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Society Symposium (society + symposium)

Distribution by Scientific Domains
Life Sciences62%

Selected Abstracts

Physiological Society Symposium , the Athlete's Heart

EXPERIMENTAL PHYSIOLOGY, Issue 5 2003
Equine athletes, racing success, the equine athlete's heart
Our recent data have confirmed that maximum oxygen delivery in racing Thoroughbreds is positively correlated to left ventricular mass measured by echocardiography. A similar, but weaker relationship also exists between left ventricular mass and Timeform performance rating in commercial racehorses. The relationship of the Thoroughbred heart to racing success and the special problems that selective breeding for aerobic capacity have had in this species are reviewed in this article. [source]

Physiological Society Symposium , the Athlete's Heart

EXPERIMENTAL PHYSIOLOGY, Issue 5 2003
Athlete's heart, effect of age, ethnicity, sporting discipline
Regular physical training is associated with several physiological and biochemical adaptations which enable an increase in cardiac output and widening of the systemic arterio-venous oxygen difference. An increase in cardiac chamber size is fundamental to the generation of a sustained increase in cardiac output for prolonged periods. Echocardiographic studies have shown that the vast majority of athletes have modest cardiac enlargement although a small proportion exhibit substantial increases in heart size. Recognised determinants of cardiac size include age, sex, ethnicity and type of sport. Cardiac dimensions vary considerably amongst athletes, even when allowances are made for these variables, suggesting that genetic, endocrine and biochemical factors also influence heart size. This review discusses the effects of age, sex, ethnicity and sporting discipline on cardiac dimensions in athletic individuals. [source]

Physiological Society Symposium , Vagal Control: From Axolotl to Man

EXPERIMENTAL PHYSIOLOGY, Issue 6 2001
Stuart Egginton
No abstract is available for this article. [source]

Physiological Society Symposium , Vagal Control: From Axolotl to Man

EXPERIMENTAL PHYSIOLOGY, Issue 6 2001
The neuranatomical basis of central control of cardiorespiratory interactions in vertebrates
First page of article [source]

Facilitation in the conceptual melting pot

JOURNAL OF ECOLOGY, Issue 6 2009
Rob W. Brooker
Summary 1. Here we present an introduction to this issue's Special Feature arising from the British Ecological Society Symposium: Facilitation in Plant Communities (20,22 April 2009). 2. Papers in the Special Feature demonstrate the benefits that arise from cross-system application of general concepts, for example, the well-known stress gradient hypothesis. Such comparisons challenge our definition of facilitation, as well as our pre-conceptions on the nature of intermediary organisms. 3. We suggest that under some circumstances a clear definition of the two-way nature of interactions is essential, e.g. when considering the evolutionary implications of facilitation. In other cases, however, we can perhaps be more relaxed, e.g. when facilitation is a component of conservation ecology. 4.Synthesis. Overall we believe that establishing facilitation as an independent concept has driven substantial progress towards a clearer understanding of how ecological systems work. Through the links established by work such as that presented in this Special Feature, we believe this field will continue to make rapid progress and aid ecological understanding in general. [source]

Proceedings of the Australian Physiological and Pharmacological Society Symposium: New Frontiers in Muscle Research Gene transfer: manipulating and monitoring function in cells and tissues

CLINICAL AND EXPERIMENTAL PHARMACOLOGY AND PHYSIOLOGY, Issue 8 2001
Rekha G Panchal
SUMMARY 1. The ectopic expression of genes has proven to be an extremely valuable tool for biologists. The most widely used systems involve electrically or chemically mediated transfer of genes to immortalized cell lines and, at the other end of the spectrum, transgenic animal models. As would be expected, there are compromises to be made when using either of these broad approaches. Immortalized cell lines have limited ,physiological relevance' and transgenic approaches are costly and out of the reach of many laboratories. There is also significant time required for the de novo generation of a transgenic animal. 2. As a viable alternative to these approaches, we describe the use of recombinant adenovirus and Sindbis virus to deliver genes to cells and tissues. 3. We exemplify this approach with studies from our laboratories: (i) an investigation of Ca2+ handling deficits in cardiac myocytes of hypertrophied hearts using infection with recombinant adenovirus encoding either green fluorescent protein (GFP) or the sarcoplasmic/endoplasmic reticulum calcium-ATPase (Serca2a); (ii) a study of the mechanism of macrophage/microglial migration by infection of embryonic phagocytes with a GFP-encoding virus and coculture with brain slices to then track the movement of labelled cells; and (iii) we are also exploiting the natural tropism of the Sindbis virus to label neurons in hippocampal brain slices in culture to resolve high-resolution structure and to map neuronal connectivity. 4. Further development of these approaches should open new avenues of investigation for the study of physiology in a range of cells and tissues. [source]

