Your search keyword '"Marcinkevičs, Ričards"' showing total 20 results

1. Stochastic Concept Bottleneck Models

Author

Vandenhirtz, Moritz, Laguna, Sonia, Marcinkevičs, Ričards, and Vogt, Julia E.

Subjects

Computer Science - Machine Learning

Abstract

Concept Bottleneck Models (CBMs) have emerged as a promising interpretable method whose final prediction is based on intermediate, human-understandable concepts rather than the raw input. Through time-consuming manual interventions, a user can correct wrongly predicted concept values to enhance the model's downstream performance. We propose Stochastic Concept Bottleneck Models (SCBMs), a novel approach that models concept dependencies. In SCBMs, a single-concept intervention affects all correlated concepts, thereby improving intervention effectiveness. Unlike previous approaches that model the concept relations via an autoregressive structure, we introduce an explicit, distributional parameterization that allows SCBMs to retain the CBMs' efficient training and inference procedure. Additionally, we leverage the parameterization to derive an effective intervention strategy based on the confidence region. We show empirically on synthetic tabular and natural image datasets that our approach improves intervention effectiveness significantly. Notably, we showcase the versatility and usability of SCBMs by examining a setting with CLIP-inferred concepts, alleviating the need for manual concept annotations., Comment: Published at 38th Conference on Neural Information Processing Systems (NeurIPS 2024)

Published

2024

2. Beyond Concept Bottleneck Models: How to Make Black Boxes Intervenable?

Author

Laguna, Sonia, Marcinkevičs, Ričards, Vandenhirtz, Moritz, and Vogt, Julia E.

Subjects

Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

Recently, interpretable machine learning has re-explored concept bottleneck models (CBM). An advantage of this model class is the user's ability to intervene on predicted concept values, affecting the downstream output. In this work, we introduce a method to perform such concept-based interventions on pretrained neural networks, which are not interpretable by design, only given a small validation set with concept labels. Furthermore, we formalise the notion of intervenability as a measure of the effectiveness of concept-based interventions and leverage this definition to fine-tune black boxes. Empirically, we explore the intervenability of black-box classifiers on synthetic tabular and natural image benchmarks. We focus on backbone architectures of varying complexity, from simple, fully connected neural nets to Stable Diffusion. We demonstrate that the proposed fine-tuning improves intervention effectiveness and often yields better-calibrated predictions. To showcase the practical utility of our techniques, we apply them to deep chest X-ray classifiers and show that fine-tuned black boxes are more intervenable than CBMs. Lastly, we establish that our methods are still effective under vision-language-model-based concept annotations, alleviating the need for a human-annotated validation set., Comment: 38th Conference on Neural Information Processing Systems (NeurIPS 2024)

Published

2024

3. Signal Is Harder To Learn Than Bias: Debiasing with Focal Loss

Author

Vandenhirtz, Moritz, Manduchi, Laura, Marcinkevičs, Ričards, and Vogt, Julia E.

Subjects

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

Abstract

Spurious correlations are everywhere. While humans often do not perceive them, neural networks are notorious for learning unwanted associations, also known as biases, instead of the underlying decision rule. As a result, practitioners are often unaware of the biased decision-making of their classifiers. Such a biased model based on spurious correlations might not generalize to unobserved data, leading to unintended, adverse consequences. We propose Signal is Harder (SiH), a variational-autoencoder-based method that simultaneously trains a biased and unbiased classifier using a novel, disentangling reweighting scheme inspired by the focal loss. Using the unbiased classifier, SiH matches or improves upon the performance of state-of-the-art debiasing methods. To improve the interpretability of our technique, we propose a perturbation scheme in the latent space for visualizing the bias that helps practitioners become aware of the sources of spurious correlations., Comment: Presented at the Domain Generalization Workshop (ICLR 2023)

Published

2023

4. Interpretable and intervenable ultrasonography-based machine learning models for pediatric appendicitis

Author

Marcinkevičs, Ričards, Wolfertstetter, Patricia Reis, Klimiene, Ugne, Chin-Cheong, Kieran, Paschke, Alyssia, Zerres, Julia, Denzinger, Markus, Niederberger, David, Wellmann, Sven, Ozkan, Ece, Knorr, Christian, and Vogt, Julia E.

