Cephalic biomechanics underpins the evolutionary success of trilobites

Esteve J; Marcé-Nogué J; Pérez-Peris F; Rayfield E

Pertenece a la colección PC:SerieArticles

TÍTULO:

Cephalic biomechanics underpins the evolutionary success of trilobites - imarina:9207346

Handle:

https://hdl.handle.net/20.500.11797/imarina9207346

Autor/es de la URV:	Marcé Nogué, Jordi
Autor según el artículo:	Esteve J; Marcé-Nogué J; Pérez-Peris F; Rayfield E
Direcció de correo del autor:	jordi.marce@urv.cat
Identificador del autor:	0000-0001-9852-7027
Año de publicación de la revista:	2021
Tipo de publicación:	Journal Publications
Referencia de l'ítem segons les normes APA:	Esteve J; Marcé-Nogué J; Pérez-Peris F; Rayfield E (2021). Cephalic biomechanics underpins the evolutionary success of trilobites. Palaeontology, 64(4), 519-530. DOI: 10.1111/pala.12541
Referencia al articulo segun fuente origial:	Palaeontology. 64 (4): 519-530
Resumen:	Arthropods (i.e. insects, spiders, crustaceans, myriapods and others), are the most successful Phanerozoic animals. The group is characterized by the possession of a segmented body, jointed limbs and a hard cuticle that is episodically moulted. One highly successful but now extinct group of arthropods is the trilobites. Trilobites underwent episodic moulting (ecdysis), and most trilobites possess facial sutures, lines of weakness in the cephalon, via which the exuviae is shed and the animal emerges. However, zones of weakness appear to represent a structural trade-off or constraint, particularly during burrowing; sacrificing a consolidated head region useful in burrowing for the ability to moult. Here we reconcile this trade-off by using biomechanical modelling to demonstrate that facial sutures exist in regions of low stress during the application of burrowing loads. Furthermore, facial sutures and the structure of the cephalon enable sutured trilobites to withstand greater stresses than their non-suture counterparts. We suggest that this ability to withstand greater burrowing loads enabled trilobites to successfully invade bioturbated and more consolidated sediments of the Cambrian Sediment Revolution, thus facilitating their diversification in the Cambrian and Ordovician and contributing to the evolutionary success of this iconic arthropod group.
DOI del artículo:	10.1111/pala.12541
Enlace a la fuente original:	https://onlinelibrary.wiley.com/doi/full/10.1111/pala.12541
Versión del articulo depositado:	info:eu-repo/semantics/publishedVersion
Acceso a la licencia de uso:	https://creativecommons.org/licenses/by/3.0/es/
Departamento:	Enginyeria Mecànica
URL Documento de licencia:	https://repositori.urv.cat/ca/proteccio-de-dades/
Áreas temáticas:	Planejamento urbano e regional / demografia Paleontology Materiais Geociências Ecology, evolution, behavior and systematics Ciências biológicas i Ciências ambientais Biodiversidade Astronomia / física
Palabras clave:	Trilobite Substrate Record Predation Moulting Finite-element models Exuviation Evolution Early cambrian trilobites Biomechanics Arthropod
Entidad:	Universitat Rovira i Virgili
Fecha de alta del registro:	2024-07-27

Descripción:	Arthropods (i.e. insects, spiders, crustaceans, myriapods and others), are the most successful Phanerozoic animals. The group is characterized by the possession of a segmented body, jointed limbs and a hard cuticle that is episodically moulted. One highly successful but now extinct group of arthropods is the trilobites. Trilobites underwent episodic moulting (ecdysis), and most trilobites possess facial sutures, lines of weakness in the cephalon, via which the exuviae is shed and the animal emerges. However, zones of weakness appear to represent a structural trade-off or constraint, particularly during burrowing; sacrificing a consolidated head region useful in burrowing for the ability to moult. Here we reconcile this trade-off by using biomechanical modelling to demonstrate that facial sutures exist in regions of low stress during the application of burrowing loads. Furthermore, facial sutures and the structure of the cephalon enable sutured trilobites to withstand greater stresses than their non-suture counterparts. We suggest that this ability to withstand greater burrowing loads enabled trilobites to successfully invade bioturbated and more consolidated sediments of the Cambrian Sediment Revolution, thus facilitating their diversification in the Cambrian and Ordovician and contributing to the evolutionary success of this iconic arthropod group.
Tipo:	Journal Publications
Coautor:	Universitat Rovira i Virgili
Títol:	Cephalic biomechanics underpins the evolutionary success of trilobites
Materia:	Ecology, Evolution, Behavior and Systematics,Paleontology Trilobite Substrate Record Predation Moulting Finite-element models Exuviation Evolution Early cambrian trilobites Biomechanics Arthropod Planejamento urbano e regional / demografia Paleontology Materiais Geociências Ecology, evolution, behavior and systematics Ciências biológicas i Ciências ambientais Biodiversidade Astronomia / física
Fecha:	2021
Autor:	Esteve J Marcé-Nogué J Pérez-Peris F Rayfield E
Derechos:	info:eu-repo/semantics/openAccess

Busca tu registro en:

Archivos desponibles
Archivo	Descripción	Formato
DocumentPrincipal	DocumentPrincipal	application/pdf

Todos los objetos de esta colección

Información