Global ETD Search

11	Discrepancy between leg and capillary blood flow kinetics during knee extension exercise Schlup, Susanna J. January 1900 (has links) Master of Science / Department of Kinesiology / Thomas Barstow / Previously in our laboratory, capillary blood flow (QCAP) kinetics were found to be significantly slower than femoral artery (QFA) kinetics following the onset of knee extension exercise. If the increase in QCAP does not follow a similar time course to QFA, blood must be flowing into the leg but not to the working muscle. One possible explanation for this discrepancy is that blood flow also increases to the nonworking lower leg muscles. Purpose: To determine if cuffing below the knee alters the kinetics of QFA and QCAP during knee extension exercise, and provide insight into the potential mechanisms controlling the rapid increase in QFA. Methods: Subjects performed a ramp max test to determine the work rate at which gas exchange threshold (GET) occurred. At least four constant work rate trials in each condition were conducted at work rates eliciting ~80% GET. Trials were performed with and without below knee occlusion. Pulmonary gas exchange, near-infrared spectroscopy, QFA and mean arterial pressure (MAP) measurements were taken. Muscle oxygen uptake (VO2m) and deoxy[hemoglobin + myoglobin] were used to estimate QCAP. Conductance (C) was calculated (QFA/MAP) and the percent change from baseline at 60s into exercise was calculated to indicate a time course of change. Results: There was no significant difference between the uncuffed and cuffed conditions (P>0.05). The mean response times (MRT) of QFA were 18.7 ± 14.2s (uncuffed) and 24.6 ± 14.9s (cuffed). QCAP MRTs were 51.8 ± 23.4s (uncuffed) and 56.7 ± 23.2s (cuffed), which were not significantly different from the time constants (τ) of VO2m (39.7 ± 23.2s (uncuffed) and 46.3 ± 24.1s (cuffed)). However, the MRT of QFA was significantly faster (P<0.05) than the MRT of QCAP and τVO2m. τVO2m and MRT QCAP were significantly correlated. The QFA and C percent increase from baseline at 60s were significantly different from MAP but not from each other. Conclusion: Cuffing below the knee did not significantly change the kinetics of QFA, QCAP or VO2m. Estimated QCAP kinetics tracked VO2m following exercise onset, while changes in QFA appeared to be primarily driven by an increase in C, not an increase in MAP. Knee extension exercise Blood flow control Blood flow kinetics Kinesiology (0575) Physiology (0719)
12	The influence of oxygen delivery and oxygen utilization on the determinants of exercise tolerance Broxterman, Ryan M. January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / Thomas J. Barstow / The physiological mechanisms determining the tolerable duration of exercise dictate human physical accomplishments across all spectrums of life. Despite extensive study, these specific mechanisms, and their dependence on oxygen delivery and oxygen utilization, remain, a certain extent, undefined. The purpose of this dissertation was to test the overarching hypothesis that muscle contraction characteristics (i.e., intensity of contraction, muscle contraction-relaxation duty cycle, etc.) alter oxygen delivery and oxygen utilization, which directly influence the power-duration relationship and fatigue development, and therefore, exercise tolerance. To accomplish this, specific interventions of altered muscle contraction-relaxation duty cycle and blood flow occlusion were utilized. In the first investigation (Chapter 2), we utilized low and high muscle contraction-relaxation duty cycles to alter blood flow to the active skeletal muscle, demonstrating that critical power (CP) was reduced with the high muscle contraction-relaxation duty cycle due to a reduction in blood flow, while the curvature constant (W’) was not altered. The second investigation (Chapter 3) utilized blood flow occlusion to show that CP was reduced and W’ increased for blood flow occlusion exercise conditions compared to control blood flow exercise conditions. The final investigation (Chapter 4) utilized periods of blood flow occlusion during and post-exercise to reveal greater magnitudes of peripheral and central fatigue development during blood flow occlusion exercise compared to control blood flow exercise. Moreover, this investigation