神经影像学
人工智能
计算机科学
基础(证据)
神经科学
功能磁共振成像
磁共振成像
机器学习
人脑
芯(光纤)
深度学习
大脑定位
大脑活动与冥想
生物标志物
人工神经网络
领域(数学)
医学影像学
计算模型
人类智力
功能连接
大脑研究
神经信息学
脑解剖学
作者
Divyanshu Tak,Biniam A. Garomsa,Anna Zapaishchykova,Tafadzwa L. Chaunzwa,Juan Carlos Pardo,Zezhong Ye,John Zielke,Yashwanth Ravipati,Suraj Pai,Sri Vajapeyam,Maryam Mahootiha,Mitchell I. Parker,Luke R. G. Pike,Ceilidh Smith,Ariana Familiar,Kevin X. Liu,Sanjay P. Prabhu,Omar Arnaout,Pratiti Bandopadhayay,Ali Nabavizadeh
标识
DOI:10.1038/s41593-026-02202-6
摘要
Artificial intelligence applied to brain magnetic resonance imaging (MRI) holds potential to advance diagnosis, prognosis and treatment planning for neurological diseases. The field has been constrained, thus far, by limited training data and task-specific models that do not generalize well across patient populations and medical tasks. By leveraging self-supervised learning, pretraining and targeted adaptation, foundation models present a promising paradigm to overcome these limitations. Here we present Brain Imaging Adaptive Core (BrainIAC)-a foundation model designed to learn generalized representations from unlabeled brain MRI data and serve as a core basis for diverse downstream application adaptation. Trained and validated on 48,965 brain MRIs across a broad spectrum of tasks, we demonstrate that BrainIAC outperforms localized supervised training and other pretrained models, particularly in low-data, few-shot, settings and in high-difficulty prediction tasks, allowing for application in scenarios otherwise infeasible. BrainIAC can be integrated into imaging pipelines and multimodal frameworks and may lead to improved biomarker discovery and artificial intelligence clinical translation.
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