MBZUAI graduate Ahmed Sharshar developed a computer vision application that assesses lung health from a video of a person breathing, estimating Forced Vital Capacity (FVC), Forced Expiratory Volume in 1 second (FEV1), and Peak Expiratory Flow (PEF). The model achieved up to 100% accuracy using thermal video data from 60 participants. Sharshar aims to create lightweight models applicable in developing countries without high-end GPUs. Why it matters: This research showcases the potential of AI to democratize healthcare access through non-invasive, accessible diagnostic tools.
KAUST is supporting Saudi Arabia's healthcare modernization by translating laboratory research into smart, digital, and precise solutions. One example is the Social and Personal Adaptive Response Kit (SPARK), an AI-driven technology integrating behavioral analysis, wearable multi-sensor systems, and human body communication to support children with autism. KAUST researchers have also developed a fully printed wireless electrocardiogram system and a smart bandage for various applications. Why it matters: These innovations align with Saudi Vision 2030 and have the potential to improve healthcare outcomes in Saudi Arabia and globally through personalized, remote care.
MBZUAI researchers have introduced MIRA, a novel framework for improving the factual accuracy of multimodal large language models in medical applications. MIRA uses calibrated retrieval to manage factual risk and integrates image embeddings with a medical knowledge base for efficient reasoning. Evaluated on medical VQA and report generation benchmarks, MIRA achieves state-of-the-art results, with code available on GitHub.
KAUST is collaborating with medical centers and Alfaisal University to integrate smart and digital tools into the Saudi healthcare system. A key objective is to improve understanding of disease mechanisms for better diagnosis, treatment, and prevention, aligning with KSA's Vision 2030. KAUST has partnered with Alfaisal University to establish the Kingdom’s first M.D./Ph.D. program. Why it matters: These partnerships aim to transition Saudi Arabia's healthcare system towards precision and personalized medicine by training practitioners in AI and smart technologies.
Researchers propose a universal anatomical embedding (UAE) framework for medical image analysis to learn appearance, semantic, and cross-modality anatomical embeddings. UAE incorporates semantic embedding learning with prototypical contrastive loss, a fixed-point-based matching strategy, and an iterative approach for cross-modality embedding learning. The framework was evaluated on landmark detection, lesion tracking and CT-MRI registration tasks, outperforming existing state-of-the-art methods.
Pascal Fua from EPFL gave a talk at MBZUAI on physics-based deep learning for medical imaging. The talk covered how self-supervision and knowledge of human anatomy and physics can improve deep learning algorithms when training data is limited. Applications discussed included endoscopic heart surgery, colonoscopy, and intubation. Why it matters: This highlights the growing importance of domain knowledge and self-supervision in overcoming data scarcity challenges for AI in healthcare applications within the region.
KAUST and the International Medical Center (IMC) have signed an MoU to collaborate on medical research related to wellness, quality of life, and population health management. The partnership aims to develop AI applications for diagnosis and treatment, along with research in precision medicine and advanced therapies. The collaboration aligns with Saudi Vision 2030's goals to build a sustainable, knowledge-driven healthcare future. Why it matters: This agreement signifies a push to integrate AI and precision medicine into practical medical solutions within the Saudi healthcare system.