Feature-based image analysis of zebrafish embryonic images

A pipeline of image analysis algorithm is developed for automatic analysis and quantification of neurons in microscopic images of zebrafish embryos. Key steps of pipeline include segmentation of zebrafish embryos from background, detection of the ROI, and quantitative measurement of neurons in the ROI. First, morphological operations are used to segment the zebrafish embryo from the background. Then based on the prior information that the torso has two approximately parallel boundaries corresponding to the back and abdomen, the algorithm automatically creates a ROI enclosing the torso. Finally, the number of neurons is obtained by improved Hough transform. Our results show that the image analysis algorithm has a high accuracy and fast computational speed. Development of such an automated image analysis pipeline represents a step toward high-throughput screening of zebrafish images with an accurate and reproducible quantification of neurons.

[1]  Ralf Dahm,et al.  Mutations that affect the survival of selected amacrine cell subpopulations define a new class of genetic defects in the vertebrate retina. , 2005, Developmental biology.

[2]  Stephen T. C. Wong,et al.  Zebrafish lacking Alzheimer presenilin enhancer 2 (Pen‐2) demonstrate excessive p53‐dependent apoptosis and neuronal loss , 2006, Journal of neurochemistry.

[3]  Werner J H Koopman,et al.  Computer-assisted live cell analysis of mitochondrial membrane potential, morphology and calcium handling. , 2008, Methods.

[4]  Anil K. Jain Fundamentals of Digital Image Processing , 2018, Control of Color Imaging Systems.

[5]  Stephen T. C. Wong,et al.  ZFIQ: a software package for zebrafish biology , 2008, Bioinform..

[6]  Cheng-chen Huang,et al.  reg6 is required for branching morphogenesis during blood vessel regeneration in zebrafish caudal fins. , 2003, Developmental biology.

[7]  Iris Leefken,et al.  A computerized image analysis system for quantitative analysis of cells in histological brain sections , 2003, Journal of Neuroscience Methods.

[8]  G. Streisinger,et al.  Production of clones of homozygous diploid zebra fish (Brachydanio rerio) , 1981, Nature.

[9]  Horace Ho-Shing Ip,et al.  Reconstruction and representation of caudal vasculature of zebrafish embryo from confocal scanning laser fluorescence microscopic images , 2005, Comput. Biol. Medicine.

[10]  Stephen T. C. Wong,et al.  Computerized image analysis for quantitative neuronal phenotyping in zebrafish , 2006, Journal of Neuroscience Methods.

[11]  Edward H. Adelson,et al.  The Laplacian Pyramid as a Compact Image Code , 1983, IEEE Trans. Commun..

[12]  M. Fishman,et al.  Vessel patterning in the embryo of the zebrafish: guidance by notochord. , 1997, Developmental biology.

[13]  Rafael C. González,et al.  Local Determination of a Moving Contrast Edge , 1985, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[14]  P. J. Burt,et al.  Fast Filter Transforms for Image Processing , 1981 .

[15]  L. Zon,et al.  The art and design of genetic screens: zebrafish , 2001, Nature Reviews Genetics.

[16]  Shuo Lin,et al.  The zebrafish as a model for human disease. , 2002, Frontiers in bioscience : a journal and virtual library.

[17]  Leonard I. Zon,et al.  Cancer genetics and drug discovery in the zebrafish , 2003, Nature Reviews Cancer.

[18]  P.V.C. Hough,et al.  Machine Analysis of Bubble Chamber Pictures , 1959 .

[19]  Stephen T. C. Wong,et al.  Robust 3D reconstruction and identification of dendritic spines from optical microscopy imaging , 2009, Medical Image Anal..

[20]  K. Pfaller,et al.  Biolistic transfection and morphological analysis of cultured sympathetic neurons , 2002, Journal of Neuroscience Methods.