Unbiased Morphometric Assessment of Red Blood Cell Storage Lesion in the Presence of Shear-Induced Stomatocytes.

IF 1.9 4区医学 Q3 HEMATOLOGY

Transfusion Medicine and Hemotherapy Pub Date : 2024-08-22 eCollection Date: 2025-06-01 DOI:10.1159/000539882

Clemens Boecker, Jose Luis Halblaub Miranda, Harald Klüter, Hajo Suhr, Karen Bieback, Philipp Wiedemann

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引用次数: 0

Abstract

Introduction: Red blood cells (RBCs) undergo progressive biochemical and morphological changes during storage, collectively called storage lesion. The quality of red cell concentrates (RCCs) is typically assessed by quantifying hemolysis. An assessment of morphological changes, associated with low quality RBCs, could give an additional indication of the safety and efficacy of the concentrates. The current standard for determining morphological changes is a manual, laborious, and subjectively biased microscopic process that limits the number of cells that can be examined. When using alternative methods like flow cells, flow and shear-induced morphologies affecting especially stomatocyte morphologies must be taken into account. We already established an automated flow morphometric RBC analysis system as an alternative to manual microscopic evaluation. The goal of the present work is to obtain a robust, automated, morphology-related signal (lesion index) quantifying RBC storage lesion in a laminar flow channel under conditions similar to stasis that is not affected by shear-induced reversible morphology changes.

Methods: We use a convolutional neural network (CNN) for high throughput classification of RBCs. We analyzed the morphological changes of 5 RCCs over a period of 12 weeks and classified RBC morphologies, including such that are degradation-induced and reversible. We introduce a lesion index to denote the percentage of irreversible spherical morphologies, known to reduce the post-transfusion survival of erythrocytes. We further addressed shear-induced stomatocyte morphologies in laminar flow and whether these affect CNN-based RBC classification.

Results: Our flow morphometry system achieves a high-resolution classification comprising nine morphological classes with an excellent overall accuracy of 92% and F₁ scores between 84% and 97%. We generate strong evidence that the morphological lesion index can predict the hemolysis level in RCCs during storage. The power of this new classification technique allowed it, for the first time, to detect and measure the lateral concentration gradient of stomatocytes in a conventional flow chamber. Importantly, we show that reversible shear rate-induced morphologies, typical for microfluidic systems, bear no influence on the lesion index.

Conclusion: Flow morphometry combined with evaluation by a CNN allows to reliably assess RBC storage lesion and thus concentrate quality. Additionally, this method reduces the need for complex laboratory procedures.

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剪切诱导的口细胞存在时红细胞储存损伤的无偏态形态学评估。

红细胞在贮藏过程中发生进行性生化和形态变化，统称为贮藏损伤。红细胞浓缩物（RCCs）的质量通常通过定量溶血来评估。形态学变化的评估，与低质量红细胞相关，可以提供浓缩物安全性和有效性的额外指示。目前确定形态变化的标准是一个人工的、费力的、主观偏见的显微过程，这限制了可以检查的细胞的数量。当使用流动细胞等替代方法时，必须考虑流动和剪切诱导的形态学，尤其是影响气孔细胞形态学的形态学。我们已经建立了一个自动流动形态测量红细胞分析系统，作为人工显微镜评估的替代方案。本研究的目标是获得一种鲁棒的、自动化的、形态相关的信号（病变指数），量化层流通道中红细胞储存病变，这种情况类似于停滞状态，不受剪切诱导的可逆形态变化的影响。方法：采用卷积神经网络（CNN）对红细胞进行高通量分类。我们分析了5例rcc在12周内的形态变化，并对RBC形态进行了分类，包括降解诱导的和可逆的。我们引入一个病变指数来表示不可逆球形形态的百分比，已知会降低输血后红细胞的存活率。我们进一步研究了剪切诱导的层流中气孔细胞形态，以及这些形态是否影响基于cnn的红细胞分类。结果：我们的流形态测量系统实现了包括9个形态类的高分辨率分类，总体准确率达到92%，F1得分在84%到97%之间。我们产生了强有力的证据，形态学病变指数可以预测在rcc储存期间溶血水平。这种新的分类技术的力量使它第一次能够检测和测量传统流室中气孔细胞的横向浓度梯度。重要的是，我们表明可逆剪切速率诱导的形态，典型的微流体系统，对损伤指数没有影响。结论：血流形态学结合CNN评价可以可靠地评估红细胞积存病变，从而提高浓缩物的质量。此外，这种方法减少了对复杂实验室程序的需要。

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

Transfusion Medicine and Hemotherapy 医学-免疫学

CiteScore

4.00

自引率

9.10%

发文量

审稿时长

6-12 weeks

期刊介绍： This journal is devoted to all areas of transfusion medicine. These include the quality and security of blood products, therapy with blood components and plasma derivatives, transfusion-related questions in transplantation, stem cell manipulation, therapeutic and diagnostic problems of homeostasis, immuno-hematological investigations, and legal aspects of the production of blood products as well as hemotherapy. Both comprehensive reviews and primary publications that detail the newest work in transfusion medicine and hemotherapy promote the international exchange of knowledge within these disciplines. Consistent with this goal, continuing clinical education is also specifically addressed.