demonstrated that W’ was significantly related to the magnitude of fatigue development. Collectively, alterations in oxygen delivery and oxygen utilization via muscle contraction characteristics and blood flow occlusion directly influence CP and the magnitude of fatigue development. However, W’ does not appear to be influenced by manipulations in oxygen delivery and oxygen utilization, per se. Rather, W’ may be determined by the magnitude of fatigue accrued during exercise, which is dependent upon oxygen delivery and oxygen utilization. The novel findings of the investigations presented in this dissertation highlight important physiological mechanisms that determine exercise tolerance and demonstrate the need for interventions that improve oxygen delivery and oxygen utilization in specific populations, such as those with chronic heart failure or chronic obstructive pulmonary disease, to improve exercise tolerance. Critical power Fatigue Exercise tolerance Oxygen delivery Oxygen utilization Kinesiology (0575) Physiology (0719)
13	Oxygen delivery-utilization matching in skeletal muscle Hirai, Daniel Muller January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / David C. Poole / The overall aim of this dissertation is to better understand the mechanisms determining skeletal muscle oxygen delivery-utilization matching in health and disease. Emphasis is directed toward the role of nitric oxide (NO) bioavailability in modulating muscle microvascular oxygenation (PO2mv; the sole driving force for blood-myocyte oxygen flux) during transitions in metabolic demand. The first investigation of this dissertation (Chapter 2) demonstrates that alterations in NO bioavailability have a major impact on skeletal muscle PO2mv kinetics following both the onset and cessation of contractions. Specifically, increased NO levels (via the NO donor sodium nitroprusside; SNP) elevates whereas reduced NO levels (non-specific NOS inhibition with NG-nitro-L-arginine methyl ester; L-NAME) diminishes muscle PO2mv at the onset and during recovery from contractions in the spinotrapezius muscle of healthy young rats. Consistent with these results, inhibition of the neuronal NO synthase isoform (S-methyl-L-thiocitrulline; SMTC; Chapter 3) reveals alterations in NO-mediated regulation of skeletal muscle PO2mv with advanced age that likely contribute to exercise intolerance in this population. In Chapter 4 we observed that pronounced oxidative stress is implicated in these pathological responses seen in aged and diseased states. Transient elevations in the oxidant hydrogen peroxide to levels seen in the early stages of senescence and cardiovascular diseases promote detrimental effects on skeletal muscle contractile function (i.e., augmented oxygen cost of force production). Chapter 5 demonstrates that endurance exercise training improves skeletal muscle microvascular oxygenation (i.e., greater PO2mv and slower PO2mv kinetics) across the metabolic transient partly via enhanced NO-mediated function in healthy young individuals. These data carry important clinical implications given that exercise training may ameliorate NO-mediated function, muscle microvascular oxygenation deficits and consequently exercise intolerance in aged and diseased populations. In conclusion, alterations in NO bioavailability have a major impact on the dynamic balance between skeletal muscle oxygen delivery and utilization (i.e., PO2mv kinetics) in health and disease. While advanced age or the predations of disease impair considerably skeletal muscle microvascular oxygenation, exercise training-induced adaptations on the oxygen transport system constitute a non-pharmacological therapeutic intervention potentially capable of mitigating these microcirculatory deficits. Exercise Physiology Nitric oxide Microcirculation Biology, Animal Physiology (0433) Health Sciences (0566) Physiology (0719)
