Quantifying HiPSC-CM structural organization at scale with deep learning-enhanced SarcGraph.

IF 3.6 2区生物学 Q1 BIOCHEMICAL RESEARCH METHODS

PLoS Computational Biology Pub Date : 2025-10-03 eCollection Date: 2025-10-01 DOI:10.1371/journal.pcbi.1013436

Saeed Mohammadzadeh, Emma Lejeune

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引用次数: 0

Abstract

In cardiac cells, structural organization is an important indicator of cell maturity and healthy function. Healthy and mature cardiomyocytes exhibit a highly organized structure, characterized by well-aligned almost crystalline morphology with densely packed and organized sarcomeres. Immature and/or diseased cardiomyocytes typically lack this highly organized structure. Critically, human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) offer a valuable model for studying human cardiac cells in a controlled, patient-specific, and minimally invasive manner. However, these cells often exhibit a disorganized and difficult to quantify structure both in their immature form and as disease models. In this work, we extend the SarcGraph computational framework-designed specifically to assess the structural and functional behavior of hiPSC-CMs-to better accommodate the structural features of immature cells. There are two key enhancements: (1) incorporating a deep learning-based z-disc classifier, and (2) introducing a novel ensemble graph-scoring approach. These modification significantly reduced false positive sarcomere detections, particularly in immature cells, and improved the detection of longer myofibrils in mature samples. With this enhanced framework, we analyze an open-source dataset published by the Allen Institute for Cell Science, where, for the first time, we are able to extract key structural features from these data using information from each individually detected sarcomere. Not only are we able to use these structural features to predict expert scores, but we are also able to use these structural features to identify bias in expert scoring and offer an alternative unsupervised learning approach based on explainable clustering. These results demonstrate the efficacy of our modified SarcGraph algorithm in extracting biologically meaningful structural features, enabling a deeper understanding of hiPSC-CM structural integrity. By making our code and tools open-source, we aim to empower the broader cardiac research community and foster further development of computational tools for cardiac tissue analysis.

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利用深度学习增强SarcGraph量化HiPSC-CM结构组织。

在心脏细胞中，结构组织是细胞成熟和健康功能的重要指标。健康和成熟的心肌细胞表现出高度组织化的结构，其特征是排列良好的近乎结晶的形态和密集排列和有组织的肌节。未成熟和/或病变心肌细胞通常缺乏这种高度组织化的结构。重要的是，人类诱导多能干细胞衍生的心肌细胞（hiPSC-CMs）提供了一个有价值的模型，以一种可控的、患者特异性的、微创的方式研究人类心脏细胞。然而，这些细胞在其未成熟形态和作为疾病模型时往往表现出无序和难以量化的结构。在这项工作中，我们扩展了SarcGraph计算框架（专门用于评估hipsc - cms的结构和功能行为），以更好地适应未成熟细胞的结构特征。有两个关键的增强：(1)结合了基于深度学习的z-disc分类器，(2)引入了一种新的集成图评分方法。这些修饰显著减少了假阳性肌节检测，特别是在未成熟细胞中，并改善了成熟样本中较长肌原纤维的检测。有了这个增强的框架，我们分析了由艾伦细胞科学研究所发布的开源数据集，其中，我们第一次能够从这些数据中提取关键的结构特征，使用来自每个单独检测到的肌节的信息。我们不仅能够使用这些结构特征来预测专家得分，而且还能够使用这些结构特征来识别专家评分中的偏差，并提供一种基于可解释聚类的替代无监督学习方法。这些结果证明了我们改进的SarcGraph算法在提取具有生物学意义的结构特征方面的有效性，从而能够更深入地了解hiPSC-CM的结构完整性。通过使我们的代码和工具开源，我们的目标是授权更广泛的心脏研究社区，并促进心脏组织分析计算工具的进一步发展。

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

PLoS Computational Biology BIOCHEMICAL RESEARCH METHODS-MATHEMATICAL & COMPUTATIONAL BIOLOGY

CiteScore

7.10

自引率

4.70%

发文量

820

审稿时长

2.5 months

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