Searching for Dental Signals of Exudativory in Galagos

Burrows, Anne M.; Nash, Leanne T.

doi:10.1007/978-1-4419-6661-2_11

Cited by 57 publications

(23 citation statements)

References 72 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition to these linear measurements, a biomechanical shape variable for the ability of the toothcomb to resist bending in the parasagittal plane, as may be experienced during gouging activities, was also calculated (see Burrows and Nash, ; Vinyard, personal communication). To create this shape variable, the second moment of area for the toothcomb ( I xx ) was calculated.…”

Section: Methodssupporting

confidence: 80%

“…As an alternative, we used the geometric mean of linear measures of size as a scaler for each dental variable (Mosiman, ; Jungers et al, ; Sokal and Rohlf, ; Coleman, ). In the present study, 16 craniodental variables were used to compute the geometric mean of each specimen (definitions shown in Table ): toothcomb mesiodistal length (TCL), toothcomb height (TCH), toothcomb labiolingual breadth (TCB), P 2 mesiodistal length (mandPL), P 2 vertical height (mandPH), P 2 buccolingual breadth (mandPB), M 3 buccolingual breadth (mandMB), M 3 mesiodistal length (mandML), maxillary canine mesiodistal length (maxCL), maxillary canine vertical height (maxCH), maxillary canine buccolingual breadth (maxCB), P 2 mesiodistal length (maxPL), P 2 vertical height (maxPH), P 2 buccolingual breadth (maxPB), maximum skull length, and maximum palatal length (after Burrows & Nash, ).…”

Section: Methodssupporting

confidence: 56%

“… ( a ) Occlusal view of the mandibular dentition and, ( b ), lateral view of the right dentary in a representative specimen of Nycticebus coucang demonstrating select linear measurements used in the present study (after Burrows and Nash, ). In (a), the distance between the black dots at the toothcomb represents toothcomb mesiodistal length (TCL); the distance between the white dots at I 2 represents toothcomb height (TCH); the distance between the black dots at M 3 represents breadth (mandMB).…”

Section: Methodsmentioning

confidence: 99%

“…Eaglen () explained morphometric variation among taxa in the toothcomb as instead being more reflective of selection for a grooming function, a notion that has been suggested in other studies (e.g., Eaglen, ; Rose et al, ; Rosenberger and Strasser, ; Asher, ). Recently, Burrows and Nash () demonstrated few morphometric differences in the toothcomb of highly exudativorous galagos ( Euoticus elegantulus and Otolemur crassicaudatus ) relative to galagos that do not intensively consume exudates. Most morphometric dental differences were evident in the relatively larger upper and lower premolars and the upper canine in exudate‐specialists relative to the non‐specialists.…”

mentioning

confidence: 99%

See 3 more Smart Citations

Exudativory in the Asian loris, Nycticebus: Evolutionary divergence in the toothcomb and M₃

Burrows

Hartstone‐Rose

Nash

2015

American J Phys Anthropol

Self Cite

View full text Add to dashboard Cite

The more robust, "squared off" toothcomb in Nycticebus matches behavioral observations that these primates gouge to access exudates. Results of the present study indicate that the toothcomb is the likely candidate for the dental tool used in gouging. The size reduction of the lower last molar in Nycticebus, a trait also found in a previous study in exudativorous galagos, may indicate that there is reduced selective pressure in a diet where little mastication would be needed to mechanically process exudates. These results may indicate that reduction in molar size could be a potential dental signature for exudativory, but further studies on a wider phylogenetic range of exudativorous primates would be necessary.

show abstract

Section: Methodssupporting

confidence: 80%

Section: Methodssupporting

confidence: 56%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Exudativory in the Asian loris, Nycticebus: Evolutionary divergence in the toothcomb and M₃

Burrows

Hartstone‐Rose

Nash

2015

American J Phys Anthropol

Self Cite

View full text Add to dashboard Cite

show abstract

“…For example, dentition within primates that are primarily seed-eaters, gum and sap-eaters, and fruit feeders shows unique morphological features linked to acquiring and processing these particular foods (e.g. Hylander, 1975;Lambert et al 2004;Burrows & Nash, 2010;Burrows et al 2015). Mandibular morphology has similarly been linked to dietary niche across a range of primate taxa (e.g.…”

Section: Ecomorphological Relationships In Primate Mimetic Musculaturementioning

confidence: 99%

Social variables exert selective pressures in the evolution and form of primate mimetic musculature

