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1. Counterfactual Explanations for Medical Image Classification and Regression using Diffusion Autoencoder

Author

Atad, Matan, Schinz, David, Moeller, Hendrik, Graf, Robert, Wiestler, Benedikt, Rueckert, Daniel, Navab, Nassir, Kirschke, Jan S., and Keicher, Matthias

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning
Abstract

Counterfactual explanations (CEs) aim to enhance the interpretability of machine learning models by illustrating how alterations in input features would affect the resulting predictions. Common CE approaches require an additional model and are typically constrained to binary counterfactuals. In contrast, we propose a novel method that operates directly on the latent space of a generative model, specifically a Diffusion Autoencoder (DAE). This approach offers inherent interpretability by enabling the generation of CEs and the continuous visualization of the model's internal representation across decision boundaries. Our method leverages the DAE's ability to encode images into a semantically rich latent space in an unsupervised manner, eliminating the need for labeled data or separate feature extraction models. We show that these latent representations are helpful for medical condition classification and the ordinal regression of severity pathologies, such as vertebral compression fractures (VCF) and diabetic retinopathy (DR). Beyond binary CEs, our method supports the visualization of ordinal CEs using a linear model, providing deeper insights into the model's decision-making process and enhancing interpretability. Experiments across various medical imaging datasets demonstrate the method's advantages in interpretability and versatility. The linear manifold of the DAE's latent space allows for meaningful interpolation and manipulation, making it a powerful tool for exploring medical image properties. Our code is available at https://doi.org/10.5281/zenodo.13859266., Comment: Accepted for publication at the Journal of Machine Learning for Biomedical Imaging (MELBA) https://melba-journal.org/2024:024. arXiv admin note: text overlap with arXiv:2303.12031

Published
2024
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2. Enhancing Interpretability of Vertebrae Fracture Grading using Human-interpretable Prototypes

Author

Sinhamahapatra, Poulami, Shit, Suprosanna, Sekuboyina, Anjany, Husseini, Malek, Schinz, David, Lenhart, Nicolas, Menze, Joern, Kirschke, Jan, Roscher, Karsten, and Guennemann, Stephan

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence
Abstract

Vertebral fracture grading classifies the severity of vertebral fractures, which is a challenging task in medical imaging and has recently attracted Deep Learning (DL) models. Only a few works attempted to make such models human-interpretable despite the need for transparency and trustworthiness in critical use cases like DL-assisted medical diagnosis. Moreover, such models either rely on post-hoc methods or additional annotations. In this work, we propose a novel interpretable-by-design method, ProtoVerse, to find relevant sub-parts of vertebral fractures (prototypes) that reliably explain the model's decision in a human-understandable way. Specifically, we introduce a novel diversity-promoting loss to mitigate prototype repetitions in small datasets with intricate semantics. We have experimented with the VerSe'19 dataset and outperformed the existing prototype-based method. Further, our model provides superior interpretability against the post-hoc method. Importantly, expert radiologists validated the visual interpretability of our results, showing clinical applicability., Comment: Accepted for publication at the Journal of Machine Learning for Biomedical Imaging (MELBA) https://melba-journal.org/2024:015

Published
2024
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4. Semantic Latent Space Regression of Diffusion Autoencoders for Vertebral Fracture Grading

Author

Keicher, Matthias, Atad, Matan, Schinz, David, Gersing, Alexandra S., Foreman, Sarah C., Goller, Sophia S., Weissinger, Juergen, Rischewski, Jon, Dietrich, Anna-Sophia, Wiestler, Benedikt, Kirschke, Jan S., and Navab, Nassir

