Machine learning-enhanced digital microscopy for personalized assessment of red blood cell storage lesions.

IF 1.6 4区医学 Q3 HEMATOLOGY

Vox Sanguinis Pub Date : 2025-08-31 DOI:10.1111/vox.70103

Jiang Deng, Hailong Zhuo, Chaojie Wang, Ning Zhao, Liping Lv, Ping Ma, Tao Wu, Qun Luo, Ke Zhang, Yanyu Zhang

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引用次数: 0

Abstract

Background and objectives: This study aims to develop a novel platform combining machine learning and microscope images for personalized assessment of red blood cell (RBC) storage lesions. RBCs undergo storage lesions, which adversely affect transfusion outcomes. Currently, there is no individualized assessment method for RBC aging applicable in clinical practice.

Materials and methods: Blood smears and cytospin preparations from stored donor RBCs were digitized using whole-slide scanning. Predictive models were developed and validated using classical machine learning, deep learning and ensemble learning techniques. These models were tested against various datasets and validated with flow cytometry. The training dataset comprised 550,870 images, the internal testing set included 192,562 images and the external testing set contained 350,793 images. Models such as k-nearest neighbour, support vector machine, extra trees, DenseNet-121, InceptionV3 and ResNet101 were employed, with ensemble learning leveraging InceptionV3 for enhanced performance.

Results: Classical machine learning models showed modest performance, whereas deep learning models (DenseNet-121, InceptionV3, ResNet101) significantly outperformed them, achieving accuracy rates up to 0.86 on the internal testing set and 0.83 on the external testing set. The RBC morphology ensemble learning model (RBC-MELM) further enhanced predictive capabilities, particularly in the blood smear and cytospin datasets. Comparative analyses with flow cytometry indicated that while flow cytometry detected accelerated aging under certain conditions, our machine learning approaches more effectively identified RBCs exhibiting accelerated aging.

Conclusion: The proposed method utilizing machine learning techniques and microscopic blood smear analysis provides a rapid, accurate and stable approach for the personalized assessment of RBC storage lesions.

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机器学习增强的数字显微镜用于红细胞储存病变的个性化评估。

背景与目的：本研究旨在开发一种结合机器学习和显微镜图像的新平台，用于红细胞（RBC）储存病变的个性化评估。红细胞会发生储存损伤，这对输血结果有不利影响。目前还没有适用于临床的个体化红细胞老化评估方法。材料和方法：采用全片扫描技术对供体红细胞的血涂片和细胞自旋制品进行数字化处理。使用经典的机器学习、深度学习和集成学习技术开发和验证了预测模型。这些模型在不同的数据集上进行了测试，并用流式细胞术进行了验证。训练数据集包含550,870张图像，内部测试集包含192,562张图像，外部测试集包含350,793张图像。采用了k近邻、支持向量机、额外树、DenseNet-121、InceptionV3和ResNet101等模型，集成学习利用InceptionV3来增强性能。结果：经典机器学习模型表现一般，而深度学习模型（DenseNet-121, InceptionV3, ResNet101）的表现明显优于它们，在内部测试集上的准确率高达0.86，在外部测试集上的准确率高达0.83。RBC形态学集合学习模型（RBC- melm）进一步增强了预测能力，特别是在血液涂片和细胞自旋数据集中。与流式细胞术的比较分析表明，流式细胞术在某些条件下检测到加速老化，而我们的机器学习方法更有效地识别出加速老化的红细胞。结论：利用机器学习技术和显微血液涂片分析的方法为红细胞积存病变的个性化评估提供了一种快速、准确和稳定的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Vox Sanguinis 医学-血液学

CiteScore

4.40

自引率

11.10%

发文量

156

审稿时长

6-12 weeks

期刊介绍： Vox Sanguinis reports on important, novel developments in transfusion medicine. Original papers, reviews and international fora are published on all aspects of blood transfusion and tissue transplantation, comprising five main sections: 1) Transfusion - Transmitted Disease and its Prevention: Identification and epidemiology of infectious agents transmissible by blood; Bacterial contamination of blood components; Donor recruitment and selection methods; Pathogen inactivation. 2) Blood Component Collection and Production: Blood collection methods and devices (including apheresis); Plasma fractionation techniques and plasma derivatives; Preparation of labile blood components; Inventory management; Hematopoietic progenitor cell collection and storage; Collection and storage of tissues; Quality management and good manufacturing practice; Automation and information technology. 3) Transfusion Medicine and New Therapies: Transfusion thresholds and audits; Haemovigilance; Clinical trials regarding appropriate haemotherapy; Non-infectious adverse affects of transfusion; Therapeutic apheresis; Support of transplant patients; Gene therapy and immunotherapy. 4) Immunohaematology and Immunogenetics: Autoimmunity in haematology; Alloimmunity of blood; Pre-transfusion testing; Immunodiagnostics; Immunobiology; Complement in immunohaematology; Blood typing reagents; Genetic markers of blood cells and serum proteins: polymorphisms and function; Genetic markers and disease; Parentage testing and forensic immunohaematology. 5) Cellular Therapy: Cell-based therapies; Stem cell sources; Stem cell processing and storage; Stem cell products; Stem cell plasticity; Regenerative medicine with cells; Cellular immunotherapy; Molecular therapy; Gene therapy.