Subjects

Computer Science - Machine Learning, Computer Science - Computer Vision and Pattern Recognition, Electrical Engineering and Systems Science - Image and Video Processing, Statistics - Applications

Abstract

Appendicitis is among the most frequent reasons for pediatric abdominal surgeries. Previous decision support systems for appendicitis have focused on clinical, laboratory, scoring, and computed tomography data and have ignored abdominal ultrasound, despite its noninvasive nature and widespread availability. In this work, we present interpretable machine learning models for predicting the diagnosis, management and severity of suspected appendicitis using ultrasound images. Our approach utilizes concept bottleneck models (CBM) that facilitate interpretation and interaction with high-level concepts understandable to clinicians. Furthermore, we extend CBMs to prediction problems with multiple views and incomplete concept sets. Our models were trained on a dataset comprising 579 pediatric patients with 1709 ultrasound images accompanied by clinical and laboratory data. Results show that our proposed method enables clinicians to utilize a human-understandable and intervenable predictive model without compromising performance or requiring time-consuming image annotation when deployed. For predicting the diagnosis, the extended multiview CBM attained an AUROC of 0.80 and an AUPR of 0.92, performing comparably to similar black-box neural networks trained and tested on the same dataset., Comment: Published in Medical Image Analysis (Elsevier)

Published

2023

5. Introduction to Machine Learning for Physicians: A Survival Guide for Data Deluge

Author

Marcinkevičs, Ričards, Ozkan, Ece, and Vogt, Julia E.

Subjects

Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

Many modern research fields increasingly rely on collecting and analysing massive, often unstructured, and unwieldy datasets. Consequently, there is growing interest in machine learning and artificial intelligence applications that can harness this `data deluge'. This broad nontechnical overview provides a gentle introduction to machine learning with a specific focus on medical and biological applications. We explain the common types of machine learning algorithms and typical tasks that can be solved, illustrating the basics with concrete examples from healthcare. Lastly, we provide an outlook on open challenges, limitations, and potential impacts of machine-learning-powered medicine.

Published

2022

6. Debiasing Deep Chest X-Ray Classifiers using Intra- and Post-processing Methods

Author

Marcinkevičs, Ričards, Ozkan, Ece, and Vogt, Julia E.

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

Deep neural networks for image-based screening and computer-aided diagnosis have achieved expert-level performance on various medical imaging modalities, including chest radiographs. Recently, several works have indicated that these state-of-the-art classifiers can be biased with respect to sensitive patient attributes, such as race or gender, leading to growing concerns about demographic disparities and discrimination resulting from algorithmic and model-based decision-making in healthcare. Fair machine learning has focused on mitigating such biases against disadvantaged or marginalised groups, mainly concentrating on tabular data or natural images. This work presents two novel intra-processing techniques based on fine-tuning and pruning an already-trained neural network. These methods are simple yet effective and can be readily applied post hoc in a setting where the protected attribute is unknown during the model development and test time. In addition, we compare several intra- and post-processing approaches applied to debiasing deep chest X-ray classifiers. To the best of our knowledge, this is one of the first efforts studying debiasing methods on chest radiographs. Our results suggest that the considered approaches successfully mitigate biases in fully connected and convolutional neural networks offering stable performance under various settings. The discussed methods can help achieve group fairness of deep medical image classifiers when deploying them in domains with different fairness considerations and constraints., Comment: MLHC 2022

Published

2022

7. A Deep Variational Approach to Clustering Survival Data

Author

Manduchi, Laura, Marcinkevičs, Ričards, Massi, Michela C., Weikert, Thomas, Sauter, Alexander, Gotta, Verena, Müller, Timothy, Vasella, Flavio, Neidert, Marian C., Pfister, Marc, Stieltjes, Bram, and Vogt, Julia E.