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning
Abstract

Vertebral fractures are a consequence of osteoporosis, with significant health implications for affected patients. Unfortunately, grading their severity using CT exams is hard and subjective, motivating automated grading methods. However, current approaches are hindered by imbalance and scarcity of data and a lack of interpretability. To address these challenges, this paper proposes a novel approach that leverages unlabelled data to train a generative Diffusion Autoencoder (DAE) model as an unsupervised feature extractor. We model fracture grading as a continuous regression, which is more reflective of the smooth progression of fractures. Specifically, we use a binary, supervised fracture classifier to construct a hyperplane in the DAE's latent space. We then regress the severity of the fracture as a function of the distance to this hyperplane, calibrating the results to the Genant scale. Importantly, the generative nature of our method allows us to visualize different grades of a given vertebra, providing interpretability and insight into the features that contribute to automated grading., Comment: Under review

Published
2023

5. Interpretable Vertebral Fracture Diagnosis

Author

Engstler, Paul, Keicher, Matthias, Schinz, David, Mach, Kristina, Gersing, Alexandra S., Foreman, Sarah C., Goller, Sophia S., Weissinger, Juergen, Rischewski, Jon, Dietrich, Anna-Sophia, Wiestler, Benedikt, Kirschke, Jan S., Khakzar, Ashkan, and Navab, Nassir

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition
Abstract

Do black-box neural network models learn clinically relevant features for fracture diagnosis? The answer not only establishes reliability quenches scientific curiosity but also leads to explainable and verbose findings that can assist the radiologists in the final and increase trust. This work identifies the concepts networks use for vertebral fracture diagnosis in CT images. This is achieved by associating concepts to neurons highly correlated with a specific diagnosis in the dataset. The concepts are either associated with neurons by radiologists pre-hoc or are visualized during a specific prediction and left for the user's interpretation. We evaluate which concepts lead to correct diagnosis and which concepts lead to false positives. The proposed frameworks and analysis pave the way for reliable and explainable vertebral fracture diagnosis., Comment: Check out the project's webpage for the code and demo: https://github.com/CAMP-eXplain-AI/Interpretable-Vertebral-Fracture-Diagnosis

Published
2022

8. A Computed Tomography Vertebral Segmentation Dataset with Anatomical Variations and Multi-Vendor Scanner Data

Author

Liebl, Hans, Schinz, David, Sekuboyina, Anjany, Malagutti, Luca, Löffler, Maximilian T., Bayat, Amirhossein, Husseini, Malek El, Tetteh, Giles, Grau, Katharina, Niederreiter, Eva, Baum, Thomas, Wiestler, Benedikt, Menze, Bjoern, Braren, Rickmer, Zimmer, Claus, and Kirschke, Jan S.

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition
Abstract

With the advent of deep learning algorithms, fully automated radiological image analysis is within reach. In spine imaging, several atlas- and shape-based as well as deep learning segmentation algorithms have been proposed, allowing for subsequent automated analysis of morphology and pathology. The first Large Scale Vertebrae Segmentation Challenge (VerSe 2019) showed that these perform well on normal anatomy, but fail in variants not frequently present in the training dataset. Building on that experience, we report on the largely increased VerSe 2020 dataset and results from the second iteration of the VerSe challenge (MICCAI 2020, Lima, Peru). VerSe 2020 comprises annotated spine computed tomography (CT) images from 300 subjects with 4142 fully visualized and annotated vertebrae, collected across multiple centres from four different scanner manufacturers, enriched with cases that exhibit anatomical variants such as enumeration abnormalities (n=77) and transitional vertebrae (n=161). Metadata includes vertebral labelling information, voxel-level segmentation masks obtained with a human-machine hybrid algorithm and anatomical ratings, to enable the development and benchmarking of robust and accurate segmentation algorithms., Comment: 18 pages, 2 figures, 2 tables; Hans Liebl, David Schinz equally contributed to this manuscript

Published
2021

9. LST-AI: A deep learning ensemble for accurate MS lesion segmentation

Author

Wiltgen, Tun, McGinnis, Julian, Schlaeger, Sarah, Kofler, Florian, Voon, CuiCi, Berthele, Achim, Bischl, Daria, Grundl, Lioba, Will, Nikolaus, Metz, Marie, Schinz, David, Sepp, Dominik, Prucker, Philipp, Schmitz-Koep, Benita, Zimmer, Claus, Menze, Bjoern, Rueckert, Daniel, Hemmer, Bernhard, Kirschke, Jan, Mühlau, Mark, and Wiestler, Benedikt

Published
2024
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14. Human Claustrum Connections: Robust In Vivo Detection by DWI‐Based Tractography in Two Large Samples.

