Catalogue Search | MBRL
Are you sure you want to remove the book from the shelf?
{{itemTitle}}
16,043
result(s) for
"Biomechanics physiology."
Sort by:
Biomechanics of Human Communication
The purpose of this book is to create a neurophysiology-based framework for assessing and improving mental health. It introduces measurable and neurobiologically-informed concepts and language to help professionals and organizations decrease stigma related to mental health and increase awareness of a new paradigm. This new, emerging paradigm moves away from previous language related to mental and psychological health, and moves towards language that focuses on promoting systems resilience and neurological adaptability through measurable neurophysiological mechanisms. It explores human communication patterns through the lens of neurophysiology, systems thinking, the Neurovisceral Integration Model, and attachment frameworks. This book will give people who are in helping professions - coaches, therapists, teachers, first responders - and leaders of all sorts - a new map and vocabulary for understanding mental health in terms of nervous system mechanisms for detecting and creating safety.
eBook
Variant and invariant patterns embedded in human locomotion through whole body kinematic coordination
Step length, cadence and joint flexion all increase in response to increases in gradient and walking speed. However, the tuning strategy leading to these changes has not been elucidated. One characteristic of joint variation that occurs during walking is the close relationship among the joints. This property reduces the number of degrees of freedom and seems to be a key issue in discussing the tuning strategy. This correlation has been analyzed for the lower limbs, but the relation between the trunk and lower body is generally ignored. Two questions about posture during walking are discussed in this paper: (1) whether there is a low-dimensional restriction that determines walking posture, which depends not just on the lower limbs but on the whole body, including the trunk and (2) whether some simple rules appear in different walking conditions. To investigate the correlation, singular value decomposition was applied to a measured walking pattern. This showed that the whole movement can be described by a closed loop on a two-dimensional plane in joint space. Furthermore, by investigating the effect of the walking condition on the decomposed patterns, the position and the tilt of the constraint plane was found to change significantly, while the loop pattern on the constraint plane was shown to be robust. This result indicates that humans select only certain kinematic characteristics for adapting to various walking conditions.
Journal Article
Frameworks of Movement Sciences
This article is composed of two parts. In the first part, a review is conducted on how research concerning human movement has been performed on Japanese subjects with newly developed methods in the last 60 years. In the second part, the frameworks of human movement sciences, such as exercise physiology, biomechanics, sports performance, and health, are proposed mainly based on the research results obtained by the author and his colleagues. It is expected that this article will be helpful to researchers in the fields of physical education, sports, and health.
Journal Article
Material Properties of Hagfish Skin, with Insights into Knotting Behaviors
Hagfishes (Myxinidae) often integrate whole-body knotting movements with jawless biting motions when reducing large marine carcasses to ingestible items. Adaptations for these behaviors include complex arrangements of axial muscles and flexible, elongate bodies without vertebrae. Between the axial muscles and the hagfish skin is a large, blood-filled subcutaneous sinus devoid of the intricate, myoseptal tendon networks characteristic of the taut skins of other fishes. We propose that the loose-fitting skin of the hagfish facilitates the formation and manipulation of body knots, even if it is of little functional significance to steady swimming. Hagfish skin is a relatively thick, anisotropic, multilayered composite material comprising a superficial, thin, and slimy epidermis, a middle dermal layer densely packed with fibrous tissues, and a deep subdermal layer comprised of adipose tissue. Hagfish skin is stiffer when pulled longitudinally than circumferentially. Stress-strain data from uniaxial tensile tests show that hagfish skins are comparable in tensile strength and stiffness to the taut skins of elongate fishes that do not engage in knotting behaviors (e.g., sea lamprey and penpoint gunnel). Sheath-core-constructed ropes, which serve as more accurate models for hagfish bodies, demonstrate that loose skin (extra sheathing) enhances flexibility of the body (rope). Along with a loose-fitting skin, the morphologies of hagfish skin parallel those of moray eels, which are also known for generating and manipulating figure-eight-style body knots when struggling with prey.
