Developing a low-cost, open-source, locally manufactured workstation and computational pipeline for automated histopathology evaluation using deep learning.

IF 9.7 1区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL EBioMedicine Pub Date : 2024-09-01 Epub Date: 2024-08-27 DOI:10.1016/j.ebiom.2024.105276
Divya Choudhury, James M Dolezal, Emma Dyer, Sara Kochanny, Siddhi Ramesh, Frederick M Howard, Jayson R Margalus, Amelia Schroeder, Jefree Schulte, Marina C Garassino, Jakob N Kather, Alexander T Pearson
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引用次数: 0

Abstract

Background: Deployment and access to state-of-the-art precision medicine technologies remains a fundamental challenge in providing equitable global cancer care in low-resource settings. The expansion of digital pathology in recent years and its potential interface with diagnostic artificial intelligence algorithms provides an opportunity to democratize access to personalized medicine. Current digital pathology workstations, however, cost thousands to hundreds of thousands of dollars. As cancer incidence rises in many low- and middle-income countries, the validation and implementation of low-cost automated diagnostic tools will be crucial to helping healthcare providers manage the growing burden of cancer.

Methods: Here we describe a low-cost ($230) workstation for digital slide capture and computational analysis composed of open-source components. We analyze the predictive performance of deep learning models when they are used to evaluate pathology images captured using this open-source workstation versus images captured using common, significantly more expensive hardware. Validation studies assessed model performance on three distinct datasets and predictive models: head and neck squamous cell carcinoma (HPV positive versus HPV negative), lung cancer (adenocarcinoma versus squamous cell carcinoma), and breast cancer (invasive ductal carcinoma versus invasive lobular carcinoma).

Findings: When compared to traditional pathology image capture methods, low-cost digital slide capture and analysis with the open-source workstation, including the low-cost microscope device, was associated with model performance of comparable accuracy for breast, lung, and HNSCC classification. At the patient level of analysis, AUROC was 0.84 for HNSCC HPV status prediction, 1.0 for lung cancer subtype prediction, and 0.80 for breast cancer classification.

Interpretation: Our ability to maintain model performance despite decreased image quality and low-power computational hardware demonstrates that it is feasible to massively reduce costs associated with deploying deep learning models for digital pathology applications. Improving access to cutting-edge diagnostic tools may provide an avenue for reducing disparities in cancer care between high- and low-income regions.

Funding: Funding for this project including personnel support was provided via grants from NIH/NCIR25-CA240134, NIH/NCIU01-CA243075, NIH/NIDCRR56-DE030958, NIH/NCIR01-CA276652, NIH/NCIK08-CA283261, NIH/NCI-SOAR25CA240134, SU2C (Stand Up to Cancer) Fanconi Anemia Research Fund - Farrah Fawcett Foundation Head and Neck Cancer Research Team Grant, and the European UnionHorizon Program (I3LUNG).

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开发低成本、开源、本地制造的工作站和计算管道,利用深度学习进行自动组织病理学评估。
背景:部署和获取最先进的精准医疗技术仍然是在低资源环境中提供公平的全球癌症治疗所面临的基本挑战。近年来,数字病理学的发展及其与人工智能诊断算法的潜在接口,为个性化医疗的普及提供了机会。然而,目前的数字病理工作站价格高达数千至数十万美元。随着许多中低收入国家癌症发病率的上升,低成本自动诊断工具的验证和实施对于帮助医疗服务提供者管理日益加重的癌症负担至关重要。方法:在此,我们介绍了一种由开源组件组成的低成本(230 美元)数字幻灯片捕获和计算分析工作站。我们分析了深度学习模型在评估使用该开源工作站捕获的病理图像与使用昂贵得多的普通硬件捕获的图像时的预测性能。验证研究评估了三个不同数据集和预测模型的模型性能:头颈部鳞状细胞癌(HPV 阳性与 HPV 阴性)、肺癌(腺癌与鳞状细胞癌)和乳腺癌(浸润性导管癌与浸润性小叶癌):与传统的病理图像采集方法相比,使用开源工作站(包括低成本显微镜设备)进行低成本数字切片采集和分析,在乳腺癌、肺癌和 HNSCC 分类方面的模型准确性相当。在患者分析层面,HNSCC HPV 状态预测的 AUROC 为 0.84,肺癌亚型预测为 1.0,乳腺癌分类为 0.80:我们能够在图像质量下降和低功耗计算硬件的情况下保持模型的性能,这表明在数字病理学应用中部署深度学习模型是可以大幅降低成本的。改善尖端诊断工具的获取途径可为缩小高收入和低收入地区之间的癌症治疗差距提供一条途径:本项目的资金包括人员支持由 NIH/NCIR25-CA240134、NIH/NCIU01-CA243075、NIH/NIDCRR56-DE030958、NIH/NCIR01-CA276652、NIH/NCIK08-CA283261 提供、NIH/NCI-SOAR25CA240134、SU2C(Stand Up to Cancer)范可尼贫血症研究基金--法拉-福赛特基金会头颈癌研究团队资助以及欧盟地平线计划(I3LUNG)。
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来源期刊
EBioMedicine
EBioMedicine Biochemistry, Genetics and Molecular Biology-General Biochemistry,Genetics and Molecular Biology
CiteScore
17.70
自引率
0.90%
发文量
579
审稿时长
5 weeks
期刊介绍: eBioMedicine is a comprehensive biomedical research journal that covers a wide range of studies that are relevant to human health. Our focus is on original research that explores the fundamental factors influencing human health and disease, including the discovery of new therapeutic targets and treatments, the identification of biomarkers and diagnostic tools, and the investigation and modification of disease pathways and mechanisms. We welcome studies from any biomedical discipline that contribute to our understanding of disease and aim to improve human health.
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