Mikael Agn scite author profile

In this paper we present a method for simultaneously segmenting brain tumors and an extensive set of organs-at-risk for radiation therapy planning of glioblastomas. The method combines a contrast-adaptive generative model for whole-brain segmentation with a new spatial regularization model of tumor shape using convolutional restricted Boltzmann machines. We demonstrate experimentally that the method is able to adapt to image acquisitions that differ substantially from any available training data, ensuring its applicability across treatment sites; that its tumor segmentation accuracy is comparable to that of the current state of the art; and that it captures most organs-at-risk sufficiently well for radiation therapy planning purposes. The proposed method may be a valuable step towards automating the delineation of brain tumors and organs-at-risk in glioblastoma patients undergoing radiation therapy.

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Brain Tumor Segmentation Using a Generative Model with an RBM Prior on Tumor Shape

Agn

Puonti

Rosenschöld

et al. 2016

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A generative model for segmentation of tumor and organs-at-risk for radiation therapy planning of glioblastoma patients

Agn

Law

Rosenschöld

et al. 2016

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We present a fully automated generative method for simultaneous brain tumor and organs-at-risk segmentation in multi-modal magnetic resonance images. The method combines an existing whole-brain segmentation technique with a spatial tumor prior, which uses convolutional restricted Boltzmann machines to model tumor shape. The method is not tuned to any specific imaging protocol and can simultaneously segment the gross tumor volume, peritumoral edema and healthy tissue structures relevant for radiotherapy planning. We validate the method on a manually delineated clinical data set of glioblastoma patients by comparing segmentations of gross tumor volume, brainstem and hippocampus. The preliminary results demonstrate the feasibility of the method.

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Fast Nonparametric Mutual-Information-based Registration and Uncertainty Estimation

Agn

Leemput

2019

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A Modality-Adaptive Method for Segmenting Brain Tumors and Organs-at-Risk in Radiation Therapy Planning

Agn¹,

Rosenschöld²,

Puonti³

et al. 2018

Preprint

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Improved resolution and reliability in dynamic PET using Bayesian regularization of MRTM2

Agn

Svarer

Frøkjær

et al. 2014

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Mikael Agn

Role of Serotonin Transporter Changes in Depressive Responses to Sex-Steroid Hormone Manipulation: A Positron Emission Tomography Study

An Ensemble of 2D Convolutional Neural Networks for Tumor Segmentation

A modality-adaptive method for segmenting brain tumors and organs-at-risk in radiation therapy planning

Brain Tumor Segmentation Using a Generative Model with an RBM Prior on Tumor Shape

A generative model for segmentation of tumor and organs-at-risk for radiation therapy planning of glioblastoma patients

Fast Nonparametric Mutual-Information-based Registration and Uncertainty Estimation

A Modality-Adaptive Method for Segmenting Brain Tumors and Organs-at-Risk in Radiation Therapy Planning

Improved resolution and reliability in dynamic PET using Bayesian regularization of MRTM2

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