14	Transforming growth factor beta 1 modulates electrophysiological parameters of vas deferens epithelial cells Yi, Sheng January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / Bruce Schultz / Transforming growth factor β1 (TGF-β1) is a cytokine that reportedly affects the severity of cystic fibrosis lung disease. The goal of this project was to define the effect of TGF-β1 on vas deferens, an organ that is universally affected in male cystic fibrosis patients. In the first study, experiments were conducted using freshly isolated porcine vas deferens epithelial cells. Primary porcine vas deferens epithelial cells exposed to TGF-β1 exhibited a significantly reduced basal transepithelial electrical resistance (Rte). TGF-β1-induced reduction in Rte was prevented by SB431542, a TGF-β receptor I inhibitor, indicating that the effect of TGF-β1 requires the activation of TGF-β receptor I. Western blot and immunohistochemistry results showed the expression of TGF-β receptor I in native vas deferens epithelia, indicating that the impaired barrier function and anion secretion that were observed in cultured vas deferens cells can likely be observed in the native context. Immunohistochemical outcomes showed that TGF-β1 exposure led to loss of organization of tight junction proteins occludin and claudin-7. These outcomes suggest that TGF-β1 impairs the barrier integrity of epithelial cells lining the vas deferens. In a parallel study that employed PVD9902 cells that are derived from porcine vas deferens, TGF-β1 exposure significantly reduced anion secretion stimulated by forskolin, forskolin/IBMX, and 8-pCPT-cAMP, suggesting that TGF-β1 affects downstream targets of the cAMP signaling pathway. Real-time RT-PCR and western blot analysis showed that TGF-β1 exposure reduced both the mRNA and the protein abundance of cystic fibrosis transmembrane conductance regulator (CFTR). Pharmacological studies showed that the inhibitory effect of TGF-β1 on forskolin-stimulated anion secretion was abrogated by SB431542 and attenuated by SB203580, a p38 mitogen-activated protein kinase (MAPK) inhibitor. These outcomes suggest that TGF-β1, via the activation of TGF-β receptor I and p38 MAPK signaling, reduces CFTR expression, and thus impairs CFTR-mediated anion secretion. Outcomes from these studies suggest that, in epithelial cells lining the vas deferens, TGF-β1 exposure leads to an impaired physical barrier and/or reduced anion secretion, which is expected to modify the composition and the maintenance of the luminal environment and thus, is expected to reduce male fertility. TGF Cystic fibrosis Vas deferens epithelia Tight junction Ion transport P38 MAPK Physiology (0719)
15	Regulation of sodium transport across epithelia derived from human mammary gland Wang, Qian January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / Bruce D. Schultz / The first aim of this project is to define the cellular mechanisms that account for the low Na[superscript]+ concentration in human milk. MCF10A cells, which were derived from human mammary epithelium and grown on permeable supports, exhibit amiloride- and benzamil-sensitive short circuit current (I[subscript]sc), suggesting activity of the epithelial Na[superscript]+ channel, ENaC. When cultured in the presence of cholera toxin (Ctx), MCF10A cells exhibit greater amiloride sensitive I[subscript]sc at all time points tested, an effect that is not reduced with Ctx washout for 12 hours or by cytosolic pathways inhibitors. Ctx increases the abundance of both beta and gamma-ENaC in the apical membrane and increases its monoubiquitination but without changing total protein and mRNA levels. Additionally, Ctx increases the levels of both the phosphorylated and the nonphosphorylated forms of Nedd4-2, a ubiquitin-protein ligase that regulates ENaC degradation. The results reveal a novel mechanism in human mammary gland epithelia by which Ctx regulates ENaC-mediated Na[superscript]+ transport. The second project aim is to develop a protocol to isolate mammary gland epithelia for subsequent in vitro culture. Caprine (1[superscript]0CME) and bovine mammary epithelia (1[superscript]0BME) were isolated and cultured on permeable supports to study hormone- and neurotransmitter-sensitive ion transport. Both 1[superscript]0CME and 1[superscript]0BME cells were passed for multiple subcultures and all passages formed electrically tight barriers. 1[superscript]0CME were cultured in the presence of hydrocortisone and exhibited high electrical resistance and amiloride-sensitive I[subscript]sc, suggesting the presence of ENaC-mediated Na[superscript]+ transport. 