Subjects

Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

In this work, we study the problem of clustering survival data $-$ a challenging and so far under-explored task. We introduce a novel semi-supervised probabilistic approach to cluster survival data by leveraging recent advances in stochastic gradient variational inference. In contrast to previous work, our proposed method employs a deep generative model to uncover the underlying distribution of both the explanatory variables and censored survival times. We compare our model to the related work on clustering and mixture models for survival data in comprehensive experiments on a wide range of synthetic, semi-synthetic, and real-world datasets, including medical imaging data. Our method performs better at identifying clusters and is competitive at predicting survival times. Relying on novel generative assumptions, the proposed model offers a holistic perspective on clustering survival data and holds a promise of discovering subpopulations whose survival is regulated by different generative mechanisms., Comment: ICLR 2022

Published

2021

8. Interpretable Models for Granger Causality Using Self-explaining Neural Networks

Author

Marcinkevičs, Ričards and Vogt, Julia E.

Subjects

Computer Science - Machine Learning, Statistics - Machine Learning

Abstract

Exploratory analysis of time series data can yield a better understanding of complex dynamical systems. Granger causality is a practical framework for analysing interactions in sequential data, applied in a wide range of domains. In this paper, we propose a novel framework for inferring multivariate Granger causality under nonlinear dynamics based on an extension of self-explaining neural networks. This framework is more interpretable than other neural-network-based techniques for inferring Granger causality, since in addition to relational inference, it also allows detecting signs of Granger-causal effects and inspecting their variability over time. In comprehensive experiments on simulated data, we show that our framework performs on par with several powerful baseline methods at inferring Granger causality and that it achieves better performance at inferring interaction signs. The results suggest that our framework is a viable and more interpretable alternative to sparse-input neural networks for inferring Granger causality., Comment: ICLR 2021

Published

2021

9. Interpretability and Explainability: A Machine Learning Zoo Mini-tour

Author

Marcinkevičs, Ričards and Vogt, Julia E.

Subjects

Computer Science - Machine Learning

Abstract

In this review, we examine the problem of designing interpretable and explainable machine learning models. Interpretability and explainability lie at the core of many machine learning and statistical applications in medicine, economics, law, and natural sciences. Although interpretability and explainability have escaped a clear universal definition, many techniques motivated by these properties have been developed over the recent 30 years with the focus currently shifting towards deep learning methods. In this review, we emphasise the divide between interpretability and explainability and illustrate these two different research directions with concrete examples of the state-of-the-art. The review is intended for a general machine learning audience with interest in exploring the problems of interpretation and explanation beyond logistic regression or random forest variable importance. This work is not an exhaustive literature survey, but rather a primer focusing selectively on certain lines of research which the authors found interesting or informative., Comment: A preprint version of the 2023 WIREs Data Mining and Knowledge Discovery article

Published

2020

10. Interpretable and intervenable ultrasonography-based machine learning models for pediatric appendicitis

Author

Marcinkevičs, Ričards, Reis Wolfertstetter, Patricia, Klimiene, Ugne, Chin-Cheong, Kieran, Paschke, Alyssia, Zerres, Julia, Denzinger, Markus, Niederberger, David, Wellmann, Sven, Ozkan, Ece, Knorr, Christian, and Vogt, Julia E.

Published

2024

11. Discovery of Important Subsequences in Electrocardiogram Beats Using the Nearest Neighbour Algorithm

Author

Marcinkevics, Ricards, Kelk, Steven, Galuzzi, Carlo, and Stegemann, Berthold

Subjects

Computer Science - Machine Learning, Quantitative Biology - Quantitative Methods, Statistics - Machine Learning

Abstract

The classification of time series data is a well-studied problem with numerous practical applications, such as medical diagnosis and speech recognition. A popular and effective approach is to classify new time series in the same way as their nearest neighbours, whereby proximity is defined using Dynamic Time Warping (DTW) distance, a measure analogous to sequence alignment in bioinformatics. However, practitioners are not only interested in accurate classification, they are also interested in why a time series is classified a certain way. To this end, we introduce here the problem of finding a minimum length subsequence of a time series, the removal of which changes the outcome of the classification under the nearest neighbour algorithm with DTW distance. Informally, such a subsequence is expected to be relevant for the classification and can be helpful for practitioners in interpreting the outcome. We describe a simple but optimized implementation for detecting these subsequences and define an accompanying measure to quantify the relevance of every time point in the time series for the classification. In tests on electrocardiogram data we show that the algorithm allows discovery of important subsequences and can be helpful in detecting abnormalities in cardiac rhythms distinguishing sick from healthy patients.

