The relationship between cranial structure, biomechanical performance and ecological diversity in varanoid lizards

This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.Skull structure is intimately associated with feeding ability in vertebrates, both in terms of specific performance measures and general ecological characteristics. This study quantitatively assessed variation in the shape of the cranium and mandible in varanoid lizards, and its relationship to structural performance (von Mises strain) and interspecific differences in feeding ecology. Geometric morphometric and linear morphometric analyses were used to evaluate morphological differences, and finite element analysis was used to quantify variation in structural performance (strain during simulated biting, shaking and pulling). This data was then integrated with ecological classes compiled from relevant scientific literature on each species in order to establish structure-function relationships. Finite element modelling results showed that variation in cranial morphology resulted in large differences in the magnitudes and locations of strain in biting, shaking and pulling load cases. Gracile species such as Varanus salvadorii displayed high strain levels during shaking, especially in the areas between the orbits. All models exhibit less strain during pull back loading compared to shake loading, even though a larger force was applied (pull =30N, shake = 20N). Relationships were identified between the morphology, performance, and ecology. Species that did not feed on hard prey clustered in the gracile region of cranial morphospace and exhibited significantly higher levels of strain during biting (P = 0.0106). Species that fed on large prey clustered in the elongate area of mandible morphospace. This relationship differs from those that have been identified in other taxonomic groups such as crocodiles and mammals. This difference may be due to a combination of the open 'space-frame' structure of the varanoid lizard skull, and the 'pull back' behaviour that some species use for processing large prey.

Neuroimaging and electrophysiology efficacy in measuring acute effects and long-term sequelae following sports-related concussion

Traumatic brain injury (TBI) is a complex pathophysiological process resulting from external forces applied to the skull and affecting the brain. TBI is a significant global contributor to disability and death, particularly in children and young adults. The severity of a TBI may range from "mild" (a brief change in mental status or consciousness) to "severe" (an extended period of unconsciousness or amnesia after the injury), with mild TBI (mTBI) the most common form, diagnosed in 80-90% of cases. Sports-related concussion contributes significantly to mTBI accounting for nearly 20% of all mTBI cases. In the past decade there has been increasing growing public concern regarding the association of sports concussion; in particular further chance of recurrent injury following a concussion due to transient cognitive impairments, and long-term detrimental mental health issues and deterioration in brain function as a consequence of multiple concussions. Attention is also turning to methods to assess concussion with questions surrounding the reliability in traditional methods of concussion assessment that include symptom observation and cognitive assessment. This chapter will discuss the neuroscience of sports-related concussion, reviewing the evidence from new and rigorous methods of concussion assessment, such as neuroimaging and electrophysiology, with a focus on transcranial magnetic stimulation, following acute concussive events through tolong-term manifestations of multiple concussions.

'A dark / Inscrutable workmanship:' Shining a ‘scientific’ light on emotion and poiesis

Max Nordau’s physiognomic study of criminality, Degeneration (1895), notably dedicated to the Italian pioneer of criminal anthropology Cesare Lombroso, labels poets and other artists—alongside criminals, prostitutes, anarchists, and lunatics—as ‘degenerates’. The Symbolist poets come under particular scrutiny in Nordau’s pseudo-scientific study. Paul Verlaine is described as ‘a repulsive degenerate subject with asymmetric skull and Mongolian face’ (1920 [1895]:128), while Stéphane Mallarmé is said to have ‘long, pointed, faun-like ears’ (131). The emotional and metaphorical intensity of their poetry, for Nordau, is another reflection of their alleged degeneracy. These poets write ‘twaddle’ (116), engaging in a ‘babbling and stammering’ (119) resonant of children and animals, which only ‘imbeciles and idiots’ profess to understand. While the Symbolists are viewed as avant-garde, Nordau is at pains to demonstrate that their irrational use of language actually exposes them as atavistic. Nordau proclaims: ‘clear speech serves the purpose of communication of the actual’ (118). By contrast, the Symbolists, ‘so far as they are honestly degenerate and imbecile, can think only in a mystical, that is, in a confused way… their emotions override their ideas.’

Identified by Nordau as one of the fin de siècle’s degenerates, Oscar Wilde evoked Nordau’s book in a petition for clemency when he was imprisoned in 1896, arguing that Nordau’s findings proved he required medical rather than punitive intervention. His plea was not successful, with Wilde later quipping: ‘I quite agree with Dr Nordau’s assertion that all men of genius are insane, but Dr Nordau forgets that all sane people are idiots’ (cited in Hitchens 2000: 18).

Software for Designing Custom Orbital-Craniofacial Implant Plans

Purpose: Custom cranio-orbital implants have been shown to achieve better performance than their hand-shaped counterparts by restoring skull anatomy more accurately and by reducing surgery time. Designing a custom implant involves reconstructing a model of the patient's skull using their computed tomography (CT) scan. The healthy side of the skull model, contralateral to the damaged region, can then be used to design an implant plan. Designing implants for areas of thin bone, such as the orbits, is challenging due to poor CT resolution of bone structures. This makes preoperative design time-intensive since thin bone structures in CT data must be manually segmented. The objective of this thesis was to research methods to accurately and efficiently design cranio-orbital implant plans, with a focus on the orbits, and to develop software that integrates these methods. Methods: The software consists of modules that use image and surface restoration approaches to enhance both the quality of CT data and the reconstructed model. It enables users to input CT data, and use tools to output a skull model with restored anatomy. The skull model can then be used to design the implant plan. The software was designed using 3D Slicer, an open-source medical visualization platform. It was tested on CT data from thirteen patients. Results: The average time it took to create a skull model with restored anatomy using our software was 0.33 hours ± 0.04 STD. In comparison, the design time of the manual segmentation method took between 3 and 6 hours. To assess the structural accuracy of the reconstructed models, CT data from the thirteen patients was used to compare the models created using our software with those using the manual method. When registering the skull models together, the difference between each set of skulls was found to be 0.4 mm ± 0.16 STD. Conclusions: We have developed a software to design custom cranio-orbital implant plans, with a focus on thin bone structures. The method described decreases design time, and is of similar accuracy to the manual method.