1[superscript]0BME were grown in a complex media in the presence or absence of dexamethasone. In contrast to 1[superscript]0CME, 1[superscript]0BME exhibited no detectable amiloride-sensitive I[subscript]sc in either culture condition. However, 1[superscript]0BME monolayers responded to an adrenergic agonist, norepinephrine, and a cholinergic agonist, carbamylcholine, with rapid increases in I[subscript]sc. Thus, this protocol for isolation and primary cell culture can be used for future studies that focus on mammary epithelial cell regulation and functions. In conclusion, the results from these projects demonstrate that mammary epithelial cells form electrically tight monolayers and can exhibit neurotransmitter- and/or hormone-induced net ion transport. The mechanisms that regulate Na[superscript]+ transport across mammary gland may provide clues to prevent or treat mastitis. Epithelial sodium channel (ENaC) Sodium transport Mamamry epithelia Cholera toxin Short circuit current Isc Physiology (0719)
16	Effects of nitrite infusion on skeletal muscle vascular control during exercise in rats with chronic heart failure Glean, Angela A. January 1900 (has links) Master of Science / Department of Kinesiology / Timothy I. Musch / Chronic heart failure (CHF) reduces nitric oxide (NO) bioavailability and impairs skeletal muscle vascular control during exercise. Reduction of nitrite (NO[subscript]2-) to NO may impact exercise-induced hyperemia particularly in muscles with pathologically-reduced O[subscript]2 delivery. We tested the hypothesis that NO[subscript]2- infusion would increase exercising skeletal muscle blood flow (BF) and vascular conductance (VC) in CHF rats with a preferential effect in muscles composed primarily of type IIb+IId/x fibers. CHF (coronary artery ligation) was induced in adult male, Sprague-Dawley rats. Following a >21 day recovery, mean arterial pressure (MAP, carotid artery catheter) and skeletal muscle BF (radiolabelled microspheres) were measured during treadmill exercise (20 m•min[superscript]-1, 5% incline) with and without NO[subscript]2- infusion. The myocardial infarct size (35 ± 3%) indicated moderate CHF. NO[subscript]2- infusion increased total hindlimb skeletal muscle VC (CHF: 0.85 ± 0.09, CHF+NO[subscript]2-: 0.93 ± 0.09 ml•min[superscript]-1•100g[superscript]-1•mmHg[superscript]-1, p<0.05) without changing MAP (CHF: 123 ± 4 mmHg, CHF+NO[subscript]2-: 120 ± 4 mmHg, p=0.17). Total hindlimb skeletal muscle BF was not significantly different (CHF: 102 ± 7, CHF+NO[subscript]2-: 109 ± 7 ml•min[superscript]-1•100g[superscript]-1, p>0.05). BF increased in 6 (~21%) and VC in 8 (~29%) of the 28 individual muscles and muscle parts. Muscles and muscle portions exhibiting greater BF and VC following NO[subscript]2- infusion were comprised of ≥63% type IIb+IId/x muscle fibers. These data demonstrate that NO[subscript]2- infusion can augment skeletal muscle vascular control during exercise in CHF rats. Given the targeted effects shown herein, a NO[subscript]2[superscript]--based therapy may provide an attractive “needs-based” approach for treatment of the vascular dysfunction in CHF. Heart failure Nitrite Exercise Muscle Blood flow Nitric oxide Kinesiology (0575) Medicine (0564) Physiology (0719)
17	Vascular ATP-sensitive potassium channels impact spatial and temporal oxygen transport: implications for sulphonylurea therapy Holdsworth, Clark Thomas January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / Timothy I. Musch / Matching local muscle O[subscript]2-supply to O[subscript]2-demand during the prodigious exercise-induced metabolic challenge is achieved through coordinated mechanisms of vascular control. The unique sensitivity of ATP-sensitive potassium (K[subscript]ATP) channels to cell metabolism indicates the potential to match energetic demand to peripheral O[subscript]2 transport. The aim of this dissertation was to determine the magnitude and kinetics of the K[subscript]ATP channel contribution to vascular control during exercise in health and heart failure. It was hypothesized that K[subscript]ATP channel inhibition via glibenclamide would, in healthy rats, 1) reduce exercising skeletal muscle blood flow and vascular conductance 2) speed the fall of microvascular O[subscript]2 driving pressure (PO[subscript]2mv; set by the O[subscript]2 delivery-O[subscript]2 utilization ratio) during muscle contractions and 3) in heart failure rats, augment the