Shape matters: inferring the motility of confluent cells from static images.

IF 2.9 3区化学 Q3 CHEMISTRY, PHYSICAL

Soft Matter Pub Date : 2025-07-07 DOI:10.1039/d5sm00222b

Quirine J S Braat, Giulia Janzen, Bas C Jansen, Vincent E Debets, Simone Ciarella, Liesbeth M C Janssen

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引用次数: 0

Abstract

Cell motility in dense cell collectives is pivotal in various diseases like cancer metastasis and asthma. A central aspect in these phenomena is the heterogeneity in cell motility, but identifying the motility of individual cells is challenging. Previous work has established the importance of the average cell shape in predicting cell dynamics. Here, we aim to identify the importance of individual cell shape features, rather than collective features, to distinguish between high-motility and low-motility (or zero-motility) cells in heterogeneous cell layers. Employing the cellular Potts model, we generate simulation snapshots and extract static features as inputs for a simple machine-learning model. Our results show that when cells are either motile or non-motile, this machine-learning model can accurately predict a cell's phenotype using only single-cell shape features. Furthermore, we explore scenarios where both cell types exhibit some degree of motility, characterized by high or low motility. In such cases, our findings indicate that a neural network trained on shape features can accurately classify cell motility, particularly when the number of highly motile cells is low, and high-motility cells are significantly more motile compared to low-motility cells. This work offers potential for physics-inspired predictions of single-cell properties with implications for inferring cell dynamics from static histological images.

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形状很重要：从静态图像推断融合细胞的运动。

致密细胞群的细胞运动在癌症转移和哮喘等多种疾病中起着关键作用。这些现象的一个中心方面是细胞运动的异质性，但识别单个细胞的运动是具有挑战性的。以前的工作已经确定了平均细胞形状在预测细胞动力学中的重要性。在这里，我们的目标是确定单个细胞形状特征的重要性，而不是集体特征，以区分异质性细胞层中的高运动性和低运动性（或零运动性）细胞。采用细胞波茨模型，我们生成仿真快照并提取静态特征作为简单机器学习模型的输入。我们的研究结果表明，当细胞处于运动状态或非运动状态时，该机器学习模型可以仅使用单细胞形状特征准确预测细胞的表型。此外，我们探索了两种细胞类型都表现出一定程度的运动性的情况，其特征是高运动性或低运动性。在这种情况下，我们的研究结果表明，在形状特征上训练的神经网络可以准确地分类细胞的运动性，特别是当高运动性细胞的数量较低时，高运动性细胞明显比低运动性细胞更具运动性。这项工作为从静态组织学图像推断细胞动力学的单细胞特性的物理启发预测提供了潜力。

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

Soft Matter 工程技术-材料科学：综合

CiteScore

6.00

自引率

5.90%

发文量

891

审稿时长

1.9 months

期刊介绍： Soft Matter is an international journal published by the Royal Society of Chemistry using Engineering-Materials Science: A Synthesis as its research focus. It publishes original research articles, review articles, and synthesis articles related to this field, reporting the latest discoveries in the relevant theoretical, practical, and applied disciplines in a timely manner, and aims to promote the rapid exchange of scientific information in this subject area. The journal is an open access journal. The journal is an open access journal and has not been placed on the alert list in the last three years.