DC Field
Value
Language
dc.contributor.author
Synek, Alexander
-
dc.contributor.author
Benca, Emir
-
dc.contributor.author
Pahr, Dieter
-
dc.date.accessioned
2024-12-05T09:31:13Z
-
dc.date.available
2024-12-05T09:31:13Z
-
dc.date.issued
2024-07-01
-
dc.identifier.citation
<div class="csl-bib-body">
<div class="csl-entry">Synek, A., Benca, E., & Pahr, D. (2024, July 1). <i>EXPLORING THE POTENTIAL OF NEURAL NETWORKS TO PREDICT METASTATIC FEMUR STRENGTH FROM 2D PROJECTIONS</i> [Conference Presentation]. 29th Congress of the European Society of Biomechanics, Edinburgh, United Kingdom of Great Britain and Northern Ireland (the). http://hdl.handle.net/20.500.12708/205280</div>
</div>
-
dc.identifier.uri
http://hdl.handle.net/20.500.12708/205280
-
dc.description.abstract
EXPLORING THE POTENTIAL OF NEURAL NETWORKS TO PREDICT
METASTATIC FEMUR STRENGTH FROM 2D PROJECTIONS
Alexander Synek (1), Emir Benca (2), Dieter H. Pahr (1,3)
1. TU Wien, Austria; 2. Medical University of Vienna, Austria
3. Karl Landsteiner University of Health Sciences, Austria
Introduction
Estimating the fracture risk of femora with metastatic
lesions represents a major challenge in clinical practice,
resulting in overtreatment of many patients [1]. Finite
element (FE) models have proven to be a useful tool for
fracture risk assessment and are on the verge of clinical
use [2]. However, they still require 3D imaging and
substantial computational resources. Predicting the
femoral strength from 2D projections, such as plain
radiographs, would enhance clinical availability, allow
continuous monitoring and could, therefore, further
improve the patients’ quality of life. The goal of this
study was to explore the potential of artificial neural
networks (NN) for fast, quantitative strength predictions
of metastatic femora from 2D projections. In a first step,
we tested if a NN can predict the strength of a single
femur with various different metastatic lesions.
Methods
To conduct a systematic exploration of the potential of
NN for femoral strength prediction, an artificial dataset
was created (Fig. 1): First, a 3D computed tomography
(CT) image of an intact proximal femur of a previous
study [3] was selected. Second, artificial metastatic
lesions were randomly inserted into the image, leading
to 2000 variations of different lesions within the same
femur. Third, non-linear FE models were used to predict
the strength (Fmax) in stance configuration for each bone.
The FE modelling workflow was based on [4], but
adapted for efficiency and calibrated using experimental
data of 68 human femur specimens [3,4] (Fmax predicted
with R²=0.89). Finally, anterior-posterior 2D projections
were created for each of the bones. Thus, a dataset was
obtained consisting of 2000 2D projections and the
corresponding FE-predicted femoral strengths.
The dataset was split into a training (n=1800) and
validation dataset (n=200). The training dataset was
used to train a custom convolutional NN that takes a
single 2D projection as an input and predicts the femoral
strength. The validation was performed using the
validation dataset by predicting the femoral strength 1)
using the original 2D projections and 2) using the 2D
projections with small random rotations and translations
to test the robustness of the NN predictions (Fig. 2).
Goodness of fit (R²) and mean absolute percentage error
(MAPE) were used to evaluate the performance of the
NN.
Results
The NN predicted the femoral strength with R²=0.95 and
MAPE of 8.4% using the original 2D projections, and
R²=0.93 and MAPE of 9.6% using the randomly rotated
and translated 2D projections (Fig. 2).
Discussion
This study showed that a convolutional NN can
quantitatively predict the femoral strength from 2D
projections with good precision and accuracy for a
single femur with different artificial metastatic lesions.
Random rotations and translations of the 2D projections
only slightly influenced the results. In the next steps, the
dataset shall be expanded to include multiple femora,
more realistic representations of the metastatic lesions,
and finally CT scans of patients with real metastatic
lesions.
References
1. Benca et al, Bone Rep., 5:51-56 2016.
2. Eggermont et al, Cancers, 14:5904, 2022.
3. Benca et al, Sci. Rep., 9:10305, 2019.
4. Dall’ara et al, Bone, 1:27-38, 2013
en
dc.language.iso
en
-
dc.subject
machine learning
en
dc.subject
metastatic bone disease
en
dc.subject
bone strength
en
dc.subject
finite element
en
dc.title
EXPLORING THE POTENTIAL OF NEURAL NETWORKS TO PREDICT METASTATIC FEMUR STRENGTH FROM 2D PROJECTIONS
en
dc.type
Presentation
en
dc.type
Vortrag
de
dc.contributor.affiliation
Medical University of Vienna, Austria
-
dc.type.category
Conference Presentation
-
tuw.researchTopic.id
M6
-
tuw.researchTopic.id
C6
-
tuw.researchTopic.name
Biological and Bioactive Materials
-
tuw.researchTopic.name
Modeling and Simulation
-
tuw.researchTopic.value
30
-
tuw.researchTopic.value
70
-
tuw.publication.orgunit
E317 - Institut für Leichtbau und Struktur-Biomechanik
-
tuw.author.orcid
0000-0002-5253-7403
-
tuw.author.orcid
0000-0002-9029-7172
-
tuw.author.orcid
0000-0002-5822-2082
-
tuw.event.name
29th Congress of the European Society of Biomechanics
en
tuw.event.startdate
30-06-2024
-
tuw.event.enddate
03-07-2024
-
tuw.event.online
On Site
-
tuw.event.type
Event for scientific audience
-
tuw.event.place
Edinburgh
-
tuw.event.country
GB
-
tuw.event.presenter
Synek, Alexander
-
tuw.event.track
Multi Track
-
wb.sciencebranch
Maschinenbau
-
wb.sciencebranch
Sonstige Technische Wissenschaften
-
wb.sciencebranch
Sonstige Humanmedizin, Gesundheitswissenschaften
-
wb.sciencebranch.oefos
2030
-
wb.sciencebranch.oefos
2119
-
wb.sciencebranch.oefos
3059
-
wb.sciencebranch.value
30
-
wb.sciencebranch.value
60
-
wb.sciencebranch.value
10
-
item.cerifentitytype
Publications
-
item.languageiso639-1
en
-
item.fulltext
no Fulltext
-
item.openairetype
conference paper not in proceedings
-
item.openairecristype
http://purl.org/coar/resource_type/c_18cp
-
item.grantfulltext
none
-
crisitem.author.dept
E317-03 - Forschungsbereich Computergestützte Biomechanik
-
crisitem.author.dept
Medical University of Vienna
-
crisitem.author.dept
E317-03 - Forschungsbereich Computergestützte Biomechanik
-
crisitem.author.orcid
0000-0002-5253-7403
-
crisitem.author.orcid
0000-0002-9029-7172
-
crisitem.author.orcid
0000-0002-5822-2082
-
crisitem.author.parentorg
E317 - Institut für Leichtbau und Struktur-Biomechanik
-
crisitem.author.parentorg
E317 - Institut für Leichtbau und Struktur-Biomechanik
-
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