Author

Wendt, Jil, Neubauer, Antonia, Hedderich, Dennis M., Schmitz‐Koep, Benita, Ayyildiz, Sevilay, Schinz, David, Hippen, Rebecca, Daamen, Marcel, Boecker, Henning, Zimmer, Claus, Wolke, Dieter, Bartmann, Peter, Sorg, Christian, and Menegaux, Aurore

Subjects
MAGNETIC resonance imaging, YOUNG adults, HUMAN anatomy, PROSENCEPHALON, LONGITUDINAL method
Abstract

Despite substantial neuroscience research in the last decade revealing the claustrum's prominent role in mammalian forebrain organization, as evidenced by its extraordinarily widespread connectivity pattern, claustrum studies in humans are rare. This is particularly true for studies focusing on claustrum connections. Two primary reasons may account for this situation: First, the intricate anatomy of the human claustrum located between the external and extreme capsule hinders straightforward and reliable structural delineation. In addition, the few studies that used diffusion‐weighted‐imaging (DWI)‐based tractography could not clarify whether in vivo tractography consistently and reliably identifies claustrum connections in humans across different subjects, cohorts, imaging methods, and connectivity metrics. To address these issues, we combined a recently developed deep‐learning‐based claustrum segmentation tool with DWI‐based tractography in two large adult cohorts: 81 healthy young adults from the human connectome project and 81 further healthy young participants from the Bavarian longitudinal study. Tracts between the claustrum and 13 cortical and 9 subcortical regions were reconstructed in each subject using probabilistic tractography. Probabilistic group average maps and different connectivity metrics were generated to assess the claustrum's connectivity profile as well as consistency and replicability of tractography. We found, across individuals, cohorts, DWI‐protocols, and measures, consistent and replicable cortical and subcortical ipsi‐ and contralateral claustrum connections. This result demonstrates robust in vivo tractography of claustrum connections in humans, providing a base for further examinations of claustrum connectivity in health and disease. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Interpretable Vertebral Fracture Diagnosis

Author

Engstler, Paul, primary, Keicher, Matthias, additional, Schinz, David, additional, Mach, Kristina, additional, Gersing, Alexandra S., additional, Foreman, Sarah C., additional, Goller, Sophia S., additional, Weissinger, Juergen, additional, Rischewski, Jon, additional, Dietrich, Anna-Sophia, additional, Wiestler, Benedikt, additional, Kirschke, Jan S., additional, Khakzar, Ashkan, additional, and Navab, Nassir, additional

Published
2022
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16. Deep Learning to Differentiate Benign and Malignant Vertebral Fractures at Multidetector CT

Author

Foreman, Sarah C., primary, Schinz, David, additional, El Husseini, Malek, additional, Goller, Sophia S., additional, Weißinger, Jürgen, additional, Dietrich, Anna-Sophia, additional, Renz, Martin, additional, Metz, Marie-Christin, additional, Feuerriegel, Georg C., additional, Wiestler, Benedikt, additional, Stahl, Robert, additional, Schwaiger, Benedikt J., additional, Makowski, Marcus R., additional, Kirschke, Jan S., additional, and Gersing, Alexandra S., additional

Published
2024
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17. LST-AI: a Deep Learning Ensemble for Accurate MS Lesion Segmentation

Author

Wiltgen, Tun, primary, McGinnis, Julian, additional, Schlaeger, Sarah, additional, Voon, CuiCi, additional, Berthele, Achim, additional, Bischl, Daria, additional, Grundl, Lioba, additional, Will, Nikolaus, additional, Metz, Marie, additional, Schinz, David, additional, Sepp, Dominik, additional, Prucker, Philipp, additional, Schmitz-Koep, Benita, additional, Zimmer, Claus, additional, Menze, Bjoern, additional, Rueckert, Daniel, additional, Hemmer, Bernhard, additional, Kirschke, Jan, additional, Muehlau, Mark, additional, and Wiestler, Benedikt, additional