PO[subscript]2mv undershoot and delay the time to reach the contracting steady-state. A total of 55 male Sprague-Dawley rats were used under control and glibenclamide conditions (5 mg kg[superscript]-1). Hindlimb muscle blood flow (radiolabelled microspheres) was determined at rest (n = 6) or during treadmill exercise (n = 6-8; 20, 40 and 60 m min[superscript]-1, 5% incline). Spinotrapezius muscle PO[subscript]2mv (phosphorescence quenching) was measured in 16 heart failure (coronary artery ligation) and 12 healthy rats and during 180 s of 1-Hz twitch contractions (~6 V). The major effects of glibenclamide were, in healthy rats, 1) a reduction in exercising hindlimb skeletal muscle blood flow with the greatest effect in predominantly oxidative muscle fiber types and at higher running speeds 2) an increased prevalence of the undershoot of PO[subscript]2mv steady-state and doubled time to reach the steady-state and 3) in heart failure rats, a reduced baseline PO[subscript]2mv, an augmented undershoot of the steady-state and time to reach steady-state and a reduction in the mean PO[subscript]2mv during contractions. These data suggest that the K[subscript]ATP channel contributes substantially to exercise-induced hyperemia and may contribute to the slowing of VO[subscript]2 kinetics given the spatial and temporal effects of glibenclamide. The K[subscript]ATP channel-mediated protection against a severe O[subscript]2-delivery to O[subscript]2-utilization mismatch at the onset of contractions raises serious concerns for sulphonylurea treatment in diabetes which is likely to cause perturbations of [metabolite] and compromise exercise tolerance. Vascular control Microcirculation Exercise Heart failure Skeletal muscle Vasodilation Kinesiology (0575) Pharmacology (0419) Physiology (0719)
18	Derangements of tonicity and implications for veterinary patients Reinhart, Jennifer M. January 1900 (has links) Master of Science / Department of Clinical Sciences / Thomas Schermerhorn / Tonicity is property of a solution that is defined as the total effective (impermeable) osmole concentration that drives fluid movement across a semipermeable membrane via osmosis. Tonicity is related to but distinct from solution osmolality, which is a summation of all solute concentrations, regardless of the solute membrane permeability. In the mammalian body, tonicity is tightly regulated at both a cellular and systemic level; tonic derangements cause rapid change in cell and tissue volume leading to significant dysfunction. Input from the central nervous, circulatory, endocrine, gastrointestinal, and urinary systems are integral to osmoregulation, so many diseases in veterinary medicine are associated with tonicity disorders. However, because the homeostatic mechanisms that control tonicity overlap with those regulating electrolyte and acid-base balance as well as hydration and vascular volume, tonic consequences of disease can be difficult to isolate. Understanding of disease-associated changes in tonicity is further complicated by the fact that the tonic contributions of many solutes that accumulate in disease are unknown. Additionally, direct assessment of tonicity is difficult because tonicity is not just a physiochemical property, but it implies a physiologic effect. Thus, simple summation of osmole concentrations is an inadequate measurement of tonicity. The following report includes three studies investigating various aspects of tonicity as it applies to veterinary patients. Chapter 2 reports a study that examines the tonic effects of ketoacids and lactate using two different in vitro red blood cell assays. Results demonstrated that the ketoacids, beta-hydroxybutyrate and acetoacetate, behave as ineffective osmoles while the tonic behavior of lactate is variable, implying a more complex cellular handling of this anion. Two additional studies examine whether the mean corpuscular volume difference (dMCV) is a novel clinical marker for hypertonicity in dogs. Results of separate retrospective (Chapter 3) and prospective (Chapter 4) studies provide evidence that dMCV is a useful clinical marker for hypertonicity in dogs. Osmolality Red blood cells Sodium Diabetes mellitus Dog Metabolism Health Education (0680) Health Sciences (0566) Physiology (0719) Veterinary Medicine (0778)

Search results