By enabling the development of accurate, privacy-preserving models from distributed datasets, FEDCOV allows healthcare providers to collaboratively build predictive models for COVID-19 severity, long-term symptoms, and treatment outcomes without sharing sensitive patient data. This approach ensures that patient information remains secure, while still enabling the creation of robust models that can improve clinical decision-making and personalized treatment plans. Additionally, the project addresses fairness and interpretability, ensuring that the models are unbiased and transparent, which is crucial for equitable healthcare delivery across diverse patient populations.​

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AI-driven models are being developed to enhance the diagnosis and treatment of infections and post-acute infection syndromes. These models will analyze complex datasets to uncover host-pathogen interactions and predict disease progression. The goal is to provide targeted, effective interventions that improve recovery outcomes and reduce healthcare burdens.​

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Based on the dataset from the ELISE project, a rule-based labeling model was created, on the basis of which a prediction model is being developed that can predict sepsis 6 to 12 hours before the onset of the disease. This model should enable early therapy and help to prevent the negative effects of sepsis on the course of critically ill children.​

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The proposed symbolic learning approach utilizes an ontological abstraction of domain knowledge to guide the extraction of interpretable and semantically valid Horn rules from a knowledge graph. The application of domain knowledge is instrumental in facilitating the extraction of interpretable and semantically valid information. A neuro-symbolic system that integrates symbolic learning from medical ontologies, inductive learning, and semantic constraint validation to extract interpretable Horn rules from knowledge graph. When applied to the context of lung cancer care, our approach enhances the prediction of novel medical relationships while ensuring semantic alignment with established domain knowledge.

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ME/CFS is a common, severe, and complex condition with a wide range of symptoms, often triggered by infections. Around 500,000 people are affected in Germany. DETECT-ME/CFS aims to develop software to support and improve the diagnostic process. The software includes a feedback loop with clinicians to enable continuous quality improvement.

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As many patients suffer from post-acute infection syndromes (PAIS), it is essential to investigate effective prevention strategies. Since these syndromes can be triggered by various infections, an intervention strategy should be developed from a population-level perspective. The AIMS project uses AI-driven population simulations to design and test such strategies, aiming to minimize the overall burden of PAIS.

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As many patients suffer from post-acute infection syndromes (PAIS), it is essential to investigate effective prevention strategies. Since these syndromes can be triggered by various infections, an intervention strategy should be developed from a population-level perspective. The AIMS project uses AI-driven population simulations to design and test such strategies, aiming to minimize the overall burden of PAIS.

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