A biomechanical study of periacetabular defects and cement filling

A biomechanical study of periacetabular defects and cement filling

Periacetabular bone metastases cause severe pain and functional disability in cancer patients. Percutaneous acetabuloplasty (PCA) is a minimally invasive, image-guided procedure whereby cement is injected into lesion sites. Pain relief and functional restoration have been observed clinically; howeve...

Full description

Saved in:
Bibliographic Details
Published in:Journal of biomechanical engineering Vol. 129; no. 2; p. 129
Main Authors: Li, Zuoping, Butala, Neha B, Etheridge, Brandon S, Siegel, Herrick J, Lemons, Jack E, Eberhardt, Alan W
Format: Journal Article
Language:English
Published: United States 01-04-2007
Subjects:
Acetabulum - injuries
Acetabulum - physiopathology
Aged
Barium Sulfate - administration & dosage
Bone Cements - therapeutic use
Cadaver
Computer Simulation
Femur - physiopathology
Finite Element Analysis
Humans
Lumbar Vertebrae - physiopathology
Lumbar Vertebrae - surgery
Male
Materials Testing
Models, Biological
Neoplasm Metastasis - physiopathology
Pelvic Bones - diagnostic imaging
Pelvic Bones - physiopathology
Pelvic Bones - surgery
Polymethyl Methacrylate - administration & dosage
Reference Standards
Reproducibility of Results
Sensitivity and Specificity
Stress, Mechanical
Tomography, X-Ray Computed
Weight-Bearing
Online Access:Get more information
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Periacetabular bone metastases cause severe pain and functional disability in cancer patients. Percutaneous acetabuloplasty (PCA) is a minimally invasive, image-guided procedure whereby cement is injected into lesion sites. Pain relief and functional restoration have been observed clinically; however, neither the biomechanical consequences of the lesions nor the effectiveness of the PCA technique are well understood. The objective of this study was to investigate how periacetabular lesion size, cortex involvement, and cement modulus affect pelvic bone stresses and strains under single-legged stance loading. Experiments were performed on a male cadaver pelvis under conditions of intact, periacetabular defect, and cement-filling with surface strains recorded at three strain gage locations. The experimental data were then employed to validate three-dimensional finite element models of the same pelvis, developed using computed tomography data. The models demonstrated that increases in cortical stresses were highest along the posterior column of the acetabulum, adjacent to the defect. Cortical stresses were more profoundly affected in the presence of transcortical defects, as compared to those involving only trabecular bone. Cement filling with a modulus of 2.2 GPa was shown to restore cortical stresses to near intact values, while a decrease in cement modulus due to inclusion of BaSO(4) reduced the restorative effect. Peak acetabular contact pressures increased less than 15% for all simulated defect conditions; however, the contact stresses were reduced to levels below intact in the presence of either cement filling. These results suggest that periacetabular defects may increase the vulnerability of the pelvis to fracture depending on size and cortical involvement and that PCA filling may lower the risk of periacetabular fractures.
ISSN:0148-0731
DOI:10.1115/1.2472367