Integrating Knowledge Graphs with Symbolic AI: The Path to Interpretable Hybrid AI Systems in Medicine
Maria-Esther Vidal,
Yashrajsinh Chudasama,
Hao Huang,
Disha Purohit,
Maria Torrente
Affiliations
Maria-Esther Vidal
Leibniz University of Hannover, Hannover, 30159, Germany; TIB-Leibniz Information Centre for Science and Technology, Hannover, 30159, Germany; L3S Research Center, Leibniz University of Hannover, Hannover, 30167, Germany; Corresponding author at: Leibniz University of Hannover, Hannover, 30159, Germany.
Yashrajsinh Chudasama
Leibniz University of Hannover, Hannover, 30159, Germany; TIB-Leibniz Information Centre for Science and Technology, Hannover, 30159, Germany
Hao Huang
Leibniz University of Hannover, Hannover, 30159, Germany; TIB-Leibniz Information Centre for Science and Technology, Hannover, 30159, Germany
Disha Purohit
Leibniz University of Hannover, Hannover, 30159, Germany; TIB-Leibniz Information Centre for Science and Technology, Hannover, 30159, Germany
Maria Torrente
Hospital Universitario Puerta de Hierro-Majadahonda, Madrid, 28222, Spain
Knowledge Graphs (KGs) are graph-based structures that integrate heterogeneous data, capture domain knowledge, and enable explainable AI through symbolic reasoning. This position paper examines the challenges and research opportunities in integrating KGs with neuro-symbolic AI, highlighting their potential to enhance explainability, scalability, and context-aware reasoning in hybrid AI systems. Using a lung cancer use case, we illustrate how hybrid approaches address tasks such as link prediction—uncovering hidden relationships in medical data—and counterfactual reasoning—analyzing alternative scenarios to understand causal factors. The discussion is framed around TrustKG, which demonstrates how constraint validation, causal reasoning, and user-centric communication can support transparent and reliable decision-making. Additionally, we identify current limitations of KGs, including gaps in knowledge coverage, evolving data integration challenges, and the need for improved usability and impact assessment. These insights are not limited to healthcare but extend to other domains like energy, manufacturing, and mobility, showcasing the broad applicability of KGs. Finally, we propose research directions to unlock their full potential in building robust, transparent, and widely adopted real-world applications.
