Computer-aided technique for determining spinal pedicle screw size and optimal insertion trajectory.
Popescu, Diana ; Parpala, Radu Constantin ; Laptoiu, Dan Constantin 等
1. INTRODUCTION
The insertion of pedicular screw, used for fixation and
stabilization of the spine and for enhancing the long-term biological
fusion by holding bony structures together, poses specific problems to
spine surgeons mainly due to the difficulty of accurately inserting the
screw without damaging the pedicle.
The medical procedure of pedicular screws insertion, the choice of
screws dimensions (diameter and length) and optimal trajectory are based
on different aspects such as bone quality, pedicle anatomy and
orientation (fig.1.a). A safe insertion of the pedicle screw means to
enter from the lateral margin of the pedicle and exits to its medial
wall [Foley, K.T. &Gupta, S.K., 2002] (fig.1.b), along the pedicle
axis. Currently, C-arm fluoroscopy is used in the operative phase for
inspecting and verifying the preliminary pedicle entry sites. Using CT
scans the axial length and diameter of the pedicle are determined for
choosing the pedicle screw. Also, information about the sagittal and
axial angulations of individual pedicles are needed for determining the
trajectory of the tap, the surgeon modifying the angle such as its
virtual extension is within the pedicle. The screw length is determined
by lateral fluoroscopy, considering that the screw should be inserted
about 80% in the vertebral body [Rodrigues, L.M.R, et al. 2008].
However, this approach requires a lot of experience and skills from the
surgeon, a possible misplacement could cause damage of the spinal nerve.
In order to increase the safety insertion, the literature and
practice in the field consider several possible approaches such as
fluoroscopy based Computer Assisted Surgery or CT. All these techniques
are using intraoperative CT scans took during the operation for
observing the position of the drill relative to the spine and thus
correcting the drill trajectory.
Another possible approach is to design and manufacture a drill
guide based on the individual patient anatomy, considering the following
procedure: in a pre-operative phase the patient is scanned, the 3D model
of the spine is obtained using a medical modeling software, the drill
guide is design to fit to the anatomical specifications of the patient
and then the template is manufactured via a Rapid Prototyping (RP)
process.
Moreover, the diameter of the pedicle screw and its length can be
chosen based on the smallest cross section of the pedicle (isthmus)
available from the 3D model of the vertebra, as will be detailed
further.
[FIGURE 1 OMITTED]
The current paper presents an ongoing interdisciplinary research
project, which involves specialists from medicine (spinal surgeons),
design (for medical modelling of CT data and guide design),
manufacturing (for evaluating different RP techniques, setting specific
parameters, etc.) and biomaterials fields. Our approach is based on the
use of a RP drill template, which is designed having the spinous process
as reference, for ensuring the right position and orientation of the
drill guide. Although the spinous process is well defined as 3D
coordinates and vertebral pedicles neighbourhood, the problem of
determining the reference points of the guiding system and the minimal
number of supporting points is very important for ensuring a high
precision of the screw implant. The drill guide contains all the
geometrical features necessary for imposing a correct insertion
position, and the design of each composing element is based on the data
obtained by CT data. Such of device is not currently available in
Romanian hospitals, for pedicular screws insertion only few guiding
systems being used, most of the time this procedure requiring X-ray
control during the insertion.
2. SPINAL PEDICLE SCREW SIZE AND OPTIMAL TRAJECTORY DETERMINATION
The first stage of the project, presented in this paper, consists
in obtaining the 3D model of a vertebra and then determining the optimal
trajectory and the right screw size. The optimal trajectory is a line,
along the pedicle axis, that contains the center of isthmus and it is
perpendicular to the isthmus plane. This way, the drill angles
materialized on the guide can be accurately transferred to the patient
for exact placement of the pedicle screws. The design of the drill
guide, as well as issues regarding the material, manufacturing process
and clinical testing will be discussed in further articles.
