Applying tribology to teeth of hoofed mammals

Schulz, Ellen; Calandra, Ivan; Kaiser, Thomas M.

doi:10.1002/sca.20181

Cited by 117 publications

(155 citation statements)

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“…between certain distantly related taxa), but to document differences in diet when they might not necessarily be expected based on tooth morphology alone. Differences between closely related taxa have been captured, for instance, in bovids (Scott, 2012; Ungar, Merceron, & Scott, 2007), cervids (Berlioz, Kostopoulos, Blondel, & Merceron, 2017), ungulates (Schulz, Calandra, & Kaiser, 2010), feliforms (DeSantis & Haupt, 2014; DeSantis, Tseng, et al, 2017), canids (DeSantis et al, 2015), primates (Scott et al, 2005; Ungar, Grine, & Teaford, 2008), and macropodids (DeSantis, Field, Wroe, & Dodson, 2017; Prideaux et al, 2009). Indeed, many bioarchaeological studies have demonstrated distinctive and predictable diet‐related differences in both gross dental wear and microwear within a single species, Homo sapiens (Rose & Ungar, 1998).…”

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confidence: 99%

The phylogenetic signal in tooth wear: What does it mean?

DeSantis

Grine

Janis

et al. 2018

Ecology and Evolution

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A new study by Fraser et al (2018) urges the use of phylogenetic comparative methods, whenever possible, in analyses of mammalian tooth wear. We are concerned about this for two reasons. First, this recommendation may mislead the research community into thinking that phylogenetic signal is an artifact of some sort rather than a fundamental outcome of the evolutionary process. Secondly, this recommendation may set a precedent for editors and reviewers to enforce phylogenetic adjustment where it may unnecessarily weaken or even directionally alter the results, shifting the emphasis of analysis from common patterns manifested by large clades to rare cases.

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confidence: 99%

The phylogenetic signal in tooth wear: What does it mean?

DeSantis

Grine

Janis

et al. 2018

Ecology and Evolution

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“…Butler himself (1978, p. 451) stated: 'Let those who are contemplating the introduction of new names pause to consider whether in so doing they are advancing the subject or making it more difficult to understand' . We aim for a broader comparative nomenclature that helps to describe facets for dental occlusion analysis (Kullmer et al 2009(Kullmer et al , 2012Fiorenza et al 2011;Benazzi et al 2013) and the analysis of masticatory biomechanics (Schulz & Kaiser 2010;Calandra et al 2012; offer the opportunity to characterize facets in more detail. Kaiser and Brinkmann (2006) introduced a labeling system of occlusal enamel ridge patterns in bovids and equids as a strictly function-orientated system that numbers facets (adopted from Janis 1990).…”

Section: Challenges For Comparative Studiesmentioning

confidence: 99%

“…This system refers to the sequence of the antagonistic contact of facets, and in addition indicates the longitudinal position of the facet in relation to the cusp. Schulz and Kaiser (2010) applied the labeling system of Kaiser and Brinkmann (2006) to facets of upper and lower teeth that allow 3D surface texture measurements to infer oral behavior (e.g. diet reconstruction and chewing function) based on microscopic wear features.…”

Section: Challenges For Comparative Studiesmentioning

confidence: 99%

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Modular Wear Facet Nomenclature for mammalian post-canine dentitions

et al. 2017

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Dental wear facets on the occlusal surface of premolars and molars are traces of their main function, the mastication and therefore reflect masticatory movements and also paramasticatory (i.e. non-dietary use of teeth) behavior. Here we present the Modular Wear Facet Nomenclature applicable to most mammalian dentitions. Topographic positions of wear facets in relation to the major cusps and crests of the teeth are used to designate the areas of the occlusal surface the facets occupy (e.g. their mesial, distal, lingual, or buccal position). Previous published systems for labeling wear facets have been inconsistent with each other. Therefore, we provide a synoptic review of the most widely-used terminologies, and introduce the alternative Modular Wear Facet Nomenclature. This nomenclature aims to overcome the difficulties caused by the existing inconsistent wear facet terminologies. Our new approach is applicable to dentitions where the occlusal morphology does not change significantly for most of the lifetime of the animal. In those dentitions, the primary occlusal surfaces are not significantly modified as wear facets become more extensive with wearing. This appears to be a common pattern in pre-tribosphenic, tribosphenic molars, and the teeth derived from tribosphenic precursors (e.g. bunodont molar morphologies). In teeth where the secondary occlusal surface is functionally intensely modified (i.e. high-crowned and evergrowing teeth with large areas of dentine exposed) any facet labeling system appears to be challenging, since the identification of individual facets is blurred and their spatial position may be indeterminable.