Published

2019

12. Self-supervised Disentanglement of Modality-Specific and Shared Factors Improves Multimodal Generative Models

Author

Daunhawer, Imant, Sutter, Thomas M., Marcinkevičs, Ričards, Vogt, Julia E., Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Akata, Zeynep, editor, Geiger, Andreas, editor, and Sattler, Torsten, editor

Published

2021

13. Breathing New Life into COPD Assessment: Multisensory Home-monitoring for Predicting Severity

Author

Xiao, Zixuan, primary, Muszynski, Michal, additional, Marcinkevičs, Ričards, additional, Zimmerli, Lukas, additional, Ivankay, Adam Daniel, additional, Kohlbrenner, Dario, additional, Kuhn, Manuel, additional, Nordmann, Yves, additional, Muehlner, Ulrich, additional, Clarenbach, Christian, additional, Vogt, Julia E., additional, and Brunschwiler, Thomas, additional

Published

2023

14. Multimodal Remote Home Monitoring of Lung Transplant Recipients during COVID-19 Vaccinations: Usability Pilot Study of the COVIDA Desk Incorporating Wearable Devices

Author

Schuurmans, Macé M., primary, Muszynski, Michal, additional, Li, Xiang, additional, Marcinkevičs, Ričards, additional, Zimmerli, Lukas, additional, Monserrat Lopez, Diego, additional, Michel, Bruno, additional, Weiss, Jonas, additional, Hage, René, additional, Roeder, Maurice, additional, Vogt, Julia E., additional, and Brunschwiler, Thomas, additional

Published

2023

15. Multimodal Remote Home Monitoring of Lung Transplant Recipients during COVID-19 Vaccinations: Usability Pilot Study of the COVIDA Desk Incorporating Wearable Devices

Author

Schuurmans, Macé M; https://orcid.org/0000-0001-5404-7566, Muszynski, Michal; https://orcid.org/0000-0002-0763-2612, Li, Xiang, Marcinkevičs, Ričards; https://orcid.org/0000-0001-8901-5062, Zimmerli, Lukas, Monserrat Lopez, Diego, Michel, Bruno; https://orcid.org/0000-0002-1104-846X, Weiss, Jonas, Hage, René; https://orcid.org/0000-0002-1994-7443, Roeder, Maurice; https://orcid.org/0000-0002-4261-0881, Vogt, Julia E, Brunschwiler, Thomas; https://orcid.org/0000-0002-7254-3405, Schuurmans, Macé M; https://orcid.org/0000-0001-5404-7566, Muszynski, Michal; https://orcid.org/0000-0002-0763-2612, Li, Xiang, Marcinkevičs, Ričards; https://orcid.org/0000-0001-8901-5062, Zimmerli, Lukas, Monserrat Lopez, Diego, Michel, Bruno; https://orcid.org/0000-0002-1104-846X, Weiss, Jonas, Hage, René; https://orcid.org/0000-0002-1994-7443, Roeder, Maurice; https://orcid.org/0000-0002-4261-0881, Vogt, Julia E, and Brunschwiler, Thomas; https://orcid.org/0000-0002-7254-3405