Published
2023
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19. Indirect evidence for altered dopaminergic neurotransmission in very premature‐born adults

Author

Schinz, David, primary, Schmitz‐Koep, Benita, additional, Zimmermann, Juliana, additional, Brandes, Elin, additional, Tahedl, Marlene, additional, Menegaux, Aurore, additional, Dukart, Juergen, additional, Zimmer, Claus, additional, Wolke, Dieter, additional, Daamen, Marcel, additional, Boecker, Henning, additional, Bartmann, Peter, additional, Sorg, Christian, additional, and Hedderich, Dennis M., additional

Published
2023
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20. Altered gray‐to‐white matter tissue contrast in preterm‐born adults

Author

Schmitz‐Koep, Benita, primary, Menegaux, Aurore, additional, Zimmermann, Juliana, additional, Thalhammer, Melissa, additional, Neubauer, Antonia, additional, Wendt, Jil, additional, Schinz, David, additional, Daamen, Marcel, additional, Boecker, Henning, additional, Zimmer, Claus, additional, Priller, Josef, additional, Wolke, Dieter, additional, Bartmann, Peter, additional, Sorg, Christian, additional, and Hedderich, Dennis M., additional

Published
2023
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21. Differentiation of benign and malignant vertebral fractures using a convolutional neural network to extract CT-based texture features

Author

Goller, Sophia S, Foreman, Sarah C, Rischewski, Jon F, Weißinger, Jürgen, Dietrich, Anna-Sophia, Schinz, David, Stahl, Robert, Luitjens, Johanna, Siller, Sebastian, Schmidt, Vanessa F, Erber, Bernd, Ricke, Jens, Liebig, Thomas, Kirschke, Jan S, Dieckmeyer, Michael, and Gersing, Alexandra S

Subjects
610 Medicine & health
Abstract

PURPOSE To assess the diagnostic performance of three-dimensional (3D) CT-based texture features (TFs) using a convolutional neural network (CNN)-based framework to differentiate benign (osteoporotic) and malignant vertebral fractures (VFs). METHODS A total of 409 patients who underwent routine thoracolumbar spine CT at two institutions were included. VFs were categorized as benign or malignant using either biopsy or imaging follow-up of at least three months as standard of reference. Automated detection, labelling, and segmentation of the vertebrae were performed using a CNN-based framework ( https://anduin.bonescreen.de ). Eight TFs were extracted: Varianceglobal, Skewnessglobal, energy, entropy, short-run emphasis (SRE), long-run emphasis (LRE), run-length non-uniformity (RLN), and run percentage (RP). Multivariate regression models adjusted for age and sex were used to compare TFs between benign and malignant VFs. RESULTS Skewnessglobal showed a significant difference between the two groups when analyzing fractured vertebrae from T1 to L6 (benign fracture group: 0.70 [0.64-0.76]; malignant fracture group: 0.59 [0.56-0.63]; and p = 0.017), suggesting a higher skewness in benign VFs compared to malignant VFs. CONCLUSION Three-dimensional CT-based global TF skewness assessed using a CNN-based framework showed significant difference between benign and malignant thoracolumbar VFs and may therefore contribute to the clinical diagnostic work-up of patients with VFs.