Burrows

Waller

et al. 2016

Journal of Anatomy

Self Cite

View full text Add to dashboard Cite

Mammals use their faces in social interactions more so than any other vertebrates. Primates are an extreme among most mammals in their complex, direct, lifelong social interactions and their frequent use of facial displays is a means of proximate visual communication with conspecifics. The available repertoire of facial displays is primarily controlled by mimetic musculature, the muscles that move the face. The form of these muscles is, in turn, limited by and influenced by phylogenetic inertia but here we use examples, both morphological and physiological, to illustrate the influence that social variables may exert on the evolution and form of mimetic musculature among primates. Ecomorphology is concerned with the adaptive responses of morphology to various ecological variables such as diet, foliage density, predation pressures, and time of day activity. We present evidence that social variables also exert selective pressures on morphology, specifically using mimetic muscles among primates as an example. Social variables include group size, dominance 'style', and mating systems. We present two case studies to illustrate the potential influence of social behavior on adaptive morphology of mimetic musculature in primates: (1) gross morphology of the mimetic muscles around the external ear in closely related species of macaque (Macaca mulatta and Macaca nigra) characterized by varying dominance styles and (2) comparative physiology of the orbicularis oris muscle among select ape species. This muscle is used in both facial displays/expressions and in vocalizations/human speech. We present qualitative observations of myosin fiber-type distribution in this muscle of siamang (Symphalangus syndactylus), chimpanzee (Pan troglodytes), and human to demonstrate the potential influence of visual and auditory communication on muscle physiology. In sum, ecomorphologists should be aware of social selective pressures as well as ecological ones, and that observed morphology might reflect a compromise between the demands of the physical and the social environments.

show abstract

Folivory, frugivory, and postcanine size in the cercopithecoidea revisited

Scott

2011

American J Phys Anthropol

View full text Add to dashboard Cite

At a given body mass, folivorous colobines have smaller postcanine teeth than frugivorous cercopithecines. This distinction is a notable exception to the general tendency for folivorous primates to have relatively larger postcanine tooth rows than closely related frugivores. The reason for this anomalous pattern is unclear, but one potential explanation is that the difference in facial size between these two subfamilies confounds the comparison-i.e., it may be that the large postcanine teeth of cercopithecines are a consequence of their large faces. The goal of this study was to test this hypothesis. Phylogenetic comparative methods were used to examine the relationships among postcanine area, facial size, and body mass in 29 anthropoid primates, including eight colobines and eight cercopithecines. Results indicate that there is a strong and highly significant partial correlation between postcanine area and facial size when body mass is held constant, which supports the hypothesis that facial size has an important influence on postcanine size. Moreover, colobines have larger postcanine teeth relative to facial size than cercopithecines. Surprisingly, when facial size is held constant, the partial correlation between postcanine area and body mass is weak and nonsignificant. These results suggest that facial size may be more appropriate than body mass for size-adjusting postcanine measurements in some contexts. A phylogenetic comparative test of the association between diet and relative postcanine size (scaled using facial size) confirms that folivorous anthropoids are characterized by relatively large postcanine teeth in comparison to closely related nonfolivores.

show abstract

Searching for Dental Signals of Exudativory in Galagos

Cited by 57 publications

References 72 publications

Exudativory in the Asian loris, Nycticebus: Evolutionary divergence in the toothcomb and M₃

Exudativory in the Asian loris, Nycticebus: Evolutionary divergence in the toothcomb and M₃

Social variables exert selective pressures in the evolution and form of primate mimetic musculature

Folivory, frugivory, and postcanine size in the cercopithecoidea revisited

Contact Info

Product

Resources

About

Searching for Dental Signals of Exudativory in Galagos

Cited by 57 publications

References 72 publications

Exudativory in the Asian loris, Nycticebus: Evolutionary divergence in the toothcomb and M3

Exudativory in the Asian loris, Nycticebus: Evolutionary divergence in the toothcomb and M3

Social variables exert selective pressures in the evolution and form of primate mimetic musculature

Folivory, frugivory, and postcanine size in the cercopithecoidea revisited

Contact Info

Product

Resources

About

Exudativory in the Asian loris, Nycticebus: Evolutionary divergence in the toothcomb and M₃

Exudativory in the Asian loris, Nycticebus: Evolutionary divergence in the toothcomb and M₃