(3) The CellOrganizer project: An open source system to learn image-derived models of subcellular organization over time and space

R. Murphy
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Abstract

The CellOrganizer project (http://cellorganizer.org) provides open source tools for learning generative models of cell organization directly from images and for synthesizing cell images (or other representations) from one or more of those models. Model learning captures variation among cells in a collection of images. Images used for model learning and instances synthesized from models can be two- or three-dimensional static images or movies. Current components of CellOrganizer can learn models of cell shape, nuclear shape, chromatin texture, vesicular organe lie number, size, shape and position, and microtubule distribution. These models can be conditional upon each other: for example, for a given synthesized cell instance, organelle position will be dependent upon the cell and nuclear shape of that instance. The models can be parametric, in which a choice is made about an explicit form to represent a particular structure, or non-parametric, in which distributions are learned empirically. One of the main uses of the system is in support of cell simulations: models learned from separate experiments can be combined into one or more synthetic cell instances that are output in a form compatible with cell simulation engines such as MCell, Virtual Cell and Smoldyn. Another important application of the system is in comparison of target patterns and perturbagen effects in high content screening and analysis. This is currently done using numerical features, but these are difficult to compare across different microscope systems or cell types since features can be affected by changes in more than one aspect of cell organization. More robust comparisons can be made using generative model parameters, since these can distinguish effects on cell size or shape from effects on organelle pattern. Ultimately, it is anticipated that collaborative efforts by many groups will enable creation of image-derived generative models that permit accurate modeling of cell behaviors, and that can be used to drive experimentation to improve them through active learning. [replace "perturbation" for the word "perturbagen"]
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(3) CellOrganizer项目:一个开源系统,用于学习亚细胞组织随时间和空间的图像衍生模型
CellOrganizer项目(http://cellorganizer.org)提供了开源工具,用于直接从图像中学习细胞组织的生成模型,并用于从一个或多个模型中合成细胞图像(或其他表示)。模型学习捕捉图像集合中细胞之间的变化。用于模型学习的图像和从模型合成的实例可以是二维或三维静态图像或电影。当前的CellOrganizer组件可以学习细胞形状、核形状、染色质质地、囊泡器官数目、大小、形状和位置以及微管分布的模型。这些模型可以相互依赖:例如,对于给定的合成细胞实例,细胞器位置将取决于该实例的细胞和核形状。模型可以是参数化的,即选择一种明确的形式来表示特定的结构,也可以是非参数化的,即根据经验学习分布。该系统的主要用途之一是支持细胞模拟:从单独的实验中学习的模型可以组合成一个或多个合成细胞实例,这些实例以与细胞模拟引擎(如MCell, Virtual cell和Smoldyn)兼容的形式输出。该系统的另一个重要应用是在高含量筛选和分析中比较目标模式和摄动效应。目前这是使用数值特征来完成的,但是这些很难在不同的显微镜系统或细胞类型之间进行比较,因为特征可能受到细胞组织多个方面的变化的影响。可以使用生成模型参数进行更可靠的比较,因为这些参数可以区分对细胞大小或形状的影响与对细胞器模式的影响。最终,预计许多小组的合作努力将能够创建图像衍生的生成模型,这些模型允许对细胞行为进行精确建模,并可用于推动实验,通过主动学习来改进它们。[用“摄动”一词代替“摄动”一词]
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