Molar occlusion and jaw roll in early crown mammals

Jäger, Kai R. K.; Cifelli, Richard L.; Martin, Thomas

doi:10.1038/s41598-020-79159-4

Cited by 11 publications

(12 citation statements)

References 55 publications

(58 reference statements)

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“…Mammalian molars evolved from simple, conical precursor forms (haplodontic) with one cusp (protocone) and one root, more or less rotationally or bilaterally symmetric. The triconodontic upper molar scheme shows two roots and three main cusps (paracone, protocone and metacone, with smaller additional cusps), in upper molars arranged more or less in a single row [56,57]. A triconodontic tooth scheme, therefore, shows bilateral symmetry to a frontal plane and to a sagittal plane.…”

Section: Symmetry Of Teeth and Dental Archesmentioning

confidence: 99%

Symmetry and Aesthetics in Dentistry

Runte

Dirksen

2021

Symmetry

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Animal bodies in general and faces in particular show mirror symmetry with respect to the median-sagittal plane, with exceptions rarely occurring. Bilateral symmetry to the median sagittal plane of the body also evolved very early. From an evolutionary point of view, it should therefore have fundamental advantages, e.g., more effective locomotion and chewing abilities. On the other hand, the recognition of bilaterally symmetric patterns is an important module in our visual perception. In particular, the recognition of faces with different spatial orientations and their identification is strongly related to the recognition of bilateral symmetry. Maxillofacial surgery and Dentistry affect effective masticatory function and perceived symmetry of the lower third of the face. Both disciplines have the ability to eliminate or mitigate asymmetries with respect to form and function. In our review, we will demonstrate symmetric structures from single teeth to the whole face. We will further describe different approaches to quantify cranial, facial and dental asymmetries by using either landmarks or 3D surface models. Severe facial asymmetries are usually caused by malformations such as hemifacial hyperplasia, injury or other diseases such as Noma or head and neck cancer. This could be an important sociobiological reason for a correlation between asymmetry and perceived disfigurement. The aim of our review is to show how facial symmetry and attractiveness are related and in what way dental and facial structures and the symmetry of their shape and color influence aesthetic perception. We will further demonstrate how modern technology can be used to improve symmetry in facial prostheses and maxillofacial surgery.

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Section: Symmetry Of Teeth and Dental Archesmentioning

confidence: 99%

Symmetry and Aesthetics in Dentistry

Runte

Dirksen

2021

Symmetry

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“…Our predicted body mass range of 57.73-128.97 g based on molar length, 16.38-51.04 g based on molar width, 37.50 g based on humeral length, and 30.60 and 26.03 g based on the diameter of the humerus. Notably, the predictions derived from the humerus midshaft diameter are only about 75% of the magnitude of predictions by Jäger et al (2020) based on humeral circumference (40.9-45.9 g). This means that the partial discrepancy between predictions based on craniodental and postcranial predictors in P. fruitaensis is greater in our study than what they reported, but consistent with the rest of the taxa within Triconodontidae in this study.…”

Section: Cranial-postcranial Disparity In Triconodontid Body Mass Pre...mentioning

confidence: 75%

“…For example, the estimated basal metabolic rate of triconodontids is only half of that calculated using previous body mass predictions (0.5 W for a 100 g mammal and 0.23 W for a 30 g mammal; Kolokotrones et al 2010). The smaller predicted body mass of triconodontids also suggest that while some may have incorporated both vertebrate and invertebrate prey into their diets (Jäger et al 2020), most probably subsisted primarily on invertebrates. The nuance of these patterns opens a wide range of potential future research, including exactly how such constraints relate to the proximate genetic and developmental drivers of these dynamics.…”

