The Role of Dynamic Energy Budgets in Conservation Physiology

Overview

Journal Conserv Physiol

Date 2021 Oct 28

PMID 34707875

Citations 4

Authors

Romain Lavaud

Ramon Filgueira

Starrlight Augustine

Affiliations

Soon will be listed here.

Abstract

The contribution of knowledge, concepts and perspectives from physiological ecology to conservation decision-making has become critical for understanding and acting upon threats to the persistence of sensitive species. Here we review applications of dynamic energy budget (DEB) theory to conservation issues and discuss how this theory for metabolic organization of all life on earth (from bacteria to whales) is well equipped to support current and future investigations in conservation research. DEB theory was first invented in 1979 in an applied institution for environmental quality assessment and mitigation. The theory has since undergone extensive development and applications. An increasing number of studies using DEB modelling have provided valuable insights and predictions in areas that pertain to conservation such as species distribution, evolutionary biology, toxicological impacts and ecosystem management. We discuss why DEB theory, through its mechanistic nature, its universality and the wide range of outcomes it can provide represents a valuable tool to tackle some of the current and future challenges linked to maintaining biodiversity, ensuring species survival, ecotoxicology, setting water and soil quality standards and restoring ecosystem structure and functioning in a changing environment under the pressure of anthropogenic driven changes.

Citing Articles

Could future ocean acidification be affecting the energy budgets of marine fish?.

Yoon G, Bozai A, Porteus C Conserv Physiol. 2024; 12(1):coae069.

PMID: 39381802 PMC: 11459383. DOI: 10.1093/conphys/coae069.

Dynamic Energy Budget models: fertile ground for understanding resource allocation in plants in a changing world.

Russo S, Ledder G, Muller E, Nisbet R Conserv Physiol. 2022; 10(1):coac061.

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Physiological performance of native and invasive crayfish species in a changing environment: insights from Dynamic Energy Budget models.

Marn N, Hudina S, Haberle I, Dobrovic A, Klanjscek T Conserv Physiol. 2022; 10(1):coac031.

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Timescale separation and models of symbiosis: state space reduction, multiple attractors and initialization.

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