FEM analysis of pedicle screw-bone interface for different insertion directions.
Popescu, Diana ; Parpala, Radu Constantin
Abstract: The paper presents a finite element analysis of three
insertion directions of pedicle screw in lumbar vertebra, the purpose
being to investigate the impact of the implantation trajectory over the
stability of vertebral pedicle-screw interface, by comparing the maximal
displacements obtained for the same pull-out force. Also, this
information is helpful in the design process of a drilling template
which can be used during surgery for increasing the pedicle screw
positioning accuracy and its pull-out strength in the vertebra.
Key words: FEM, pedicle screw, lumbar vertebra, screw-bone
interface
1. INTRODUCTION
Posterior spinal stabilizationis required for different types of
pathologies and consists in using screws inserted in the pedicles and
connected with rods for fusing the vertebrae. This surgical procedure
imposes a precise technique for avoiding the damages of pedicles or
neural structures. For this purpose, during the preoperative phase, the
surgeon carefully analyses the bone quality, the pedicle morphology and
orientation, and establishes the screw entry point in the vertebra (fig.
1), as well as the screw type and dimensions (diameter and length).
In the clinical practice, the insertion trajectory of screws
isusually along the pedicle axis for increasing the placement safety,
but in the same time, the insertion direction must bechoosen to provide
the strongest possible interface between bone and screw. In this
context, there are severals ways for obtaining an enhanced interface
between vertebral bone and pedicle screws: changing the design of the
screw (Chatzistergos, et al., 2010), (Batulla, et al., 2006), (Patel et
al., 2010) coating the screw surface for improving the contact or using
reinforcing materials. Another possible solution, investigated in this
paper with the use of finite element analysis (FEA) is to modify the
screw implant trajectory for providing more contact with the cortical,
rather than cancellous bone. This trajectory could be materialised
during surgery by using a drilling template manufactured via a Rapid
Prototyping process, customized for each pacient.
Analysis and characterisation of the interface between screws and
bones represents an important research subject for several years due to
the fact that clinical practice identifiesscrew loosening as a main
cause of failure, despite a correct positioning of the implant.
Therefore the literature presents biomechanical studies in which the
pull-out strength is determined for different loads, insertion direction
or fixation systems (Sterba et al., 2007), (Xu, et al., 2010), (Zhang,
G.H., 2004), (Santoni, et al., 2008).However, to the best of the
authors' knowledge no previous research has been done for
establishing a finite element model of the interface between bone and
pedicle screw inserted at different angles.
A review of finite elements(FE) studies for human spine is
presented in (Jones& Wilcox, 2008). The purpose of this research
work is to establish a standard approach for verification and validation of different finite element models and materials properties used in
different studies in the field for analysing bone-implant interface.
Also, literature reports the use of FEM for improving the design and
stability of screws, rods and screws-rods systems by elaborating and
validating complete lumbar vertebra finite element models.
2. METHOD
A threedimensional model of a L3 vertebra was generated in Mimics
10.01 from CT scan data (Van Sint, 1998). The model was exported in
CATIA V5 and processed in different workbenches for obtaining a surface
and then a solid model (fig.2). The vertebra was modelled as consisting
in two parts: a cortical one at the exterior and a cancellous one in the
interior.
The pedicle screw was modelled simplified, as a cylinder.
Three insertion trajectories were analyzedin ANSYS V12:1. along the
pedicle axis; 2. parallel with the spinous process; 3. passing more
medial-lateral ("closer" to the cortical bone)compared with
direction 1 (fig.3). The deformation values for a pull-out force of 25N
were compared.
All the analysed trajectories were considered as starting from the
same entry point, established at thelateral border of the superior facet
where it intersects the midportion of the transverse process.
The material (considered isotropic and with linear elastic
behaviour) properties for cortical and cancelous bone used in the FE
model are presented in table 1, as mentioned in literature (Jones &
Wilcox, 2008).
[FIGURE 1 OMITTED]
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3. RESULTS
Analysing the total deformation and equivalent von Miss
stressobtained in FEA (an example is presented in figure 3), the best
insertion trajectory is parallel to the spinous process (table 2). These
results are confirmed by the biomechanical tests presented in (Sterba et
al., 2007) and (Santoni et al., 2008).
The explanation of this result is that the screw's thread, in
this position, comes in contact with a larger part of the cortical
bone--with better material properties compared to cancellous bone, this
way improving the fixation strength. Due to the fact that this path is
practically difficult to achieve, a drill guide, customized for each
patient and manufactured using a Rapid Manufacturing process, could be a
solution.
4. DISCUSSION AND CONCLUSIONS
The purpose of the research was to find a way to improve the
longevity and stability of vertebral pedicle-screw interface. To the
best of the authors' knowledge no previous research has been done
for finite element modeling of the interface between bone and pedicle
screw inserted at different angles, although biomechanical tests were
performed in this sense.
The complexity of the problem resides in the difficulty to
establish material properties or the correct boundary conditions
considering the great variation between individuals. Therefore, further
analysis will consider not only the use of a standard screw model, but
also a better assessment of bone mechanical properties considering the
new approach in which estimations of material properties are assigned
based on the relation between Hounsfield units, bone mineral density (information available by quantitative computer tomography--QCT) and
elastic modulus (Jovanovici, J.D., et al., 2010).
[FIGURE 5 OMITTED]
5. ACKNOWLEDGEMENTS
The work has been co-funded by the Sectoral Operational Programme
Human Resources Development 2007-2013 of the Romanian Ministry of
Labour, Family and Social Protection through the Financial Agreement
POSDRU/89/1.5/S/62557.
6. REFERENCES
Battula, S., et al. (2006). Experimental evaluation of the holding
power/stiffness of the self-tapping bone screws in normal and
osteoporotic bone material. Clinical Biomechanics, 2:533-537
Chatzistergos, P.E., et al. (2010). A parametric study of
cylindrical pedicle screw desgin implications on the pullout performance
using an experimentally validated finite-element model, Medical
Engineering & Physics, 32:145-154
Inceoglu, S., et al. (2007). Cortex of the pedicle of the vertebral
arch. Part II: Microstructure, J Neurosurg Spine 7:347-351
Jones, A., Wilcox, R. (2008), Finite element analysis of the spine:
Towards a framework of verification, validation and sensitivity
analysis, Medical Engineering & Physics, 30: 1287-1304
Jovanovici, J.D. et al. 2010. Finite element modeling of the
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data, FactaUniversitatis, Series: Mechanical Engineering. 8(1): 19-26
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Santoni, B.G., et al. (2008). Cortical bone trajectory for lumbar
pedicle screws, The Spine Journal, pp. 1-8
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http://isbweb.org/data/vsj/index.html, The Laboratory of Human Anatomy
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Tab. 1. Material properties for bone and pedicle screw
Young Modulus Poisson ratio
(MPa)
Cortical bone 780 0.3
Cancellous Bone 100 0.2
Screw 100000 0.3
Vertebral arch 1000 0.45
Articular process 1000 0.45
Tab. 2. Results of FE analysis for three insertion trajectories
Trajectory 1 Trajectory 2
Maximal 3,5871 * [10.sup.-7] m 2,042 * [10.sup.-7] m
deformation
Equivalent
von Miss 4,4411 MPa 3,362 MPa
stress
Trajectory 3
Maximal 2,242 * [10.sup.-7] m
deformation
Equivalent
von Miss 3,3155 MPa
stress