Proceedings of the Australian Physiological and Pharmacological Society Symposium: New Frontiers in Muscle Research Hybrid skeletal muscle fibres: a rare or common phenomenon?

CLINICAL AND EXPERIMENTAL PHARMACOLOGY AND PHYSIOLOGY, Issue 8 2001
Gabriela MM Stephenson
SUMMARY 1. The main aim of the present review is to raise awareness of the molecular complexity of single skeletal muscle fibres from ,normal' and ,transforming' muscles, in recognition of the many types of hybrids that have been observed in vertebrate skeletal muscle. The data used to illustrate various points made in the review were taken from studies on mammalian (mostly rat) and amphibian muscles. 2. The review provides a brief overview of the pattern and extent of molecular heterogeneity in hybrid muscle fibres and of the methodological problems encountered when attempting to identify and characterize such fibres. Particular attention is given to four types of skeletal muscle hybrids: (i) myosin heavy chain (MHC) hybrids; (ii) mismatched MHC,myosin light chains (MLC) hybrids; (iii) mismatched MHC,regulatory protein hybrids; and (iv) hybrids containing mismatched MHC,sarcoplasmic reticulum protein isoforms. 3. Some of the current ideas regarding the functional significance, origin and cognitive value of hybrid fibres are examined critically. [source]

Proceedings of the Australian Physiological and Pharmacological Society Symposium: The Hypothalamus HYPOTHALAMIC PARAVENTRICULAR NUCLEUS AND CARDIOVASCULAR REGULATION

CLINICAL AND EXPERIMENTAL PHARMACOLOGY AND PHYSIOLOGY, Issue 1-2 2001
Emilio BadoerArticle first published online: 10 DEC 200
SUMMARY 1. The hypothalamic paraventricular nucleus (PVN) is an important integrative site within the brain composed of magnocellular and parvocellular neurons. It is known to influence sympathetic nerve activity. 2. The parvocellular PVN contains neurons that project to the intermediolateral cell column of the thoraco,lumbar spinal cord (IML). This defines the PVN as an autonomic ,premotor nucleus', one of only five present within the brain. 3. Another projection arising from the PVN is a prominent innervation of the pressor region of the rostral ventrolateral medulla (RVLM), also a premotor nucleus. The distribution of the PVN neurons projecting to the RVLM is similar to that of the PVN neurons that project to the IML. 4. It has been found that up to 30% of spinally projecting neurons in the PVN also send collaterals to the RVLM. Thus, there are neurons in the PVN that can: (i) directly influence sympathetic nerve activity (via PVN,IML connections); (ii) indirectly influence sympathetic nerve activity (via PVN,RVLM connections); and (iii) both directly and indirectly influence sympathetic nerve activity (via neurons with collaterals to the IML and RVLM). 5. In the rat, results of studies using the protein Fos to identify activated neurons in the brain suggest that neurons in the PVN with projections to the IML or RVLM may be activated by decreases in blood volume. 6. In conclusion, the PVN can influence sympathetic nerve activity. Within the PVN are neurons with anatomical connections that enable them to affect sympathetic nerve activity either directly, indirectly or via both mechanisms (via collaterals). Studies that have examined the role of specific subgroups within the PVN suggest that PVN neurons with connections to the IML or to the RVLM may play a role in the reflex changes in sympathetic nerve activity that are involved in blood volume regulation. [source]