Published
2023
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22. Aberrant allometric scaling of cortical folding in preterm-born adults

Author

Schmitz-Koep, Benita, primary, Menegaux, Aurore, additional, Zimmermann, Juliana, additional, Thalhammer, Melissa, additional, Neubauer, Antonia, additional, Wendt, Jil, additional, Schinz, David, additional, Wachinger, Christian, additional, Daamen, Marcel, additional, Boecker, Henning, additional, Zimmer, Claus, additional, Priller, Josef, additional, Wolke, Dieter, additional, Bartmann, Peter, additional, Sorg, Christian, additional, and Hedderich, Dennis M, additional

Published
2022
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23. Impact of normative brain volume reports on the diagnosis of neurodegenerative dementia disorders in neuroradiology: A real-world, clinical practice study

Author

Hedderich, Dennis M., primary, Schmitz-Koep, Benita, additional, Schuberth, Madeleine, additional, Schultz, Vivian, additional, Schlaeger, Sarah J., additional, Schinz, David, additional, Rubbert, Christian, additional, Caspers, Julian, additional, Zimmer, Claus, additional, Grimmer, Timo, additional, and Yakushev, Igor, additional

Published
2022
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24. Efficient Claustrum Segmentation in T2-weighted Neonatal Brain MRI Using Transfer Learning from Adult Scans

Author

Neubauer, Antonia; https://orcid.org/0000-0001-9820-3735, Li, Hongwei Bran, Wendt, Jil, Schmitz-Koep, Benita, Menegaux, Aurore, Schinz, David, Menze, Bjoern, Zimmer, Claus, Sorg, Christian, Hedderich, Dennis M, Neubauer, Antonia; https://orcid.org/0000-0001-9820-3735, Li, Hongwei Bran, Wendt, Jil, Schmitz-Koep, Benita, Menegaux, Aurore, Schinz, David, Menze, Bjoern, Zimmer, Claus, Sorg, Christian, and Hedderich, Dennis M

Abstract

Purpose Intrauterine claustrum and subplate neuron development have been suggested to overlap. As premature birth typically impairs subplate neuron development, neonatal claustrum might indicate a specific prematurity impact; however, claustrum identification usually relies on expert knowledge due to its intricate structure. We established automated claustrum segmentation in newborns. Methods We applied a deep learning-based algorithm for segmenting the claustrum in 558 T2-weighted neonatal brain MRI of the developing Human Connectome Project (dHCP) with transfer learning from claustrum segmentation in T1-weighted scans of adults. The model was trained and evaluated on 30 manual bilateral claustrum annotations in neonates. Results With only 20 annotated scans, the model yielded median volumetric similarity, robust Hausdorff distance and Dice score of 95.9%, 1.12 mm and 80.0%, respectively, representing an excellent agreement between the automatic and manual segmentations. In comparison with interrater reliability, the model achieved significantly superior volumetric similarity (p = 0.047) and Dice score (p < 0.005) indicating stable high-quality performance. Furthermore, the effectiveness of the transfer learning technique was demonstrated in comparison with nontransfer learning. The model can achieve satisfactory segmentation with only 12 annotated scans. Finally, the model’s applicability was verified on 528 scans and revealed reliable segmentations in 97.4%. Conclusion The developed fast and accurate automated segmentation has great potential in large-scale study cohorts and to facilitate MRI-based connectome research of the neonatal claustrum. The easy to use models and codes are made publicly available.

Published
2022

26. Aberrant Claustrum Structure in Preterm-Born Neonates: An MRI Study

Author

Neubauer, Antonia, primary, Menegaux, Aurore, additional, Wendt, Jil, additional, Li, Hongwei Bran, additional, Schmitz-Koep, Benita, additional, Ruzok, Tobias, additional, Thalhammer, Melissa, additional, Schinz, David, additional, Bartmann, Peter, additional, Wolke, Dieter, additional, Priller, Josef, additional, Zimmer, Claus, additional, Rückert, Daniel, additional, Hedderich, Dennis M., additional, and Sorg, Christian, additional

Published
2022
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28. A computed tomography vertebral segmentation dataset with anatomical variations and multi-vendor scanner data

Author

Liebl, Hans, primary, Schinz, David, additional, Sekuboyina, Anjany, additional, Malagutti, Luca, additional, Löffler, Maximilian T., additional, Bayat, Amirhossein, additional, El Husseini, Malek, additional, Tetteh, Giles, additional, Grau, Katharina, additional, Niederreiter, Eva, additional, Baum, Thomas, additional, Wiestler, Benedikt, additional, Menze, Bjoern, additional, Braren, Rickmer, additional, Zimmer, Claus, additional, and Kirschke, Jan S., additional

