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Main Authors: Gayford, Joel Harrison, Irschick, Duncan J, Martin, Johnson, Chin, Andrew, Rummer, Jodie L
Format: Artículo científico
Language:en
Published: Royal Society open science 2025
Online Access:https://pubmed.ncbi.nlm.nih.gov/40535946/
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author Gayford, Joel Harrison
Irschick, Duncan J
Martin, Johnson
Chin, Andrew
Rummer, Jodie L
author_facet Gayford, Joel Harrison
Irschick, Duncan J
Martin, Johnson
Chin, Andrew
Rummer, Jodie L
Gayford, Joel Harrison
Irschick, Duncan J
Martin, Johnson
Chin, Andrew
Rummer, Jodie L
collection PubMed - marine biology
contents The geometry of life: testing the scaling of whole-organism surface area and volume using sharks. Gayford, Joel Harrison Irschick, Duncan J Martin, Johnson Chin, Andrew Rummer, Jodie L The ratio of surface area to volume is a key biological parameter that underpins our understanding of physiology across all levels of biological organization. Surfaces control the rate of key reactions and processes operating within the body and between organisms and their environment. Our understanding of surface area to volume ratios is embedded in the 2/3 scaling law, stating that surface area scales with volume raised to a power of 0.66. However, most empirical studies of surface area and volume scaling in animals focus on individual cells or tissues. Comparatively few studies have addressed these scaling relationships among species or ontogenetic stages at the whole-organism level. This study uncovers quantitative support for the 2/3 scaling law in an interspecific dataset at the whole-organism level. We find that the scaling of surface area to volume across 54 shark species (exhibiting an approx. 19 000-fold variation in body mass) is nearly identical to the isometric prediction of the 2/3 scaling law. There is no evidence that this relationship is driven by ecological or physiological characteristics. One plausible explanation is the presence of developmental constraints on tissue allocation that could influence the range of possible surface areas or volumes at any given body size.
format Artículo científico
id pubmed_40535946
institution PubMed
language en
publishDate 2025
publisher Royal Society open science
record_format pubmed
spellingShingle The geometry of life: testing the scaling of whole-organism surface area and volume using sharks.
Gayford, Joel Harrison
Irschick, Duncan J
Martin, Johnson
Chin, Andrew
Rummer, Jodie L
The geometry of life: testing the scaling of whole-organism surface area and volume using sharks. Gayford, Joel Harrison Irschick, Duncan J Martin, Johnson Chin, Andrew Rummer, Jodie L The ratio of surface area to volume is a key biological parameter that underpins our understanding of physiology across all levels of biological organization. Surfaces control the rate of key reactions and processes operating within the body and between organisms and their environment. Our understanding of surface area to volume ratios is embedded in the 2/3 scaling law, stating that surface area scales with volume raised to a power of 0.66. However, most empirical studies of surface area and volume scaling in animals focus on individual cells or tissues. Comparatively few studies have addressed these scaling relationships among species or ontogenetic stages at the whole-organism level. This study uncovers quantitative support for the 2/3 scaling law in an interspecific dataset at the whole-organism level. We find that the scaling of surface area to volume across 54 shark species (exhibiting an approx. 19 000-fold variation in body mass) is nearly identical to the isometric prediction of the 2/3 scaling law. There is no evidence that this relationship is driven by ecological or physiological characteristics. One plausible explanation is the presence of developmental constraints on tissue allocation that could influence the range of possible surface areas or volumes at any given body size.
title The geometry of life: testing the scaling of whole-organism surface area and volume using sharks.
url https://pubmed.ncbi.nlm.nih.gov/40535946/