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Main Authors: Romeo, Mattia, Gagliardo, Cesare, Cottone, Grazia, Collura, Giorgio, Maggio, Enrico, Runfola, Claudio, Bruno, Eleonora, D'Oca, Maria Cristina, Midiri, Massimo, Lizzi, Francesca, Postuma, Ian, D'Amelio, Marco, Lascialfari, Alessandro, Retico, Alessandra, Marrale, Maurizio
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.15462
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author Romeo, Mattia
Gagliardo, Cesare
Cottone, Grazia
Collura, Giorgio
Maggio, Enrico
Runfola, Claudio
Bruno, Eleonora
D'Oca, Maria Cristina
Midiri, Massimo
Lizzi, Francesca
Postuma, Ian
D'Amelio, Marco
Lascialfari, Alessandro
Retico, Alessandra
Marrale, Maurizio
author_facet Romeo, Mattia
Gagliardo, Cesare
Cottone, Grazia
Collura, Giorgio
Maggio, Enrico
Runfola, Claudio
Bruno, Eleonora
D'Oca, Maria Cristina
Midiri, Massimo
Lizzi, Francesca
Postuma, Ian
D'Amelio, Marco
Lascialfari, Alessandro
Retico, Alessandra
Marrale, Maurizio
contents In the last years in-vivo tractography has assumed an important role in neurosciences, for both research and clinical applications such as non-invasive investigation of brain connectivity and presurgical planning in neurosurgery. In more recent years there has been a growing interest in the applications of diffusion tractography for target identification in functional neurological disorders for an increasingly tailored approach. The growing diffusion of well-established neurosurgical procedures, such as deep brain stimulation or trans-cranial Magnetic Resonance-guided Focused Ultrasound, favored this trend. Tractography can indeed provide more accurate, patient-specific, information about the targeted region if compared to stereotactic atlases. On the other hand, this tractography-based approach is not very physician-friendly, and its heavily time consuming since it needs several hours for Magnetic Resonance Imaging data processing. In this study we propose a novel open-source deep learning framework called DeLTA-BIT (acronym of Deep-learning Local TrActography for BraIn Targeting) for fast target predictions, based on probabilistic tractography. The proposed framework exploits a convolutional neural network (CNN) to predict the location of the Ventral Intermediate Nucleus of the thalamus (VIM). The CNN was trained on the Human Connectome Project (HCP) dataset. The model capability in predicting the VIM location was tested both on the HCP (internal validation) and clinical data (external validation). Results from the internal validation have shown good capability in predicting the VIM region (mean DSC = 0.62+- 0.15, mean sDSC=0.76+- 0.17) by using just T1 images as input, in a time scale of fraction of second per subject. As for the clinical data, results have been compared with an atlas-based method demonstrating similar performance, but within a significantly shorter timeframe.
format Preprint
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institution arXiv
publishDate 2023
record_format arxiv
spellingShingle DeLTA-BIT: an open-source probabilistic tractography-based deep learning framework for thalamic targeting in functional neurological disorders
Romeo, Mattia
Gagliardo, Cesare
Cottone, Grazia
Collura, Giorgio
Maggio, Enrico
Runfola, Claudio
Bruno, Eleonora
D'Oca, Maria Cristina
Midiri, Massimo
Lizzi, Francesca
Postuma, Ian
D'Amelio, Marco
Lascialfari, Alessandro
Retico, Alessandra
Marrale, Maurizio
Medical Physics
In the last years in-vivo tractography has assumed an important role in neurosciences, for both research and clinical applications such as non-invasive investigation of brain connectivity and presurgical planning in neurosurgery. In more recent years there has been a growing interest in the applications of diffusion tractography for target identification in functional neurological disorders for an increasingly tailored approach. The growing diffusion of well-established neurosurgical procedures, such as deep brain stimulation or trans-cranial Magnetic Resonance-guided Focused Ultrasound, favored this trend. Tractography can indeed provide more accurate, patient-specific, information about the targeted region if compared to stereotactic atlases. On the other hand, this tractography-based approach is not very physician-friendly, and its heavily time consuming since it needs several hours for Magnetic Resonance Imaging data processing. In this study we propose a novel open-source deep learning framework called DeLTA-BIT (acronym of Deep-learning Local TrActography for BraIn Targeting) for fast target predictions, based on probabilistic tractography. The proposed framework exploits a convolutional neural network (CNN) to predict the location of the Ventral Intermediate Nucleus of the thalamus (VIM). The CNN was trained on the Human Connectome Project (HCP) dataset. The model capability in predicting the VIM location was tested both on the HCP (internal validation) and clinical data (external validation). Results from the internal validation have shown good capability in predicting the VIM region (mean DSC = 0.62+- 0.15, mean sDSC=0.76+- 0.17) by using just T1 images as input, in a time scale of fraction of second per subject. As for the clinical data, results have been compared with an atlas-based method demonstrating similar performance, but within a significantly shorter timeframe.
title DeLTA-BIT: an open-source probabilistic tractography-based deep learning framework for thalamic targeting in functional neurological disorders
topic Medical Physics
url https://arxiv.org/abs/2312.15462