Published
2021
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30. A computed tomography vertebral segmentation dataset with anatomical variations and multi-vendor scanner data

Author

Liebl, Hans; https://orcid.org/0000-0002-0171-9880, Schinz, David; https://orcid.org/0000-0003-3734-1135, Sekuboyina, Anjany, Malagutti, Luca, Löffler, Maximilian T, Bayat, Amirhossein, El Husseini, Malek, Tetteh, Giles, Grau, Katharina, Niederreiter, Eva, Baum, Thomas; https://orcid.org/0000-0002-4574-5212, Wiestler, Benedikt; https://orcid.org/0000-0002-2963-7772, Menze, Bjoern; https://orcid.org/0000-0003-4136-5690, Braren, Rickmer, Zimmer, Claus, Kirschke, Jan S; https://orcid.org/0000-0002-7557-0003, Liebl, Hans; https://orcid.org/0000-0002-0171-9880, Schinz, David; https://orcid.org/0000-0003-3734-1135, Sekuboyina, Anjany, Malagutti, Luca, Löffler, Maximilian T, Bayat, Amirhossein, El Husseini, Malek, Tetteh, Giles, Grau, Katharina, Niederreiter, Eva, Baum, Thomas; https://orcid.org/0000-0002-4574-5212, Wiestler, Benedikt; https://orcid.org/0000-0002-2963-7772, Menze, Bjoern; https://orcid.org/0000-0003-4136-5690, Braren, Rickmer, Zimmer, Claus, and Kirschke, Jan S; https://orcid.org/0000-0002-7557-0003

Abstract

With the advent of deep learning algorithms, fully automated radiological image analysis is within reach. In spine imaging, several atlas- and shape-based as well as deep learning segmentation algorithms have been proposed, allowing for subsequent automated analysis of morphology and pathology. The first “Large Scale Vertebrae Segmentation Challenge” (VerSe 2019) showed that these perform well on normal anatomy, but fail in variants not frequently present in the training dataset. Building on that experience, we report on the largely increased VerSe 2020 dataset and results from the second iteration of the VerSe challenge (MICCAI 2020, Lima, Peru). VerSe 2020 comprises annotated spine computed tomography (CT) images from 300 subjects with 4142 fully visualized and annotated vertebrae, collected across multiple centres from four different scanner manufacturers, enriched with cases that exhibit anatomical variants such as enumeration abnormalities (n = 77) and transitional vertebrae (n = 161). Metadata includes vertebral labelling information, voxel-level segmentation masks obtained with a human-machine hybrid algorithm and anatomical ratings, to enable the development and benchmarking of robust and accurate segmentation algorithms.

Published
2021

32. A computed tomography vertebral segmentation dataset with anatomical variations and multi-vendor scanner data

Author

Liebl, Hans, Schinz, David, Sekuboyina, Anjany, Malagutti, Luca, Löffler, Maximilian T., Bayat, Amirhossein, El Husseini, Malek, Tetteh, Giles, Grau, Katharina, Niederreiter, Eva, Baum, Thomas, Wiestler, Benedikt, Menze, Bjoern, Braren, Rickmer, Zimmer, Claus, and Kirschke, Jan S.

