample preparation, and mechanical testing. Moreover, the supervision, mentoring, and training provided by the host organization (University of Sheffield, Dr Dall’Ara and Integrative Musculoskeletal Biomechanics group) on imaging and subject-specific finite element modelling will complete his profile as a bioengineer with a specialization in tumour and spine biomechanics.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/832430 |
| Start date: | 01-09-2019 |
| End date: | 31-08-2021 |
| Total budget - Public funding: | 212 933,76 Euro - 212 933,00 Euro |
Cordis data
Original description
Lytic spinal metastases are frequent in cancer patients and can weaken vertebrae, increasing the risk of fracture and leading to spine instability. Qualitative scoring systems are used by oncologists and orthopaedic surgeons to decide if the metastatic vertebrae need to be surgically treated. However these guidelines are not accurate for all those patients with middle-size lesions. An accurate, quantitative and mechanistic computational model would improve the prediction of the risk of fracture in these patients. However, such models need first to be validated against well-controlled expertiments in the laboratory.METASPINE will deliver for the first time a method to comprehensively understand the effect of the properties of bone lesions on the mechanical competence of metastatic vertebrae.
In this project, lytic defects will be experimentally reproduced in the vertebrae, which will be tested under multi-axial loading conditions in order to evaluate the effect of the lesions on the displacement and strain fields distributions. A combination of state of the art in situ mechanical testing, microCT imaging and Digital Volume Correlation will be used. Simultaneously, subject specific clinical CT based finite element models of the metastatic vertebrae will be generated, validated against the experimental data, and used to simulate scenarios which cannot be reproduced experimentally.
The applicant (Dr Marco Palanca) is a research fellow in the field of experimental spine biomechanics. He will apply his experimental skills to optimise the sample preparation, and mechanical testing. Moreover, the supervision, mentoring, and training provided by the host organization (University of Sheffield, Dr Dall’Ara and Integrative Musculoskeletal Biomechanics group) on imaging and subject-specific finite element modelling will complete his profile as a bioengineer with a specialization in tumour and spine biomechanics.
Status
CLOSEDCall topic
MSCA-IF-2018Update Date
28-04-2024
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