Modelling of morphogenesis to support the design of fungal-based engineered living materials

Vilhelm Carlström; Adrien Rigobello; Phil Ayres

doi:10.1017/btd.2024.10

Modelling of morphogenesis to support the design of fungal-based engineered living materials

Vilhelm Carlström, Adrien Rigobello, Phil Ayres

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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Abstract

To realize the potential of materials comprising living organisms, bioengineers require a holistic understanding of the reciprocal relationship between environmental conditions and the biochemical and biophysical processes that influence development and behaviour. Mathematical modelling has a critical part to play in managing the complexity of biological dynamical systems and attaining higher degrees of control over their trajectories and endpoints. To support the development of mycelium-based engineered living materials, this paper reviews the literature of growth models for filamentous fungi with emphasis on the connection between morphogenesis and metabolism.

Originalsprog	Engelsk
Tidsskrift	Research Directions: Biotechnology Design
Vol/bind	2
Udgave nummer	e11
Sider (fra-til)	1-16
Antal sider	16
ISSN	2752-9452
DOI	https://doi.org/10.1017/btd.2024.10
Status	Udgivet - 30 sep. 2024

Kunstnerisk udviklingsvirksomhed (KUV)

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10.1017/btd.2024.10Licens: CC BY-NC-SA

Modelling of morphogenesis - Carlström, Rigobello & Ayres 2024Forlagets udgivne version, 798 KBLicens: CC BY-NC-SA

FUNGATERIA: Enlisting synthetic fungal-bacterial consortia to produce multi-cellular mycelium-based ELMs with computational capability
Ayres, P. (PI), Rigobello, A. (Andet), Colmo, C. (Andet) & You-Wen, J. (Andet)
EU Horizon, European Innovation Council
01/11/2022 → 31/10/2026
Projekter: Projekt › Forskning

Citationsformater

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AB - To realize the potential of materials comprising living organisms, bioengineers require a holistic understanding of the reciprocal relationship between environmental conditions and the biochemical and biophysical processes that influence development and behaviour. Mathematical modelling has a critical part to play in managing the complexity of biological dynamical systems and attaining higher degrees of control over their trajectories and endpoints. To support the development of mycelium-based engineered living materials, this paper reviews the literature of growth models for filamentous fungi with emphasis on the connection between morphogenesis and metabolism.

KW - Engineered living materials

KW - computational biology

KW - growth model

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KW - mycelium materials

KW - fermentation

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Modelling of morphogenesis to support the design of fungal-based engineered living materials

Abstract

Kunstnerisk udviklingsvirksomhed (KUV)

Adgang til dokumentet

Projekter

FUNGATERIA: Enlisting synthetic fungal-bacterial consortia to produce multi-cellular mycelium-based ELMs with computational capability

Citationsformater