用于预测航天相关神经-眼部综合征的人工智能深度学习模型
Artificial Intelligence Deep Learning Models to Predict Spaceflight Associated Neuro-Ocular Syndrome.
作者信息
Huang Alex S, Jalili Jalil, Walker Evan, Weinreb Robert N, Laurie Steven S, Macias Brandon R, Christopher Mark
机构信息
From the Hamilton Glaucoma Center (A.S.H., J.J., E.W., R.N.W., and M.C.), The Viterbi Family Department of Ophthalmology, Shiley Eye Institute, University of California, San Diego, California, USA.
From the Hamilton Glaucoma Center (A.S.H., J.J., E.W., R.N.W., and M.C.), The Viterbi Family Department of Ophthalmology, Shiley Eye Institute, University of California, San Diego, California, USA.
出版信息
Am J Ophthalmol. 2025 Oct;278:115-123. doi: 10.1016/j.ajo.2025.06.009. Epub 2025 Jun 10.
PURPOSE
To create deep learning artificial intelligence (AI) models for predicting the development of Spaceflight Associated Neuro-Ocular Syndrome (SANS) using optical coherence tomography (OCT) imaging of the optic nerve head.
DESIGN
Retrospective analysis.
METHODS
AI deep learning models were trained to predict SANS onset by using two OCT datasets: pre- and inflight OCT images acquired from astronauts (flight data) and pre- and in-bedrest images from research participants undergoing head-down tilt bedrest as an Earth-bound model of SANS (ground data). Both datasets were partitioned by participant into training and testing data. Resnet50-based models were trained using exclusively flight data, exclusively ground data, and a combination of both. All models were evaluated based on their ability to predict SANS using only pre-flight or pre-bedrest imaging in both datasets. Performance was assessed using receiver operating characteristic areas under the curve (AUC). Class activation maps (CAMs) were generated to identify impactful image regions.
RESULTS
The model trained on flight data achieved an AUC (95% CI) of 0.82 (0.54-1.0) on flight data and 0.67 (0.51-0.83) on ground data. The ground-trained model achieved an AUC of 0.71 (0.50-0.91) on ground data and 0.76 (0.51-0.91) on flight data. The combined model achieved an AUC of 0.81 (0.53-0.95) and 0.72 (0.52-0.92) on flight and ground data, respectively. CAMs identified peripapillary regions of the nerve fiber layer, retinal pigmented epithelium, and anterior lamina surface as most important for predictions.
CONCLUSIONS
AI models can predict SANS based on pre-flight OCT imaging with moderate-to-high performance even in this data-limited setting. The performance of cross-trained models and similarity in CAMs suggests similarity between SANS-related changes in flight and ground datasets, proving further support that head-down tilt bedrest is a reasonable Earth-bound model for SANS. NOTE: Publication of this article is sponsored by the American Ophthalmological Society.
目的
利用视神经乳头的光学相干断层扫描(OCT)成像创建深度学习人工智能(AI)模型,以预测航天相关神经眼部综合征(SANS)的发生。
设计
回顾性分析。
方法
通过使用两个OCT数据集训练AI深度学习模型来预测SANS的发病:从宇航员获取的飞行前和飞行中的OCT图像(飞行数据),以及作为SANS的地面模型进行头低位卧床休息的研究参与者的卧床前和卧床中的图像(地面数据)。两个数据集均按参与者划分为训练数据和测试数据。基于Resnet50的模型分别仅使用飞行数据、仅使用地面数据以及两者的组合进行训练。所有模型均根据其仅使用两个数据集中的飞行前或卧床前成像来预测SANS的能力进行评估。使用曲线下的受试者操作特征面积(AUC)评估性能。生成类激活映射(CAM)以识别有影响的图像区域。
结果
在飞行数据上训练的模型在飞行数据上的AUC(95%可信区间)为0.82(0.54 - 1.0),在地面数据上为0.67(0.51 - 0.83)。在地面训练的模型在地面数据上的AUC为0.71(0.50 - 0.91),在飞行数据上为0.76(0.51 - 0.91)。组合模型在飞行数据和地面数据上的AUC分别为0.81(0.53 - 0.95)和0.72(0.52 - 0.92)。CAM识别出神经纤维层、视网膜色素上皮和前板层表面的视乳头周围区域对预测最为重要。
结论
即使在这种数据有限的情况下,AI模型也可以基于飞行前OCT成像以中到高性能预测SANS。交叉训练模型的性能以及CAM中的相似性表明飞行和地面数据集中与SANS相关的变化之间存在相似性,进一步证明头低位卧床休息是SANS合理的地面模型。注:本文的发表由美国眼科学会赞助。
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