Your search keyword '"Tinauer C"' showing total 6 results

1. RELEVANCE-GUIDED DEEP LEARNING FOR FEATURE IDENTIFICATION IN R2* MAPS IN ALZHEIMER���S DISEASE CLASSIFICATION

Author

Tinauer, C., Heber, S., Pirpamer, L., Damulina, A., Soellradl, M., Sackl, M., and Hofer, E.

Published

2021

2. Fully Automated Hippocampus Segmentation using T2-informed Deep Convolutional Neural Networks.

Author

Sackl M, Tinauer C, Urschler M, Enzinger C, Stollberger R, and Ropele S

Subjects

Humans, Image Processing, Computer-Assisted methods, Neural Networks, Computer, Male, Female, Aged, Alzheimer Disease diagnostic imaging, Alzheimer Disease pathology, Neuroimaging methods, Neuroimaging standards, Hippocampus diagnostic imaging, Hippocampus pathology, Magnetic Resonance Imaging methods, Deep Learning

Abstract

Hippocampal atrophy (tissue loss) has become a fundamental outcome parameter in clinical trials on Alzheimer's disease. To accurately estimate hippocampus volume and track its volume loss, a robust and reliable segmentation is essential. Manual hippocampus segmentation is considered the gold standard but is extensive, time-consuming, and prone to rater bias. Therefore, it is often replaced by automated programs like FreeSurfer, one of the most commonly used tools in clinical research. Recently, deep learning-based methods have also been successfully applied to hippocampus segmentation. The basis of all approaches are clinically used T1-weighted whole-brain MR images with approximately 1 mm isotropic resolution. However, such T1 images show low contrast-to-noise ratios (CNRs), particularly for many hippocampal substructures, limiting delineation reliability. To overcome these limitations, high-resolution T2-weighted scans are suggested for better visualization and delineation, as they show higher CNRs and usually allow for higher resolutions. Unfortunately, such time-consuming T2-weighted sequences are not feasible in a clinical routine. We propose an automated hippocampus segmentation pipeline leveraging deep learning with T2-weighted MR images for enhanced hippocampus segmentation of clinical T1-weighted images based on a series of 3D convolutional neural networks and a specifically acquired multi-contrast dataset. This dataset consists of corresponding pairs of T1- and high-resolution T2-weighted images, with the T2 images only used to create more accurate manual ground truth annotations and to train the segmentation network. The T2-based ground truth labels were also used to evaluate all experiments by comparing the masks visually and by various quantitative measures. We compared our approach with four established state-of-the-art hippocampus segmentation algorithms (FreeSurfer, ASHS, HippoDeep, HippMapp3r) and demonstrated a superior segmentation performance. Moreover, we found that the automated segmentation of T1-weighted images benefits from the T2-based ground truth data. In conclusion, this work showed the beneficial use of high-resolution, T2-based ground truth data for training an automated, deep learning-based hippocampus segmentation and provides the basis for a reliable estimation of hippocampal atrophy in clinical studies., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Evaluation of a self-administered iPad ® -based processing speed assessment for people with multiple sclerosis in a clinical routine setting.

Author

Hechenberger S, Helmlinger B, Tinauer C, Jauk E, Ropele S, Heschl B, Wurth S, Damulina A, Eppinger S, Demjaha R, Khalil M, Enzinger C, and Pinter D

Subjects

Humans, Male, Female, Middle Aged, Adult, Feasibility Studies, Magnetic Resonance Imaging, Aged, Processing Speed, Multiple Sclerosis diagnostic imaging, Neuropsychological Tests, Cognitive Dysfunction etiology, Cognitive Dysfunction diagnosis, Cognitive Dysfunction diagnostic imaging, Computers, Handheld

Abstract

Background: Limited resources often hinder regular cognitive assessment of people with multiple sclerosis (pwMS) in standard clinical care. A self-administered iPad®-based cognitive screening-tool (Processing Speed Test; PST) might mitigate this problem., Objective: To evaluate the PST in clinical routine., Methods: We investigated the feasibility of the PST in both a quiet and a waiting room setting. We assessed the validity of the PST in comparison with the established Symbol Digit Modalities Test (SDMT). We explored associations between processing speed assessments and the Brief International Cognitive Assessment for MS (BICAMS), magnetic resonance imaging (MRI) parameters, and psychological factors. Additionally, we explored the ability of the PST to detect impairment in processing speed compared to the SDMT., Results: The PST was feasible in the waiting room setting. PST and SDMT correlated comparably with the BICAMS, MRI parameters, and psychological variables. Of 172 pwMS, 50 (30.8%) showed cognitive impairment according to the BICAMS; respective values were 47 (27.3%) for the SDMT and 9 (5.2%) for the PST., Conclusions: The PST performed in a waiting room setting correlates strongly with established cognitive tests. It thus may be used to assess processing speed in a resource-efficient manner and complement cognitive assessment in clinical routine. Despite comparable validity of the PST and SDMT, we identified more pwMS with impaired processing speed using normative data of the SDMT compared to the PST and advise caution, that the common cut-off score of - 1.5 SD from the current PST is not appropriate in Europe., (© 2024. The Author(s).)

