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AI Model TxGNN Utilizes Zero-Shot Learning to Repurpose Drugs for Rare Diseases



Iris Coleman
Oct 02, 2024 17:20

Harvard scientists develop TxGNN, an AI model using zero-shot learning to identify new uses for existing drugs, potentially closing treatment gaps for rare diseases.





A groundbreaking AI model known as TxGNN is offering new hope in the treatment of rare diseases by repurposing existing drugs, according to a report by the NVIDIA Technical Blog. This innovative tool leverages zero-shot learning to help doctors find new therapeutic uses for drugs that are already on the market.

Revolutionizing Rare Disease Treatment

The study, recently published in Nature Medicine, was led by scientists from Harvard University. The research highlights the potential of TxGNN to reduce the time and cost associated with drug development, thereby delivering effective treatments to patients much more quickly. “With this tool, we aim to identify new therapies across the disease spectrum, particularly for rare, ultrarare, and neglected conditions,” said Marinka Zitnik, an assistant professor of biomedical informatics at Harvard Medical School.

Globally, over 300 million people are affected by more than 7,000 rare or undiagnosed diseases. Alarmingly, only about 7% of these rare diseases have an FDA-approved drug treatment, leaving many patients waiting for new therapies.

Innovative Approach with Graph Neural Networks

Traditional drug-repurposing models often struggle with rare diseases due to a lack of data. TxGNN addresses this limitation by using graph neural networks (GNNs) to analyze complex relationships and patterns in large medical datasets, which include information on diseases, drugs, and proteins. This allows the AI model to understand and predict how a drug could influence a specific condition.

The researchers trained and fine-tuned TxGNN using NVIDIA V100 and H100 Tensor Core GPUs. Zitnik emphasized the importance of these GPUs in processing the extensive medical knowledge graph, which spans 17,080 diseases and nearly 8,000 drugs.

Improved Predictions and Real-World Applications

During testing, TxGNN improved treatment predictions by up to 19% without being trained on the specific disease. The AI model also outperformed existing models in predicting contraindications—situations where a drug should not be used. Moreover, its treatment suggestions often matched medications that doctors prescribe off-label for specific conditions.

TxGNN provides transparent explanations for its predictions, allowing medical experts to review and gain insights into the AI’s reasoning. This transparency is crucial for building trust in AI-driven medical decisions.

For those interested in exploring TxGNN, the TxGNN Explorer offers a visual interface to learn more about this innovative tool.

Read the full story from Harvard Medical School.

Image source: Shutterstock


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