2.1. Survey of the literature in the field
Previous researches referring to pedicle screw drill templates use
as references the middle of the posterior surface of the spinous process
at its thickest and the most posterior boundary of the spinal canal for
determining the coordinates for assessing the accuracy of implantation
[Porada, et al., 2001]. For increasing stability, supports are designed
to fit also transverse process in a surface-to-surface approach or using
different support structures which are in contact with the posterior
surface of lamina.
[Porada, et al., 2001] and [Yoo, T.S., 2003] presents two
methodologies which use SurgiCase, respectively a dedicated software
based on OpenGL, for determining the screw insertion trajectory and
screw size, considering the patient CT scan data.
[Lu, S., 2009] uses patient CT data to build a 3D model and then
projects the pedicle model on lamina and vertebra planes. First, the
smaller diameter of the pedicle projection is determined for
establishing the maximum dimension of the screw, and then the circle is
projected between the lamina and vertebral body for obtaining the screw
trajectory.
[Pacheco, H.O., 2007] presents a patented approach for improving
pedicle screw placement in which the optimal insertion trajectory is
computed by linear least squares method.
Our approach will use CATIA V5 for determining the pedicle axis and
then the pedicle isthmus, the same software being used in further
research for designing the drill template.
2.2. 3D modeling--reconstruction of the of a spine vertebra
DICOM files from the spiral three-dimensional CT scanning of the
lumbar vertebra L3 [Van Sint Jan, S., 1998] were used for reconstructing
L3 vertebra in Mimics software. The 3D model was generated and then
exported to CATIA V5 (CV5). Workbenches such as Digitized Shape Editor
and Quick Surface Reconstruction were used to obtain the CATPart model
from the STL file exported by Mimics. CV5 surface model of the L3
vertebra and the extracted surfaces which delimit the pedicle are
presented in figure 3. The input from the user consists first in
extracting the surfaces which form the pedicle shape. These surfaces are
then sectioned with successive planes, parallel with the coronal plane.
Each section has an almost oval shape, the centers of ovals are
determined and then the axis line, which is approximately equally
distanced of all the center points (mean line), is generated. The size
of the screw is chosen considering the smaller diameter of the pedicle
(fig.4) based on the sectioned previous determined, as the pedicle
thickness and cross section varies along its length.
3. CONCLUSIONS AND FURTHER RESEARCH
The guiding system proposed is based on specific information about
the patient's anatomy, imposing an individual solution for each
clinical case, which recommends RP processes for manufacturing the
guide. The guide will be held by the assistant surgeon or by the surgeon
in the same orientation as the patient in the line of sight, this
allowing minimally invasive approach with instrumentation in situ,
reducing intra-operative X-ray and facilitating accurate screw
placement.
The current paper presents the first two steps from the following
methodology to design and manufacture a guiding system for inserting
pedicle screws:
1. Planning the screws trajectories and determining the pedicle
screw size based on the patient individual data
2. Establishing reference points/elements for guide positioning
3. Determining positioning constraints imposed by surgeon
4. Designing the drill guide
5. Rapid manufacturing of the guide
6. CT post-op validation for assessing the implant accuracy.
Further research will also consider the programming
capabilities of CV5 software to automatically generate the screw
insertion trajectory which approximately passes to the middle of the
pedicle.
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.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
[FIGURE 4 OMITTED]
4. REFERENCES
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the lumbar spine: preliminary clinical results, J. Neurosurg (Spine),
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Lu, S., et al. (2009), A novel computer-assisted drill guide
template for lumbar pedicle screw placement: a cadaveric and clinical
study, Int J Med Robot., Jun; 5(2):184-9, ISSN 1478-5951
Pacheco, H.O., (2007), Method of improving pedicle screw placement
in spinal surgery, Patent US20050192575
Porada, P. A. Millner, N. Chibverton, E. Berry, B. B. Seedhom,
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Rodrigues, L.M.R, et al. (2008), Correlation between pedicular
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http://isbweb.org/data/vsj/index.html, The Laboratory of Human Anatomy
and Embryology, Faculty of Medicine, University of Brussels
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www.back.com/anatomy-lumbar.html
