Foraging behavior of free-ranging Weddell seals (Leptonychotes weddelli) in the Antarctic fast-ice environment

Madden, Kiersten Marie, 1980-

29 August 2008

Detailed information on diet and foraging behavior is necessary for understanding predator-prey interactions and food-web dynamics. The primary objective of this dissertation was to gain a more complete understanding of the natural foraging behavior of Weddell seals (Leptonychotes weddellii) in McMurdo Sound, Antarctica using a video data recorder to document the seal's three-dimensional movements and encounters with prey. Seals exhibited a variety of dive types that could be sorted into five groups based on 18 dive descriptors. Three of these groups (deep aerobic, deep anaerobic, and shallow aerobic) were identified as foraging dives, the frequency of which varied with bathymetry. Deep aerobic foraging dives were similar in depth and duration to foraging dives in previous studies and were more common at offshore breathing holes. However, differences occurred between offshore free-ranging and isolated-hole dives in the behaviors involving descent and the frequency of certain behavioral transitions. These differences were responses by the seals to variations in prey abundance, rather than responses to a change in breathing hole availability. Even with an apparently homogenous sample of seals, there was significant individual variability in foraging success, behavior, diet, and foraging tactics. Dive depth, duration, distance, and energetic cost were important for explaining foraging success when seals dove in shallow areas where Antarctic silverfish (Pleuragramma antarcticum) were more difficult to reach and less abundant. However, the relationship between those variables was not the same for all individuals. Diet and foraging tactics also varied significantly among individuals diving near the coastline. Two coastal seals specialized on silverfish, while two others consumed silverfish and benthic prey. Although benthic prey were more accessible along the coastline than offshore, silverfish, which have a high lipid content, required less handling to consume. Thus, it may be energy-efficient for seals to specialize on silverfish at coastal locations despite the additional time and energy required to travel to depths where silverfish are located. These results helped us understand variability within Weddell seal populations and the basis upon which foraging decisions are made in response to changes in bathymetry, access to breathing holes, and prey abundance and availability.

Gait analysis of normal and total knee replacement subjects

Poon, Mei-ying, Dora., 潘美英.

January 1997

published_or_final_version / Orthopaedic Surgery / Master / Master of Philosophy

Total knee replacement.

Gait in humans.

Human locomotion.

Adaptation of locomotor control in able and impaired human walking

Toney, Megan

21 September 2015

Extensive research has documented the stereotypical kinematic and kinetic patterns in healthy human walking, but we have a limited understanding of the neuromechanical control principles that contribute to their execution. Furthermore, the strategies used to adapt human walking to morphological or environmental constraints are poorly understood. After a traumatic injury, like amputation, regaining independent mobility is a primary goal of rehabilitation. Without a clear understanding of the neuromechanical principles governing locomotion, monitoring and quantitatively improving gait rehabilitation outcomes is challenging. The purpose of this doctoral work was to identify controlled variables in able and impaired human walking and to compare the control strategies used to adapt to a novel walking environment both with and without amputation. I apply an uncontrolled manifold (UCM) analysis to test whether likely goal variables of human walking are selectively stabilized through step-to-step variability structure. I found that both able-bodied subjects and subjects with an amputation maintain consistent whole body dynamics and leg power production by exploiting inherent motor abundance. Consistent leg power production is accomplished primarily through step-to-step leg force corrections that are driven by variable timing of ankle torque production. Covariance between ankle and knee torques enable robust motor control in able-bodied individuals, but this stabilizing mechanism is absent in individuals with a transtibial amputation. This coordinated joint torque control also appears to assist able-bodied short-term adaptation, invoked by split-belt treadmill walking. However, loss of ankle motor control and distal sensory feedback due to amputation appears to limit reactive, feedback driven adaptation patterns in subjects with an amputation. Ultimately, this work highlights the role of intact distal sensorimotor function in locomotor control and adaptation. The major findings I present have substantial implications for gait rehabilitation and prosthetic design.

Biomechanics

Locomotion

Amputation

Motor control

Uncontrolled manifold

Adaptation

Split belt treadmill

Contribution of brain with or without visual cortex lesion to exploratory locomotion in the rat

Nemati, Farshad, University of Lethbridge. Faculty of Arts and Science

January 2008

Over the past five decades spatial behavior has been a subject of research interest in psychology and neuroscience, in part based on philosophical theories of mental spatial representations. In order to continue uncovering the facts regarding spatial behavior, the focus of this thesis was on the contribution of entry point and visual inputs to the organization of exploratory locomotion and spatial representation in the rat. Despite the contribution of the hippocampus to spatial abilities, the exploratory locomotion is still visually organized in rats with damage to the hippocampus. On the other hand, recent studies have demonstrated a contribution of visual areas to the spatial ability of the rat. Nevertheless, the contribution of visual cortex to the organization of exploratory locomotion has not been studied in an open field. The experiments in this thesis were designed to characterize the organization of exploratory locomotion to the point of entry and/or visual cues. Rats were started from the edge or center of an open table near or on which a salient object could be placed. The main findings were that rats organized their exploratory locomotion to their point of entry and modified their behavior as they encountered objects. Also, rats with damage to visual cortex displayed an extra-attachment to the visual objects and in contrast to controls did not expand their exploratory locomotion with time. The results are discussed with respect to the centrality of the entry point in the organization of exploratory locomotion and the neural network that control visual exploration in the rat. / xiii, 220 leaves : ill. ; 29 cm. --

