血细胞革命:利用 "归化 "增强技术揭示 11 种不同类型的血细胞

IF 1.8 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Algorithms Pub Date : 2023-12-10 DOI:10.3390/a16120562
Mohamad Abou Ali, F. Dornaika, Ignacio Arganda-Carreras
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引用次数: 0

摘要

人工智能(AI)已成为一种尖端工具,可同时加快、确保和加强对病人的诊断和治疗。外周血涂片(PBS)分析就是这种能力的一个例证。在大学医疗中心,血液学专家每天都要例行检查数百张 PBS 切片,以验证或纠正先进的血液分析仪在评估可能有问题的病人样本时产生的结果。从逻辑上讲,这一过程可能会导致 PBC 读数错误,给患者健康带来风险。人工智能是一种变革性工具,可显著提高读数和诊断的准确性和精确度。这项研究重塑了血细胞分类的参数,利用人工智能的能力,通过具有挑战性的 11 类 PBC 数据集,将特定血细胞类别从 5 类扩大到 11 类。这种转变有助于对血细胞多样性进行更深入的探索,超越了医学图像分析中以往的限制。我们的方法结合了最先进的深度学习技术,包括预训练 ConvNets、ViTb16 模型和定制 CNN 架构。我们采用迁移学习、微调和集合策略(如 CBAM 和平均集合)来实现前所未有的准确性和可解释性。我们的完全微调 EfficientNetV2 B0 模型树立了新的标准,其宏观平均精度、召回率和 F1 分数分别达到 91%、90% 和 90%,平均准确率达到 93%。这一突破凸显了 11 级血细胞分类在更精确医疗诊断方面的变革潜力。此外,我们开创性的 "Naturalize "增强技术也取得了显著效果。利用 "Naturalize "技术生成的 2K-PBC 数据集的宏观平均精确度、召回率和 F1 分数均达到 97%,而利用经过全面微调的 EfficientNetV2 B0 模型生成的数据集的平均精确度则达到 96%。这一创新不仅提高了分类性能,还解决了医学深度学习中的数据稀缺和偏差问题。我们的研究标志着血细胞分类领域的范式转变,使医学分析更加细致入微、更具洞察力。Naturalize "技术的影响超越了血细胞分类,强调了多样化和全面的数据集在通过深度学习推进医疗应用方面的重要作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Blood Cell Revolution: Unveiling 11 Distinct Types with ‘Naturalize’ Augmentation
Artificial intelligence (AI) has emerged as a cutting-edge tool, simultaneously accelerating, securing, and enhancing the diagnosis and treatment of patients. An exemplification of this capability is evident in the analysis of peripheral blood smears (PBS). In university medical centers, hematologists routinely examine hundreds of PBS slides daily to validate or correct outcomes produced by advanced hematology analyzers assessing samples from potentially problematic patients. This process may logically lead to erroneous PBC readings, posing risks to patient health. AI functions as a transformative tool, significantly improving the accuracy and precision of readings and diagnoses. This study reshapes the parameters of blood cell classification, harnessing the capabilities of AI and broadening the scope from 5 to 11 specific blood cell categories with the challenging 11-class PBC dataset. This transformation facilitates a more profound exploration of blood cell diversity, surpassing prior constraints in medical image analysis. Our approach combines state-of-the-art deep learning techniques, including pre-trained ConvNets, ViTb16 models, and custom CNN architectures. We employ transfer learning, fine-tuning, and ensemble strategies, such as CBAM and Averaging ensembles, to achieve unprecedented accuracy and interpretability. Our fully fine-tuned EfficientNetV2 B0 model sets a new standard, with a macro-average precision, recall, and F1-score of 91%, 90%, and 90%, respectively, and an average accuracy of 93%. This breakthrough underscores the transformative potential of 11-class blood cell classification for more precise medical diagnoses. Moreover, our groundbreaking “Naturalize” augmentation technique produces remarkable results. The 2K-PBC dataset generated with “Naturalize” boasts a macro-average precision, recall, and F1-score of 97%, along with an average accuracy of 96% when leveraging the fully fine-tuned EfficientNetV2 B0 model. This innovation not only elevates classification performance but also addresses data scarcity and bias in medical deep learning. Our research marks a paradigm shift in blood cell classification, enabling more nuanced and insightful medical analyses. The “Naturalize” technique’s impact extends beyond blood cell classification, emphasizing the vital role of diverse and comprehensive datasets in advancing healthcare applications through deep learning.
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来源期刊
Algorithms
Algorithms Mathematics-Numerical Analysis
CiteScore
4.10
自引率
4.30%
发文量
394
审稿时长
11 weeks
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