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Hauptverfasser: Thorley, Alexander, Chartsias, Agis, Strom, Jordan, Lang, Roberto, Slivnick, Jeremy, O'Driscoll, Jamie, Sharma, Rajan, Kotecha, Dipak, Duan, Jinming, Gomez, Alberto
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2509.19691
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author Thorley, Alexander
Chartsias, Agis
Strom, Jordan
Lang, Roberto
Slivnick, Jeremy
O'Driscoll, Jamie
Sharma, Rajan
Kotecha, Dipak
Duan, Jinming
Gomez, Alberto
author_facet Thorley, Alexander
Chartsias, Agis
Strom, Jordan
Lang, Roberto
Slivnick, Jeremy
O'Driscoll, Jamie
Sharma, Rajan
Kotecha, Dipak
Duan, Jinming
Gomez, Alberto
contents Cardiac amyloidosis (CA) is a rare cardiomyopathy, with typical abnormalities in clinical measurements from echocardiograms such as reduced global longitudinal strain of the myocardium. An alternative approach for detecting CA is via neural networks, using video classification models such as convolutional neural networks. These models process entire video clips, but provide no assurance that classification is based on clinically relevant features known to be associated with CA. An alternative paradigm for disease classification is to apply models to quantitative features such as strain, ensuring that the classification relates to clinically relevant features. Drawing inspiration from this approach, we explicitly constrain a transformer model to the anatomical region where many known CA abnormalities occur -- the myocardium, which we embed as a set of deforming points and corresponding sampled image patches into input tokens. We show that our anatomical constraint can also be applied to the popular self-supervised learning masked autoencoder pre-training, where we propose to mask and reconstruct only anatomical patches. We show that by constraining both the transformer and pre-training task to the myocardium where CA imaging features are localized, we achieve increased performance on a CA classification task compared to full video transformers. Our model provides an explicit guarantee that the classification is focused on only anatomical regions of the echo, and enables us to visualize transformer attention scores over the deforming myocardium.
format Preprint
id arxiv_https___arxiv_org_abs_2509_19691
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Anatomically Constrained Transformers for Cardiac Amyloidosis Classification
Thorley, Alexander
Chartsias, Agis
Strom, Jordan
Lang, Roberto
Slivnick, Jeremy
O'Driscoll, Jamie
Sharma, Rajan
Kotecha, Dipak
Duan, Jinming
Gomez, Alberto
Computer Vision and Pattern Recognition
Cardiac amyloidosis (CA) is a rare cardiomyopathy, with typical abnormalities in clinical measurements from echocardiograms such as reduced global longitudinal strain of the myocardium. An alternative approach for detecting CA is via neural networks, using video classification models such as convolutional neural networks. These models process entire video clips, but provide no assurance that classification is based on clinically relevant features known to be associated with CA. An alternative paradigm for disease classification is to apply models to quantitative features such as strain, ensuring that the classification relates to clinically relevant features. Drawing inspiration from this approach, we explicitly constrain a transformer model to the anatomical region where many known CA abnormalities occur -- the myocardium, which we embed as a set of deforming points and corresponding sampled image patches into input tokens. We show that our anatomical constraint can also be applied to the popular self-supervised learning masked autoencoder pre-training, where we propose to mask and reconstruct only anatomical patches. We show that by constraining both the transformer and pre-training task to the myocardium where CA imaging features are localized, we achieve increased performance on a CA classification task compared to full video transformers. Our model provides an explicit guarantee that the classification is focused on only anatomical regions of the echo, and enables us to visualize transformer attention scores over the deforming myocardium.
title Anatomically Constrained Transformers for Cardiac Amyloidosis Classification
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2509.19691