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Growth of shell-like soft biological tissues under mechanical loading

Farzam Dadgar-Rad Orcid Logo, Amirhossein N. Dorostkar Orcid Logo, Mokarram Hossain Orcid Logo

International Journal of Non-Linear Mechanics, Volume: 156, Start page: 104505

Swansea University Author: Mokarram Hossain Orcid Logo

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DOI (Published version): 10.1016/j.ijnonlinmec.2023.104505

Abstract

Application of mechanical loading to soft biological tissues plays a central role in tissue engineering. Mechanical stimuli convert into intracellular biochemical activity, referred to as mechanotransduction, and lead to the growth of tissues. In most practical applications, the mechanotransduction...

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Published in: International Journal of Non-Linear Mechanics
ISSN: 0020-7462
Published: Elsevier BV 2023
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URI: https://cronfa.swan.ac.uk/Record/cronfa63948
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spelling v2 63948 2023-07-26 Growth of shell-like soft biological tissues under mechanical loading 140f4aa5c5ec18ec173c8542a7fddafd 0000-0002-4616-1104 Mokarram Hossain Mokarram Hossain true false 2023-07-26 GENG Application of mechanical loading to soft biological tissues plays a central role in tissue engineering. Mechanical stimuli convert into intracellular biochemical activity, referred to as mechanotransduction, and lead to the growth of tissues. In most practical applications, the mechanotransduction phenomenon has been examined on thin tissues in two- or three-dimensional space. Accordingly, a phenomenological finite growth formulation for shell-like soft tissues under mechanical loading is presented in this work. The basic kinematic and kinetic quantities besides the constitutive response are formulated. The unconditionally stable implicit Euler-backward scheme is employed to solve the evolution equation of the growth parameter. Moreover, a nonlinear finite element formulation is developed, which can provide numerical solutions under arbitrary geometry, loading, and boundary conditions. Several examples are presented that demonstrate the applicability and performance of the formulation. The results indicate that finite growth as well as finite deformation of thin tissues under mechanical input can be successfully predicted by the present formulation. Journal Article International Journal of Non-Linear Mechanics 156 104505 Elsevier BV 0020-7462 Growth mechanics, Soft tissue, Shell, Large deformation, Finite Element Method 1 11 2023 2023-11-01 10.1016/j.ijnonlinmec.2023.104505 http://dx.doi.org/10.1016/j.ijnonlinmec.2023.104505 COLLEGE NANME General Engineering COLLEGE CODE GENG Swansea University SU Library paid the OA fee (TA Institutional Deal) Swansea University 2023-09-04T12:49:15.8087573 2023-07-26T09:16:23.5356000 Faculty of Science and Engineering School of Engineering and Applied Sciences - Uncategorised Farzam Dadgar-Rad 0000-0003-1546-2446 1 Amirhossein N. Dorostkar 0009-0000-1603-7260 2 Mokarram Hossain 0000-0002-4616-1104 3 63948__28181__904733615acf4f3c8e42af694c4a360d.pdf 63948.pdf 2023-07-26T09:33:18.8436212 Output 1881056 application/pdf Accepted Manuscript true Under a Creative Commons license CC BY false eng https://creativecommons.org/licenses/by/4.0/ 63948__28328__526d21752987468c8ce4c3313f1901b1.pdf 63948.VOR.pdf 2023-08-18T16:24:05.7277067 Output 2658735 application/pdf Version of Record true Distributed under the terms of a Creative Commons attribution CC-BY-Licence. true eng https://creativecommons.org/licenses/by/4.0/
title Growth of shell-like soft biological tissues under mechanical loading
spellingShingle Growth of shell-like soft biological tissues under mechanical loading
Mokarram Hossain
title_short Growth of shell-like soft biological tissues under mechanical loading
title_full Growth of shell-like soft biological tissues under mechanical loading
title_fullStr Growth of shell-like soft biological tissues under mechanical loading
title_full_unstemmed Growth of shell-like soft biological tissues under mechanical loading
title_sort Growth of shell-like soft biological tissues under mechanical loading
author_id_str_mv 140f4aa5c5ec18ec173c8542a7fddafd
author_id_fullname_str_mv 140f4aa5c5ec18ec173c8542a7fddafd_***_Mokarram Hossain
author Mokarram Hossain
author2 Farzam Dadgar-Rad
Amirhossein N. Dorostkar
Mokarram Hossain
format Journal article
container_title International Journal of Non-Linear Mechanics
container_volume 156
container_start_page 104505
publishDate 2023
institution Swansea University
issn 0020-7462
doi_str_mv 10.1016/j.ijnonlinmec.2023.104505
publisher Elsevier BV
college_str Faculty of Science and Engineering
hierarchytype
hierarchy_top_id facultyofscienceandengineering
hierarchy_top_title Faculty of Science and Engineering
hierarchy_parent_id facultyofscienceandengineering
hierarchy_parent_title Faculty of Science and Engineering
department_str School of Engineering and Applied Sciences - Uncategorised{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Uncategorised
url http://dx.doi.org/10.1016/j.ijnonlinmec.2023.104505
document_store_str 1
active_str 0
description Application of mechanical loading to soft biological tissues plays a central role in tissue engineering. Mechanical stimuli convert into intracellular biochemical activity, referred to as mechanotransduction, and lead to the growth of tissues. In most practical applications, the mechanotransduction phenomenon has been examined on thin tissues in two- or three-dimensional space. Accordingly, a phenomenological finite growth formulation for shell-like soft tissues under mechanical loading is presented in this work. The basic kinematic and kinetic quantities besides the constitutive response are formulated. The unconditionally stable implicit Euler-backward scheme is employed to solve the evolution equation of the growth parameter. Moreover, a nonlinear finite element formulation is developed, which can provide numerical solutions under arbitrary geometry, loading, and boundary conditions. Several examples are presented that demonstrate the applicability and performance of the formulation. The results indicate that finite growth as well as finite deformation of thin tissues under mechanical input can be successfully predicted by the present formulation.
published_date 2023-11-01T12:49:17Z
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score 11.012678

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