A mechanical model of blastocyst hatching

Viggo Tvergaard; Daniel Needleman; Alan Needleman

doi:10.1016/j.eml.2020.101132

A mechanical model of blastocyst hatching

Viggo Tvergaard
, Daniel Needleman
, Alan Needleman^*

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

We develop a continuum mechanics model of blastocyst hatching. The blastocyst and the zona pellucida are modeled as concentric thick-walled initially spherical shells embedded in a viscous medium. Each shell is characterized by a nonlinear elastic–viscous–constitutive relation. The stiffer outer shell (the zona pellucida) contains an opening. The softer inner shell (the blastocyst) is subject to a continually increasing pressure, which can eventually drive the escape of the inner shell from the outer shell (“hatching”). The focus is on the continuum mechanics modeling framework and illustrating the sort of quantitative predictions that can be made. Numerical examples are presented for the predicted dependence of the evolution of the escape process on values of parameters characterizing the constitutive response of the shells, on the viscosity of the external medium and on the size of the opening in the zona pellucida.

Original language	English
Article number	101132
Journal	Extreme Mechanics Letters
Volume	42
Number of pages	10
ISSN	2352-4316
DOIs	https://doi.org/10.1016/j.eml.2020.101132
Publication status	Published - 2021

Keywords

Mammalian embryo hatching
Shell mechanics
Pressure loading

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title = "A mechanical model of blastocyst hatching",

abstract = "We develop a continuum mechanics model of blastocyst hatching. The blastocyst and the zona pellucida are modeled as concentric thick-walled initially spherical shells embedded in a viscous medium. Each shell is characterized by a nonlinear elastic–viscous–constitutive relation. The stiffer outer shell (the zona pellucida) contains an opening. The softer inner shell (the blastocyst) is subject to a continually increasing pressure, which can eventually drive the escape of the inner shell from the outer shell (“hatching”). The focus is on the continuum mechanics modeling framework and illustrating the sort of quantitative predictions that can be made. Numerical examples are presented for the predicted dependence of the evolution of the escape process on values of parameters characterizing the constitutive response of the shells, on the viscosity of the external medium and on the size of the opening in the zona pellucida.",

keywords = "Mammalian embryo hatching, Shell mechanics, Pressure loading",

author = "Viggo Tvergaard and Daniel Needleman and Alan Needleman",

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T1 - A mechanical model of blastocyst hatching

AU - Tvergaard, Viggo

AU - Needleman, Daniel

AU - Needleman, Alan

PY - 2021

Y1 - 2021

N2 - We develop a continuum mechanics model of blastocyst hatching. The blastocyst and the zona pellucida are modeled as concentric thick-walled initially spherical shells embedded in a viscous medium. Each shell is characterized by a nonlinear elastic–viscous–constitutive relation. The stiffer outer shell (the zona pellucida) contains an opening. The softer inner shell (the blastocyst) is subject to a continually increasing pressure, which can eventually drive the escape of the inner shell from the outer shell (“hatching”). The focus is on the continuum mechanics modeling framework and illustrating the sort of quantitative predictions that can be made. Numerical examples are presented for the predicted dependence of the evolution of the escape process on values of parameters characterizing the constitutive response of the shells, on the viscosity of the external medium and on the size of the opening in the zona pellucida.

AB - We develop a continuum mechanics model of blastocyst hatching. The blastocyst and the zona pellucida are modeled as concentric thick-walled initially spherical shells embedded in a viscous medium. Each shell is characterized by a nonlinear elastic–viscous–constitutive relation. The stiffer outer shell (the zona pellucida) contains an opening. The softer inner shell (the blastocyst) is subject to a continually increasing pressure, which can eventually drive the escape of the inner shell from the outer shell (“hatching”). The focus is on the continuum mechanics modeling framework and illustrating the sort of quantitative predictions that can be made. Numerical examples are presented for the predicted dependence of the evolution of the escape process on values of parameters characterizing the constitutive response of the shells, on the viscosity of the external medium and on the size of the opening in the zona pellucida.

KW - Mammalian embryo hatching

KW - Shell mechanics

KW - Pressure loading

U2 - 10.1016/j.eml.2020.101132

DO - 10.1016/j.eml.2020.101132

M3 - Journal article

SN - 2352-4316

VL - 42

JO - Extreme Mechanics Letters

JF - Extreme Mechanics Letters

M1 - 101132

ER -

A mechanical model of blastocyst hatching

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Keywords

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