Section: Re-evaluation Of Eutriconodonta Body Massmentioning

confidence: 77%

“…The possibility of extrapolation is further evident from the fact that our models derived from the midshaft diameter of the femur and humerus have slopes that are smaller than those of Campione & Evans (2012). We thus used our models to reanalyse data from Jäger et al (2020) and included additional measurements derived from their published figures. Our predicted body mass range of 57.73-128.97 g based on molar length, 16.38-51.04 g based on molar width, 37.50 g based on humeral length, and 30.60 and 26.03 g based on the diameter of the humerus.…”

Section: Cranial-postcranial Disparity In Triconodontid Body Mass Pre...mentioning

confidence: 99%

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High‐precision body mass predictors for small mammals: a case study in the Mesozoic

Huang,

Wilson,

Bhullar

et al. 2024

Palaeontology

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Body mass is a pivotal quantity in palaeobiology but must be inferred from an imperfect fossil record. We analyse the performance of regression models derived from various dentoskeletal predictors in mammals to inform fossils from the early, Mesozoic history of this radiation. Our focus is on the critical small end of the size spectrum; critical because the earliest mammals were small, because small size persisted onto the stems of the major extant radiations, and because small mammals compose a large proportion of crown diversity. The sampling strategy is diverse in terms of both phylogeny and skeletal predictors: the former allows a general application, while the latter enables comparison of various models. Linear regressions based on extant small mammals indicate a universal correlation of body mass with observed measurements, but with clear differences in precision. Postcranial predictors outperform jaw and dental metrics, with certain femoral joint dimensions providing surprisingly precise predictions. Our results indicate complex patterns of size evolution within the small‐bodied category, including the possibility that multiple Mesozoic species approached the theoretical lower limit of mammalian body size. The ability to study such dynamics only becomes possible when predicting body mass within a strict, highly focused phylogenetic context. The heuristic value of the models we provide here is not limited to the Mesozoic but is applicable to small‐bodied mammals of any geologic age.

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“…These differences include a single replacement, rather than continual loss and replacement of teeth (diphydonty rather than polyphydonty), heterodonty (varied tooth shapes in different parts of the jaw) rather than homodonty (uniform tooth shapes throughout the jaw), and most importantly for the evolution of the TMJ, occlusion of the upper and lower dentition. Occlusion is facilitated by complimentary cusp patterns in the upper and lower dentition for shearing and crushing of food items (Crompton, 1981 ; Grossnickle et al, 2021 ; Jäger et al, 2020 ). The changes in the dentition would have put more strain on the primary jaw joint, leading to the added involvement of additional bones to buttress these effects and support the jaw during movement (Crompton & Hylander, 1986 ).…”

Section: Architecture Of the Tmjmentioning

confidence: 99%

Evolution and development of the mammalian jaw joint: Making a novel structure

Anthwal

Tucker

2022

Evolution and Development

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A jaw joint between the squamosal and dentary is a defining feature of mammals and is referred to as the temporomandibular joint (TMJ) in humans.Driven by changes in dentition and jaw musculature, this new joint evolved early in the mammalian ancestral lineage and permitted the transference of the ancestral jaw joint into the middle ear. The fossil record demonstrates the steps in the cynodont lineage that led to the acquisition of the TMJ, including the expansion of the dentary bone, formation of the coronoid process, and initial contact between the dentary and squamosal. From a developmental perspective, the components of the TMJ form through tissue interactions of muscle and skeletal elements, as well as through interaction between the jaw and the cranial base, with the signals involved in these interactions being both biomechanical and biochemical. In this review, we discuss the development of the TMJ in an evolutionary context. We describe the evolution of the TMJ in the fossil record and the development of the TMJ in embryonic development.We address the formation of key elements of the TMJ and how knowledge from developmental biology can inform our understanding of TMJ evolution.

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Molar occlusion and jaw roll in early crown mammals

Cited by 11 publications

References 55 publications

Symmetry and Aesthetics in Dentistry

Symmetry and Aesthetics in Dentistry

High‐precision body mass predictors for small mammals: a case study in the Mesozoic

Evolution and development of the mammalian jaw joint: Making a novel structure

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