Alexis M. Wiktorowicz-Conroy scite author profile

Many bones are supported internally by a latticework of trabeculae. Scaling of whole bone length and diameter has been extensively investigated, but scaling of the trabecular network is not well characterized. We analysed trabecular geometry in the femora of 90 terrestrial mammalian and avian species with body masses ranging from 3 g to 3400 kg. We found that bone volume fraction does not scale substantially with animal size, while trabeculae in larger animals' femora are thicker, further apart and fewer per unit volume than in smaller animals. Finite element modelling indicates that trabecular scaling does not alter the bulk stiffness of trabecular bone, but does alter strain within trabeculae under equal applied loads. Allometry of bone's trabecular tissue may contribute to the skeleton's ability to withstand load, without incurring the physiological or mechanical costs of increasing bone mass.

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Temporal gait parameters in the alpaca and the evolution of pacing and trotting locomotion in the Camelidae

Pfau

Hinton

Whitehead

et al. 2011

Journal of Zoology

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Alpacas are increasingly popular as domesticated companion and commercial animals. Their footfall patterns, however, are not well documented. It would be fascinating to know if artificial selection has changed alpacas' locomotor patterns from the ancestral condition in the vicu˜na. Some members of the Camelidae pace rather than trot, but the gaits of most species have not been studied quantitatively. Thus, investigating alpacas' gaits might contribute to understanding the factors influencing gait choice and evolution. We aimed to quantify the temporal footfall patterns of alpacas to determine observed gaits and to describe gait parameters as a function of speed. Kinematic data (3D motion capture) of locomotor patterns over a range of speeds were collected from four alpacas. We quantified the influence of speed on stance time, swing time, stride time (and frequency), duty factor and stride length, and created gait diagrams for symmetrical and asymmetrical gaits. Alpacas moved using lateral sequence walks, mainly lateral couplets walks and runs with some lateral sequence, singlefoot footfall patterns. Remarkably, the alpacas never truly paced or trotted. At faster speeds, they switched to asymmetrical gaits, predominantly transverse gallops. With increasing speed, stance and stride times decreased, and stride frequencies and stride length increased. Swing times decreased slightly with speed for symmetrical gaits, and a tendency towards an increasing swing time was evident in asymmetrical gaits. It is still uncertain why quadrupeds choose particular gaits and intriguingly, extant camelids (alpacas, dromedary camels) do not trot. The apparent absence of pacing in alpacas deserves further investigation in an experimental and comparative framework. Yet, this absence seems inherited from their vicu˜na ancestors, indicating that pacing gaits may not be ancestral or common for Camelidae. Future studies should include kinetic and anatomical data to provide insight into wholebody mechanics, and include other unstudied species such as guanacos and vicu˜nas.

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3D Morphometric and Posture Study of Felid Scapulae Using Statistical Shape Modelling

et al. 2012

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We present a three dimensional (3D) morphometric modelling study of the scapulae of Felidae, with a focus on the correlations between forelimb postures and extracted scapular shape variations. Our shape modelling results indicate that the scapular infraspinous fossa becomes larger and relatively broader along the craniocaudal axis in larger felids. We infer that this enlargement of the scapular fossa may be a size-related specialization for postural support of the shoulder joint.

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Correction: Three-Dimensional Geometric Analysis of Felid Limb Bone Allometry

Doube¹,

Wiktorowicz-Conroy²,

Christiansen³

et al. 2009

PLoS ONE

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Background: Studies of bone allometry typically use simple measurements taken in a small number of locations per bone; often the midshaft diameter or joint surface area is compared to body mass or bone length. However, bones must fulfil multiple roles simultaneously with minimum cost to the animal while meeting the structural requirements imposed by behaviour and locomotion, and not exceeding its capacity for adaptation and repair. We use entire bone volumes from the forelimbs and hindlimbs of Felidae (cats) to investigate regional complexities in bone allometry.Method/Principal Findings: Computed tomographic (CT) images (16435 slices in 116 stacks) were made of 9 limb bones from each of 13 individuals of 9 feline species ranging in size from domestic cat (Felis catus) to tiger (Panthera tigris). Eleven geometric parameters were calculated for every CT slice and scaling exponents calculated at 5% increments along the entire length of each bone. Three-dimensional moments of inertia were calculated for each bone volume, and spherical radii were measured in the glenoid cavity, humeral head and femoral head. Allometry of the midshaft, moments of inertia and joint radii were determined. Allometry was highly variable and related to local bone function, with joint surfaces and muscle attachment sites generally showing stronger positive allometry than the midshaft.Conclusions/Significance: Examining whole bones revealed that bone allometry is strongly affected by regional variations in bone function, presumably through mechanical effects on bone modelling. Bone's phenotypic plasticity may be an advantage during rapid evolutionary divergence by allowing exploitation of the full size range that a morphotype can occupy. Felids show bone allometry rather than postural change across their size range, unlike similar-sized animals.

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Aracaniform Swimming: A Proposed New Category of Swimming Mode in Bony Fishes (Teleostei: Tetraodontiformes: Aracanidae)

Gordon

Lauritzen

Wiktorowicz-Conroy

et al. 2020

Physiological and Biochemical Zoology

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The deepwater boxfishes of the family Aracanidae are the phylogenetic sister group of the shallow-water, generally more tropical boxfishes of the family Ostraciidae. Both families are among the most derived groups of teleosts. All members of both families have armored bodies, the forward 70% of which are enclosed in rigid bony boxes (carapaces). There is substantial intragroup variation in both groups in body shapes, sizes, and ornamentation of the carapaces. Swimming-related morphology, swimming mode, biomechanics, kinematics, and hydrodynamics have been studied in detail in multiple species of the ostraciids. Ostraciids are all relatively high-performance median and paired fin swimmers. They are highly maneuverable. They swim rectilinearly with substantial dynamic stability and efficiency. Aracanids have not been previously studied in these respects. This article describes swimming-related aspects of morphology, swimming modes, biomechanics, and kinematics in two south Australian species (striped cowfish and ornate cowfish) that are possibly representative of the entire group. These species differ morphologically in many respects, both from each other and from ostraciids. There are differences in numbers, sizes, and placements of keels on carapaces. The most important differences from ostraciids are openings in the posterior edges of the carapaces behind the dorsal and anal fins. The bases of those fins in ostraciids are enclosed in bone. The openings in aracanids free the fins and tail to move. As a result, aracanids are body and caudal fin swimmers. Their overall swimming performances are less stable, efficient, and effective. We propose establishing a new category of swimming mode for bony fishes called "aracaniform swimming."

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