Published

2024

4. Interpretable brain disease classification and relevance-guided deep learning.

Author

Tinauer C, Heber S, Pirpamer L, Damulina A, Schmidt R, Stollberger R, Ropele S, and Langkammer C

Subjects

Humans, Middle Aged, Aged, Aged, 80 and over, Head, Brain diagnostic imaging, Atrophy, Alzheimer Disease diagnostic imaging, Deep Learning

Abstract

Deep neural networks are increasingly used for neurological disease classification by MRI, but the networks' decisions are not easily interpretable by humans. Heat mapping by deep Taylor decomposition revealed that (potentially misleading) image features even outside of the brain tissue are crucial for the classifier's decision. We propose a regularization technique to train convolutional neural network (CNN) classifiers utilizing relevance-guided heat maps calculated online during training. The method was applied using T1-weighted MR images from 128 subjects with Alzheimer's disease (mean age = 71.9 ± 8.5 years) and 290 control subjects (mean age = 71.3 ± 6.4 years). The developed relevance-guided framework achieves higher classification accuracies than conventional CNNs but more importantly, it relies on less but more relevant and physiological plausible voxels within brain tissue. Additionally, preprocessing effects from skull stripping and registration are mitigated. With the interpretability of the decision mechanisms underlying CNNs, these results challenge the notion that unprocessed T1-weighted brain MR images in standard CNNs yield higher classification accuracy in Alzheimer's disease than solely atrophy., (© 2022. The Author(s).)

Published

2022

5. Heritability of R2* iron in the basal ganglia and cortex.

Author

Hofer E, Pirpamer L, Langkammer C, Tinauer C, Seshadri S, Schmidt H, and Schmidt R

Subjects

Aged, Brain, Cerebral Cortex diagnostic imaging, Humans, Magnetic Resonance Imaging, Middle Aged, Basal Ganglia, Iron

Abstract

Background: While iron is essential for normal brain functioning, elevated concentrations are commonly found in neurodegenerative diseases and are associated with impaired cognition and neurological deficits. Currently, only little is known about genetic and environmental factors that influence brain iron concentrations., Methods: Heritability and bivariate heritability of regional brain iron concentrations, assessed by R2* relaxometry at 3 Tesla MRI, were estimated with variance components models in 130 middle-aged to elderly participants of the Austrian Stroke Prevention Family Study., Results: Heritability of R2* iron ranged from 0.46 to 0.82 in basal ganglia and from 0.65 to 0.76 in cortical lobes. Age and BMI explained up to 12% and 9% of the variance of R2* iron, while APOE ε4 carrier status, hypertension, diabetes, hypercholesterolemia, sex and smoking explained 5% or less. The genetic correlation of R2* iron among basal ganglionic nuclei and among cortical lobes ranged from 0.78 to 0.87 and from 0.65 to 0.97, respectively. R2* rates in basal ganglia and cortex were not genetically correlated., Conclusions: Regional brain iron concentrations are mainly driven by genetic factors while environmental factors contribute to a certain extent. Brain iron levels in the basal ganglia and cortex are controlled by distinct sets of genes.

Published

2022

6. Cross-sectional and Longitudinal Assessment of Brain Iron Level in Alzheimer Disease Using 3-T MRI.

Author

Damulina A, Pirpamer L, Soellradl M, Sackl M, Tinauer C, Hofer E, Enzinger C, Gesierich B, Duering M, Ropele S, Schmidt R, and Langkammer C

Subjects

Aged, Aged, 80 and over, Humans, Middle Aged, Prospective Studies, Alzheimer Disease diagnostic imaging, Brain diagnostic imaging, Brain Chemistry physiology, Iron analysis, Magnetic Resonance Imaging methods

Abstract

Background Deep gray matter structures in patients with Alzheimer disease (AD) contain higher brain iron concentrations. However, few studies have included neocortical areas, which are challenging to assess with MRI. Purpose To investigate baseline and change in brain iron levels using MRI at 3 T with R2* relaxation rate mapping in individuals with AD compared with healthy control (HC) participants. Materials and Methods In this prospective study, participants with AD recruited between 2010 and 2016 and age-matched HC participants selected from 2010 to 2014 were evaluated. Of 100 participants with AD, 56 underwent subsequent neuropsychological testing and brain MRI at a mean follow-up of 17 months. All participants underwent 3-T MRI, including R2* mapping corrected for macroscopic B0 field inhomogeneities. Anatomic structures were segmented, and median R2* values were calculated in the neocortex and cortical lobes, basal ganglia (BG), hippocampi, and thalami. Multivariable linear regression analysis was applied to study the difference in R2* levels between groups and the association between longitudinal changes in R2* values and cognition in the AD group. Results A total of 100 participants with AD (mean age, 73 years ± 9 [standard deviation]; 58 women) and 100 age-matched HC participants (mean age, 73 years ± 9; 60 women) were evaluated. Median R2* levels were higher in the AD group than in the HC group in the BG (HC, 29.0 sec -1 ; AD, 30.2 sec -1 ; P = .01) and total neocortex (HC, 17.0 sec -1 ; AD, 17.4 sec -1 ; P < .001) and regionally in the occipital (HC, 19.6 sec -1 ; AD, 20.2 sec -1 ; P = .007) and temporal (HC, 16.4 sec -1 ; AD, 18.1 sec -1 ; P < .001) lobes. R2* values in the temporal lobe were associated with longitudinal changes in Consortium to Establish a Registry for Alzheimer's Disease total score (β = -3.23 score/sec -1 , P = .003) in participants with AD independent of longitudinal changes in brain volume. Conclusion Iron concentration in the deep gray matter and neocortical regions was higher in patients with Alzheimer disease than in healthy control participants. Change in iron levels over time in the temporal lobe was associated with cognitive decline in individuals with Alzheimer disease. © RSNA, 2020 Online supplemental material is available for this article.

Published

2020