Abstract

Background and Objectives: Remote patient monitoring (RPM) of vital signs and symptoms for lung transplant recipients (LTRs) has become increasingly relevant in many situations. Nevertheless, RPM research integrating multisensory home monitoring in LTRs is scarce. We developed a novel multisensory home monitoring device and tested it in the context of COVID-19 vaccinations. We hypothesize that multisensory RPM and smartphone-based questionnaire feedback on signs and symptoms will be well accepted among LTRs. To assess the usability and acceptability of a remote monitoring system consisting of wearable devices, including home spirometry and a smartphone-based questionnaire application for symptom and vital sign monitoring using wearable devices, during the first and second SARS-CoV-2 vaccination. Materials and Methods: Observational usability pilot study for six weeks of home monitoring with the COVIDA Desk for LTRs. During the first week after the vaccination, intensive monitoring was performed by recording data on physical activity, spirometry, temperature, pulse oximetry and self-reported symptoms, signs and additional measurements. During the subsequent days, the number of monitoring assessments was reduced. LTRs reported on their perceptions of the usability of the monitoring device through a purpose-designed questionnaire. Results: Ten LTRs planning to receive the first COVID-19 vaccinations were recruited. For the intensive monitoring study phase, LTRs recorded symptoms, signs and additional measurements. The most frequent adverse events reported were local pain, fatigue, sleep disturbance and headache. The duration of these symptoms was 5–8 days post-vaccination. Adherence to the main monitoring devices was high. LTRs rated usability as high. The majority were willing to continue monitoring. Conclusions: The COVIDA Desk showed favorable technical performance and was well accepted by the LTRs during the vaccination phase of the pandemic. The feasibility of the

Published

2023

16. Machine learning analysis of humoral and cellular responses to SARS-CoV-2 infection in young adults

Author

Marcinkevičs, Ričards, Silva, Pamuditha N., Hankele, Anna-Katharina, Dörnte, Charlyn, Kadelka, Sarah, Csik, Katharina, Godbersen, Svenja, Goga, Algera, Hasenöhrl, Lynn, Hirschi, Pascale, Kabakci, Hasan, LaPierre, Mary P., Mayrhofer, Johanna, Title, Alexandra C., Shu, Xuan, Baiioud, Nouell, Bernal, Sandra, Dassisti, Laura, Saenz-de-Juano, Mara D., Schmidhauser, Meret, Silvestrelli, Giulia, Ulbrich, Simon Z., Ulbrich, Thea J., Wyss, Tamara, Stekhoven, Daniel, Al-Quaddoomi, Faisal S., Yu, Shuqing, Binder, Mascha, Schultheiβ, Christoph, Zindel, Claudia, Kolling, Christoph, Goldhahn, Jörg, Kasmapour Seighalani, Bahram, Zjablovskaja, Polina, Hardung, Frank, Schuster, Marc, Richter, Anne, Huang, Yi-Ju, Lauer, Gereon, Baurmann, Herrad, Low, Jun Siong, Vaqueirinho, Daniela, Jovic, Sandra, Piccoli, Luca, Ciesek, Sandra, Vogt, Julia E., Sallusto, Federica, Stoffel, Markus, and Ulbrich, Susanne E.

Subjects

machine learning, SARS-CoV-2, Immunology, Immunology and Allergy, neutralizing antibodies, antibody titers, T cell response

Abstract

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) induces B and T cell responses, contributing to virus neutralization. In a cohort of 2,911 young adults, we identified 65 individuals who had an asymptomatic or mildly symptomatic SARS-CoV-2 infection and characterized their humoral and T cell responses to the Spike (S), Nucleocapsid (N) and Membrane (M) proteins. We found that previous infection induced CD4 T cells that vigorously responded to pools of peptides derived from the S and N proteins. By using statistical and machine learning models, we observed that the T cell response highly correlated with a compound titer of antibodies against the Receptor Binding Domain (RBD), S and N. However, while serum antibodies decayed over time, the cellular phenotype of these individuals remained stable over four months. Our computational analysis demonstrates that in young adults, asymptomatic and paucisymptomatic SARS-CoV-2 infections can induce robust and long-lasting CD4 T cell responses that exhibit slower decays than antibody titers. These observations imply that next-generation COVID-19 vaccines should be designed to induce stronger cellular responses to sustain the generation of potent neutralizing antibodies., Frontiers in Immunology, 14, ISSN:1664-3224

Published

2023

17. Interpretable and explainable machine learning: A methods‐centric overview with concrete examples

Author

Marcinkevičs, Ričards, primary and Vogt, Julia E., additional

Published

2023

18. Multiview Concept Bottleneck Models Applied to Diagnosing Pediatric Appendicitis

Author

Klimiene, Ugne, Marcinkevičs, Ričards, Reis Wolfertstetter, Patricia, Özkan Elsen, Ece, Paschke, Alyssia, Niederberger, David, Wellmann, Sven, Knorr, Christian, and Vogt, Julia E.

