TY - JOUR
T1 - An effective method for quantification, visualization, and analysis of 3D cell shape during early embryogenesis
AU - Li, Zelin
AU - Huang, Zhaoke
AU - Cao, Jianfeng
AU - Guan, Guoye
AU - Zhao, Zhongying
AU - Yan, Hong
N1 - Funding Information:
We thank all the members of Yan Lab, Tang Lab, and Zhao Lab for supports. We appreciate Dr. David for his assistance in improving the paper materials. The work is funded by the Hong Kong Innovation and Technology Commission-ITC (InnoHK Project CIMDA), Hong Kong Research Grant Council-RGC (11204821) and City University of Hong Kong (Project 9610034).
Publisher Copyright:
© 2024 The Author(s). Quantitative Biology published by John Wiley & Sons Australia, Ltd on behalf of Higher Education Press.
PY - 2025/3
Y1 - 2025/3
N2 - Embryogenesis is the most basic process in developmental biology. Effectively and simply quantifying cell shape is challenging for the complex and dynamic 3D embryonic cells. Traditional descriptors such as volume, surface area, and mean curvature often fall short, providing only a global view and lacking in local detail and reconstruction capability. Addressing this, we introduce an effective integrated method, 3D Cell Shape Quantification (3DCSQ), for transforming digitized 3D cell shapes into analytical feature vectors, named eigengrid (proposed grid descriptor like eigen value), eigenharmonic, and eigenspectrum. We uniquely combine spherical grids, spherical harmonics, and principal component analysis for cell shape quantification. We demonstrate 3DCSQ’s effectiveness in recognizing cellular morphological phenotypes and clustering cells. Applied to Caenorhabditis elegans embryos of 29 living embryos from 4- to 350-cell stages, 3DCSQ identifies and quantifies biologically reproducible cellular patterns including distinct skin cell deformations. We also provide automatically cell shape lineaging analysis program. This method not only systematizes cell shape description and evaluation but also monitors cell differentiation through shape changes, presenting an advancement in biological imaging and analysis.
AB - Embryogenesis is the most basic process in developmental biology. Effectively and simply quantifying cell shape is challenging for the complex and dynamic 3D embryonic cells. Traditional descriptors such as volume, surface area, and mean curvature often fall short, providing only a global view and lacking in local detail and reconstruction capability. Addressing this, we introduce an effective integrated method, 3D Cell Shape Quantification (3DCSQ), for transforming digitized 3D cell shapes into analytical feature vectors, named eigengrid (proposed grid descriptor like eigen value), eigenharmonic, and eigenspectrum. We uniquely combine spherical grids, spherical harmonics, and principal component analysis for cell shape quantification. We demonstrate 3DCSQ’s effectiveness in recognizing cellular morphological phenotypes and clustering cells. Applied to Caenorhabditis elegans embryos of 29 living embryos from 4- to 350-cell stages, 3DCSQ identifies and quantifies biologically reproducible cellular patterns including distinct skin cell deformations. We also provide automatically cell shape lineaging analysis program. This method not only systematizes cell shape description and evaluation but also monitors cell differentiation through shape changes, presenting an advancement in biological imaging and analysis.
KW - Caenorhabditis elegans (C. elegans)
KW - cell shape quantification
KW - eigen features (eigengrid, eigenharmonic & eigenspectrum)
KW - lineage analysis
KW - morphological reproducibility
KW - spherical harmonics (SPHARM)
UR - http://www.scopus.com/inward/record.url?scp=85212689374&partnerID=8YFLogxK
U2 - 10.1002/qub2.83
DO - 10.1002/qub2.83
M3 - Journal article
AN - SCOPUS:85212689374
SN - 2095-4689
VL - 13
JO - Quantitative Biology
JF - Quantitative Biology
IS - 1
M1 - e83
ER -
