Abstract

Stem cells have received much attention recently for their potential utility in regenerative medicine. The identification of their differentiated progeny often requires complex staining procedures, and is challenging for intermediary stages which are a priori unknown. In this work, the ability of label-free quantitative coherent anti-Stokes Raman scattering (CARS) micro-spectroscopy to identify populations of intermediate cell states during the differentiation of murine embryonic stem cells into adipocytes is assessed. Cells were imaged at different days of differentiation by hyperspectral CARS, and images were analysed with an unsupervised factorization algorithm providing Raman-like spectra and spatially resolved maps of chemical components. Chemical decomposition combined with a statistical analysis of their spatial distributions provided a set of parameters that were used for classification analysis. The first 2 principal components of these parameters indicated 3 main groups, attributed to undifferentiated cells, cells differentiated into committed white pre-adipocytes, and differentiating cells exhibiting a distinct protein globular structure with adjacent lipid droplets. An unsupervised classification methodology was developed, separating undifferentiated cell from cells in other stages, using a novel method to estimate the optimal number of clusters. The proposed unsupervised classification pipeline of hyperspectral CARS data offers a promising new tool for automated cell sorting in lineage analysis.

Highlights

  • A significant challenge when investigating biological phenomena is that biological systems exhibit complex dynamic interactions with inter-celluar and intra-cellular states fluctuating and changing to accommodate feedback from the surrounding micro-environment in order to enable tissue homoeostasis

  • We have investigated the heterogeneous differentiation of mouse embryonic stem cells using hyperspectral coherent anti-Stokes Raman scattering (CARS) micro-spectroscopy combined with an advanced quantitative data analysis tool for unsupervised classification analysis

  • We investigated murine embryonic stem cells (mESc) undergoing heterogeneous differentiation towards adipocytes using label-free chemically specific hyperspectral CARS micro-spectroscopy and our latest advances in quantitative data analysis

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Summary

| INTRODUCTION

A significant challenge when investigating biological phenomena is that biological systems exhibit complex dynamic interactions with inter-celluar and intra-cellular states fluctuating and changing to accommodate feedback from the surrounding micro-environment in order to enable tissue homoeostasis. The desirable properties of stem cells, which tissue engineers aim to exploit, are their ability to self-renew in-vitro (potentially indefinitely, dependent on stem cell type) and their inherent ability to transition through several intermediate or precursor states (progenitor cells) to produce multiple specialised cell types (differentiation) Stem cells and their differentiated progeny are currently primarily identified based on a combination of in-vitro morphology and marker profiles (sometimes destructive). In order to overcome some of these limitations, we sought to develop a label-free micro-spectroscopy platform which could assess intermediary cell states through the identification of novel, non-destructive, markers of cellular phenotype by utilising chemically specific vibrational imaging based on coherent Raman scattering (CRS) and the model of mouse embryonic stem cells differentiating towards the adipocytic lineage. We have investigated the heterogeneous differentiation of mouse embryonic stem cells using hyperspectral coherent anti-Stokes Raman scattering (CARS) micro-spectroscopy combined with an advanced quantitative data analysis tool for unsupervised classification analysis. We found 3 main clusters that were attributed to undifferentiated cells, cells differentiated into committed white preadipocytes (as discussed below) and intermediate differentiating cells exhibiting a distinct protein globular structure with adjacent lipid droplets

| MATERIALS AND METHODS
| RESULTS AND DISCUSSION
| CONCLUSIONS

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