Dissertations, Academic

Electronic dissertations

Spatial behavior in animals -- Research

Rats -- Behavior

Animal locomotion -- Research

Visual cortex -- Research

Targeted over-expression of hsp22 and the maintenance of locomotor activity of third instar larvae of Drosophila melanogaster at high temperatures

Joshi, Namrata

02 October 2007

Hsp22 has been implicated in stress tolerance and longevity in various organisms though its role in Drosophila melanogaster larval thermal tolerance has not yet been investigated. I undertook this project to determine if over-expression of hsp22 in either muscle or motor neurons could alter locomotor ability at high temperature in third instar larvae of D. melanogaster. A combination of the UAS-gal4 and tet-On promoter systems was used to over-express transgenic hsp22 in the larvae. A β-galactosidase assay was used to determine the level of gene expression following administration of different amounts of tetracycline. A concentration of 100 μg/ml of tetracycline was found to elicit appreciably higher expression of the reporter gene than 0 and 0.1 μg/ml of tetracycline. Locomotor ability of larvae was assessed at a temperature of approximately 400C by measuring the time to movement failure (TMF). Larvae that were fed 100 μg/ml of tetracycline showed a significant decline in the TMF, which could be attributed to the presence of tetracycline at a concentration of 100 μg/ml. Possible reasons behind the lack of a noticeable effect of hsp22 over-expression on the TMF are discussed. The detrimental effect of tetracycline could be attributed to the decline in mitochondrial translation or a decline in the population of endogenous bacteria, which are known to exert positive effects on the development and function of Drosophila larvae. / Thesis (Master, Biology) -- Queen's University, 2007-10-01 14:24:15.801

Heat shock protein 22

Drosophila melanogaster

Larval locomotion

High temperature stress

Visual control of human gait during locomotor pointing

Popescu, Adrian

Unknown Date

No description available.

Adaptive locomotion

Intermittent vision

Head-free gaze

Visuomotor control

Task complexity

The Stomatin STO-6 is a Novel Regulator of the Caenorhabditis elegans Motor Circuit

Barbier, Louis Wei-Chun

15 November 2013

The ability to move is essential to an animal’s ability to interact with and respond to its changing environment. The nematode Caenorhabditis elegans is a commonly used organism in the study of the genetic and neural bases of behaviours, yet the mechanistic explanation for its ability to move in a smooth sinusoidal wave remains elusive. Here, I present studies of an uncharacterized gene, sto-6, encoding a stomatin protein that regulates C. elegans motor behaviour. I show that this gene plays a role in two unexplained and fundamental processes to C. elegans locomotion: wave initiation and wave propagation. Furthermore, I examine the genetic interaction between sto-6 and an innexin gene unc-7, providing support for the hypothesis that stomatins regulate gap junction proteins in C. elegans. Together, these studies push forward our understanding of the mechanistic basis of C. elegans locomotion, and open up avenues of further inquiry.

c. elegans

motor circuit

stomatin

locomotion

nervous system

0369

0307

0317

The Stomatin STO-6 is a Novel Regulator of the Caenorhabditis elegans Motor Circuit

Barbier, Louis Wei-Chun

15 November 2013

The ability to move is essential to an animal’s ability to interact with and respond to its changing environment. The nematode Caenorhabditis elegans is a commonly used organism in the study of the genetic and neural bases of behaviours, yet the mechanistic explanation for its ability to move in a smooth sinusoidal wave remains elusive. Here, I present studies of an uncharacterized gene, sto-6, encoding a stomatin protein that regulates C. elegans motor behaviour. I show that this gene plays a role in two unexplained and fundamental processes to C. elegans locomotion: wave initiation and wave propagation. Furthermore, I examine the genetic interaction between sto-6 and an innexin gene unc-7, providing support for the hypothesis that stomatins regulate gap junction proteins in C. elegans. Together, these studies push forward our understanding of the mechanistic basis of C. elegans locomotion, and open up avenues of further inquiry.

c. elegans

motor circuit

stomatin

locomotion

nervous system

0369

0307

0317

Adaptive parallelization of model-base head tracking

Schodl, Arno

January 1999

No description available.

Computer vision

Human locomotion Computer simulation

Parallel algorithms

The evolution of avian hindlimb conformation and locomotor function

Allen, Vivian Richard

January 2011

No description available.

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