Subjects
ddc, Data Descriptor, Bone, Computer science, Medical research, Scientific data
Published
2020

33. Claustrum volumes are lower in schizophrenia and mediate patients' attentional deficits.

Author

Schinz D, Neubauer A, Hippen R, Schulz J, Li HB, Thalhammer M, Schmitz-Koep B, Menegaux A, Wendt J, Ayyildiz S, Brandl F, Priller J, Uder M, Zimmer C, Hedderich MD, and Sorg C

Abstract

Background: While the last decade of extensive research revealed the prominent role of the claustrum for mammalian forebrain organization, i.e., widely distributed claustral-cortical circuits coordinate basic cognitive functions such as attention, it is poorly understood whether the claustrum is relevant for schizophrenia and related cognitive symptoms. We hypothesized firstly, that claustrum volumes are lower in schizophrenia and secondarily, that potentially lower volumes mediate patients' attention deficits., Methods: Based on T1-weighted MRI, advanced automated claustrum segmentation, and attention symbol coding task (SCT) in 90 patients with schizophrenia and 96 healthy controls from two independent sites, the COBRE open-source database and MUNICH dataset, we compared total-intracranial-volume-normalized claustrum volumes and SCT scores across groups via ANCOVA and related variables via correlation and mediation analysis., Results: Patients had lower claustrum volumes of about 13 % (p<0.001, Hedges g=0.63), which not only correlated with (r=0.24, p=0.014) but also mediated lower SCT scores (indirect effect ab = -1.30 ± 0.69; CI [-3.73; -1.04]). Results were not confounded by age, sex, global and claustrum-adjacent gray matter changes, scanner site, smoking, and medication., Conclusions: Results demonstrate lower claustrum volumes that mediate patients' attention deficits in schizophrenia. Data indicate the claustrum as being relevant for schizophrenia pathophysiology and cognitive functioning., (Copyright © 2024. Published by Elsevier Inc.)

Published
2024
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34. LST-AI: a Deep Learning Ensemble for Accurate MS Lesion Segmentation.

Author

Wiltgen T, McGinnis J, Schlaeger S, Kofler F, Voon C, Berthele A, Bischl D, Grundl L, Will N, Metz M, Schinz D, Sepp D, Prucker P, Schmitz-Koep B, Zimmer C, Menze B, Rueckert D, Hemmer B, Kirschke J, Mühlau M, and Wiestler B

Abstract

Automated segmentation of brain white matter lesions is crucial for both clinical assessment and scientific research in multiple sclerosis (MS). Over a decade ago, we introduced an engineered lesion segmentation tool, LST. While recent lesion segmentation approaches have leveraged artificial intelligence (AI), they often remain proprietary and difficult to adopt. As an open-source tool, we present LST-AI, an advanced deep learning-based extension of LST that consists of an ensemble of three 3D-UNets. LST-AI explicitly addresses the imbalance between white matter (WM) lesions and non-lesioned WM. It employs a composite loss function incorporating binary cross-entropy and Tversky loss to improve segmentation of the highly heterogeneous MS lesions. We train the network ensemble on 491 MS pairs of T1w and FLAIR images, collected in-house from a 3T MRI scanner, and expert neuroradiologists manually segmented the utilized lesion maps for training. LST-AI additionally includes a lesion location annotation tool, labeling lesion location according to the 2017 McDonald criteria (periventricular, infratentorial, juxtacortical, subcortical). We conduct evaluations on 103 test cases consisting of publicly available data using the Anima segmentation validation tools and compare LST-AI with several publicly available lesion segmentation models. Our empirical analysis shows that LST-AI achieves superior performance compared to existing methods. Its Dice and F1 scores exceeded 0.62, outperforming LST, SAMSEG (Sequence Adaptive Multimodal SEGmentation), and the popular nnUNet framework, which all scored below 0.56. Notably, LST-AI demonstrated exceptional performance on the MSSEG-1 challenge dataset, an international WM lesion segmentation challenge, with a Dice score of 0.65 and an F1 score of 0.63-surpassing all other competing models at the time of the challenge. With increasing lesion volume, the lesion detection rate rapidly increased with a detection rate of >75% for lesions with a volume between 10mm 3 and 100mm 3 . Given its higher segmentation performance, we recommend that research groups currently using LST transition to LST-AI. To facilitate broad adoption, we are releasing LST-AI as an open-source model, available as a command-line tool, dockerized container, or Python script, enabling diverse applications across multiple platforms., Competing Interests: Declaration of Competing Interests: The authors declare no competing interests.

Published
2024
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