Now showing 1 - 2 of 2
  • Publication
    Morphology, Biomechanics and Diet in Anthropoidea (Primates)
    (2019-03-11)
    Luk, Hiu Ying
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    ; ;
    Sherratt, Emma
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    In recent years there have been an increasing number of studies investigating the relationship between diet preference, skull shape and biomechanics of primates. Understanding the relationship between morphological and mechanical variations and extrinsic factors, such as diet and feeding behaviour, provides insights into the evolution of our own species. However, most diet-related morphological studies have focused on the mandibles and dentition, while most biomechanical studies have concentrated on species that either feed on mechanically challenging foods (hard-object feeders) or are mechanically challenged during food acquiring (e.g., tree-gouging exudate feeders). These mechanical studies are usually small scale with only a few species and there is a lack more comprehensive comparisons. Studies on the relationship between cranial shape and biomechanical performances in primates are also limited. In the present study, whether cranial morphology and/or mechanical performance reflect dietary preferences were examined in Anthropoidea, which is a clade of primates that includes all the New World and Old World monkeys. It was hypothesised that cranial shape and its mechanical behaviour reflect diet regardless of phylogeny and cranial size.

    Three-dimensional geometric morphometrics was used to investigate the relationship between cranial shape and diet. Finite element analysis was used to assess the mechanical performance in the anthropoid crania during premolar, molar, and incisor loadings. Von Mises strain magnitudes and distributions were used to determine the ability to withstand high bite forces. Mechanical advantages were calculated as the ratio of bite force per muscle force. Results showed that diet had very limited influence on cranial morphology. New World monkeys generally exhibited a stronger correlation between diet and cranial shape than Old World monkeys. This suggested that cranial morphology in primates was not the sole result of dietary selection. Variations of strain magnitudes were also found to be mostly insignificant with diet. However, results showed that mechanical advantages were a better predictor of diet preference, especially for species that require higher bite forces during feeding. Hard food feeders were more mechanically efficient at producing high premolar and molar bites compared to other dietary groups. Exudate feeders were also relatively efficient at producing high bite forces at the incisors. While cranial morphology was found to have limited correlation with diet, there was a strong relationship between cranial shape and mechanical advantage. This result indicated that mechanical advantage can be achieved by different combinations of craniofacial features.

  • Publication
    Basicranium and face: Assessing the impact of morphological integration on primate evolution
    (Academic Press, 2018)
    Neaux, Dimitri
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    ; ; ;
    Luk, Theodora
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    The basicranium and facial skeleton are two integrated structures displaying great morphological diversity across primates. Previous studies focusing on limited taxonomic samples have demonstrated that morphological integration has a significant impact on the evolution of these structures. However, this influence is still poorly understood. A more complete understanding of craniofacial integration across primates has important implications for functional hypotheses of primate evolution. In the present study, we analyzed a large sample of primate species to assess how integration affects the relationship between basicranial and facial evolutionary pathways across the order. First, we quantified integration and modularity between basicranium and face using phylogenetically-informed partial least squares analyses. Then, we defined the influence of morphological integration between these structures on rates of evolution, using a time-calibrated phylogenetic tree, and on disparity through time, comparing the morphological disparity across the tree with that expected under a pure Brownian process. Finally, we assessed the correlation between the basicranium and face, and three factors purported to have an important role in shaping these structures during evolution: endocranial volume, positional behavior (i.e., locomotion and posture), and diet. Our findings show that the face and basicranium, despite being highly integrated, display significantly different evolutionary rates. However, our results demonstrate that morphological integration impacted shape disparity through time. We also found that endocranial volume and positional behavior are important drivers of cranial shape evolution, partly affected by morphological integration.