Quantifying HiPSC-CM Structural Organization at Scale with Deep Learning-Enhanced SarcGraph

TL;DR

This paper enhances the SarcGraph framework with deep learning to better analyze the structural organization of hiPSC-CMs, enabling accurate feature extraction, prediction of expert scores, and bias detection in cell maturity assessment.

Contribution

The authors introduce a deep learning-based z-disc classifier and an ensemble graph-scoring method to improve sarcomere detection in immature hiPSC-CMs within the SarcGraph framework.

Findings

Reduced false positive sarcomere detections in immature cells

Detected longer myofibrils in mature samples

Successfully predicted expert scores and identified scoring bias

Abstract

In cardiac cells, structural organization is an important indicator of cell maturity and healthy function. Healthy cardiomyocytes exhibit well-aligned morphology with densely packed and organized sarcomeres. Immature or diseased cardiomyocytes typically lack this organized structure. Critically, human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) offer a valuable model for studying human cardiac cells in a controlled environment. However, these cells often exhibit a disorganized structure. In this work, we extend the SarcGraph computational framework -- designed 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 in immature cells, and resulted in 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 in extracting biologically meaningful 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.