Subjects

Machine Learning, Explainable ML, Appendicitis, Interpretability, Classification, Ultrasonography, Precision medicine

Abstract

Arguably, interpretability is one of the guiding principles behind the development of machine-learning-based healthcare decision support tools and computer-aided diagnosis systems. There has been a renewed interest in interpretable classification based on high-level concepts, including, among other model classes, the re-exploration of concept bottleneck models. By their nature, medical diagnosis, patient management, and monitoring require the assessment of multiple views and modalities to form a holistic representation of the patient's state. For instance, in ultrasound imaging, a region of interest might be registered from multiple views that are informative about different sets of clinically relevant features. Motivated by this, we extend the classical concept bottleneck model to the multiview classification setting by representation fusion across the views. We apply our multiview concept bottleneck model to the dataset of ultrasound images acquired from a cohort of pediatric patients with suspected appendicitis to predict the disease. The results suggest that auxiliary supervision from the concepts and aggregation across multiple views help develop more accurate and interpretable classifiers.

Published

2022

19. A Deep Variational Approach to Clustering Survival Data

Author

Manduchi, Laura, Marcinkevičs, Ričards, Massi, Michela C., Weikert, Thomas, Sauter, Alexander, Gotta, Verena, Müller, Timothy, Vasella, Flavio, Neidert, Marian C., Pfister, Marc, Stieltjes, Bram, and Vogt, Julia E.

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Cluster analysis, Statistics - Machine Learning, Machine learning, Survival analysis, Variational autoencoder, Deep Generative Models, Machine Learning (stat.ML), Machine Learning (cs.LG)

Abstract

In this work, we study the problem of clustering survival data $-$ a challenging and so far under-explored task. We introduce a novel semi-supervised probabilistic approach to cluster survival data by leveraging recent advances in stochastic gradient variational inference. In contrast to previous work, our proposed method employs a deep generative model to uncover the underlying distribution of both the explanatory variables and censored survival times. We compare our model to the related work on clustering and mixture models for survival data in comprehensive experiments on a wide range of synthetic, semi-synthetic, and real-world datasets, including medical imaging data. Our method performs better at identifying clusters and is competitive at predicting survival times. Relying on novel generative assumptions, the proposed model offers a holistic perspective on clustering survival data and holds a promise of discovering subpopulations whose survival is regulated by different generative mechanisms., Comment: ICLR 2022

Published

2022

20. Debiasing Neural Networks using Differentiable Classification Parity Proxies

Author

Marcinkevičs, Ričards, Özkan Elsen, Ece, and Vogt, Julia E.

Subjects

Fairness, Debiasing, Classification, Neural networks

Abstract

Due to growing concerns about demographic disparities and discrimination resulting from algorithmic and model-based decision-making, recent research has focused on mitigating biases against already disadvantaged or marginalised groups in classification models. From the perspective of classification parity, the two commonest metrics for assessing fairness are statistical parity and equality of opportunity. Current approaches to debiasing in classification either require the knowledge of the protected attribute before or during training or are entirely agnostic to the model class and parameters. This work considers differentiable proxy functions for statistical parity and equality of opportunity and introduces two novel debiasing techniques for neural network classifiers based on fine-tuning and pruning an already-trained network. As opposed to the prior work leveraging adversarial training, the proposed methods are simple yet effective and can be readily applied post hoc. Our experimental results encouragingly suggest that these approaches successfully debias fully connected neural networks trained on tabular data and often outperform model-agnostic post-processing methods.

Published

2022