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“…Applied to biological materials, the method is nondestructive and yields information-rich data sets containing both topography and reflective intensity for each coordinate in the field of view. OT has as yet seen limited application in biology, revealing details of wear on grazing ungulate teeth in one of the few published applications (Schulz et al, 2010). Here, we apply OT technology to the analysis of the cellular makeup of the plant epidermis and, in so doing, demonstrate its high-throughput, wide spatiotemporal resolution and stunning dimensionality.…”

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Application of Optical Topometry to Analysis of the Plant Epidermis

2015

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The plant epidermis regulates key physiological functions contributing to photosynthetic rate, plant productivity, and ecosystem stability. Yet, quantitative characterization of this interface between a plant and its aerial environment is laborious and destructive with current techniques, making large-scale characterization of epidermal cell parameters impractical. Here, we present our exploration of optical topometry (OT) for the analysis of plant organ surfaces. OT is a mature, confocal microscopybased implementation of surface metrology that generates nanometer-scale digital characterizations of any surface. We report epidermal analyses in Arabidopsis (Arabidopsis thaliana) and other species as well as dried herbarium specimens and fossilized plants. We evaluate the technology's analytical potential for identifying an array of epidermal characters, including cell type distributions, variation in cell morphology and stomatal depth, differentiation of herbarium specimens, and real-time deformations in living tissue following detachment. As applied to plant material, OT is very fast and nondestructive, yielding richly mineable data sets describing living tissues and rendering a variety of their characteristics accessible for statistical, quantitative genetic, and structural analysis.High-throughput methodologies are enabling ever more precise and integrated analyses of plant genomes, transcriptomes, proteomes, and metabolomes. However, connecting such comprehensive molecular data sets to the higher orders of plant organization that they control depends upon capturing correspondingly precise and authentic quantitative depictions of plant cell biology, anatomy, and developmental features. Highthroughput phenotyping techniques, enabling the speed and accuracy of data acquisition characteristic of omic technologies, are now needed if we are to forge mechanistic links between macroscopic plant phenotypes and their molecular underpinnings.This report addresses the challenge of structurally phenotyping the plant epidermis. A widely used and cost-effective method for quantifying epidermal phenotypes employs nail polish and/or dental resin to create an impression of the tissue surface, followed by imaging under light microscopy (Geisler et al., 2000;Delgado et al., 2011). Resultant images are then manually quantified using image analysis software such as ImageJ or Cell Profiler, yielding outputs such as cell sizes, stomatal index (number of stomata per total cell number), or stomatal density (number of stomata per unit area). Methods appropriate for smaller scale studies involve tissue fixation and staining or transgenic marker lines (Dow et al., 2014;Lawson et al., 2014). These current methods share common disadvantages of tedious sample preparation and low throughput. More elaborate methods involving fluorescence and electron microscopy are encumbered by the additional disadvantage of higher imaging equipment costs (Salomon et al., 2010). Finally, nearly all of these methods are somewhat or completely destructive, allo...

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Applying tribology to teeth of hoofed mammals

Cited by 117 publications

References 35 publications

The phylogenetic signal in tooth wear: What does it mean?

The phylogenetic signal in tooth wear: What does it mean?

Modular Wear Facet Nomenclature for mammalian post-canine dentitions

Application of Optical Topometry to Analysis of the Plant Epidermis

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