Journal Article
Variations in Copepod Proteome and Respiration Rate in Association with Diel Vertical Migration and Circadian Cycle
The diel vertical migration of zooplankton is a process during which individuals spend the night in surface waters and retreat to depth during the daytime, with substantial implications for carbon transport and the ecology of midwater ecosystems. The physiological consequences of this daily pattern have, however, been poorly studied beyond investigations of speed and the energetic cost of swimming. Many other processes are likely influenced, such as fuel use, energetic tradeoffs, underlying diel (circadian) rhythms, and antioxidant responses. Using a new reference transcriptome, proteomic analyses were applied to compare the physiological state of a migratory copepod, Pleuromamma xiphias, immediately after arriving to the surface at night and six hours later. Oxygen consumption was monitored semi-continuously to explore underlying cyclical patterns in metabolic rate under darkdark conditions. The proteomic analysis suggests a distinct shift in physiology that reflects migratory exertion and changes in metabolism. These proteomic analyses are supported by the respiration experiments, which show an underlying cycle in metabolic rate, with a peak at dawn. This project generates molecular tools (transcriptome and proteome) that will allow for more detailed understanding of the underlying physiological processes that influence and are influenced by diel vertical migration. Further, these studies suggest that P. xiphias is a tractable model for continuing investigations of circadian and diel vertical migration influences on plankton physiology. Previous studies did not account for this cyclic pattern of respiration and may therefore have unrepresented respiratory carbon fluxes from copepods by about 24%.
Journal Article
Particle Selection in Suspension-Feeding Bivalves
Suspension-feeding bivalves are known to discriminate among a complex mixture of particles present in their environments. The exact mechanism that allows bivalves to ingest some particles and reject others as pseudofeces has yet to be fully elucidated. Recent studies have shown that interactions between lectins found in the mucus covering oyster and mussel feeding organs and carbohydrates found on the microalga cell surface play a central role in this selection process. In this study, we evaluated whether these interactions are also involved in food selection in bivalves with other gill architectures, namely, the clam Mercenaria mercenaria and the scallop Argopecten irradians. Statistical methods were used to predict whether given microalgae would be rejected or ingested depending on their cell surface carbohydrate profiles. Eight different microalgae with previously established surface carbohydrate profiles were grown and harvested during their exponential growth phase to be used in feeding experiments. Microalgae were then used in 17 feeding experiments where different pairs of microalgae were presented to clams and scallops to evaluate selection. Decision trees that model selection were then developed for each bivalve. Results showed that microalgae rich in mannose residues were likely to beingested in both bivalves. N-acetylglucosamine and fucose residues also seem to play a role in food particle choice in scallops and clams, respectively. Overall, this study demonstrates the role of carbohydratelectin interactions in particle selection in suspension-feeding bivalves displaying different gill architectures, and it highlights the importance of mannose residues as a cue for the selection of ingested particles.
Journal Article
The Behavioral Ecology of Intermittent Locomotion1
Most physiological and ecological approaches to animal locomotion are based on steady state assumptions, yet movements of many animals are interspersed with pauses lasting from milliseconds to minutes. Thus, pauses, along with changes in the duration and speed of moves, form part of a dynamic system of intermittent locomotion by which animals adjust their locomotor behavior to changing circumstances. Intermittent locomotion occurs in a wide array of organisms from protozoans to mammals. It is found in aerial, aquatic and terrestrial locomotion and in many behavioral contexts including search and pursuit of prey, mate search, escape from predators, habitat assessment and general travel. In our survey, animals exhibiting intermittent locomotion paused on average nearly 50% of their locomotion time (range 6–94%). Although intermittent locomotion is usually expected to increase energetic costs as a result of additional expenditure for acceleration and deceleration, a variety of energetic benefits can arise when forward movement continues during pauses. Endurance also can be improved by partial recovery from fatigue during pauses. Perceptual benefits can arise because pauses increase the capacity of the sensory systems to detect relevant stimuli. Several processes, including velocity blur, relative motion detection, foveation, attention and interference between sensory systems are probably involved. In animals that do not pause, alternative mechanisms for stabilizing the perceptual field are often present. Because movement is an important cue for stimulus detection, pauses can also reduce unwanted detection by an organism's predators or prey. Several models have attempted to integrate energetic and perceptual processes, but many challenges remain. Future advances will require improved quantification of the effects of speed on perception.
Journal Article