Global ETD Search

21	THE EFFECTS OF EXERCISE PRECONDITIONING ON FOCAL ISCHEMIC STROKE Grohs, Gillian 01 January 2017 (has links) Cleaved fragments of the extracellular matrix protein perlecan have been shown to promote neuroprotection and repair after ischemic stroke. The cysteine proteases cathepsin B and L as well as the metalloprotease bone morphogenic protein 1 (BMP-1) are capable of releasing the biologically active C-terminal laminin-like globular domain (LG3) of perlecan. Exercise, a known method of reducing stroke risk and severity, has been shown to increase the expression of some proteases associated with perlecan processing. Using a transient distal middle cerebral artery occlusion (MCAo) model for focal ischemic stroke we show that while 7 days of running only slightly decreased infarct volume, BMP1 and perlecan (HSPG2) RNA expression in skeletal muscle was significantly increased in 3-month-old male wild type C57/BL6 mice. Moreover, elevated levels of BMP1 RNA were still detectable after 3 days of detraining, suggesting a prolonged effect of exercise on BMP1 expression. Levels of LG3 in the blood were below the limit of detection in the current study, however it is likely that a more sensitive method would enable analysis of serum. These preliminary findings suggest that LG3 could be a molecular mediator of neuroprotection afforded by exercise though further studies are required. Ischemic Stroke Exercise Preconditioning Neurovascular Unit Perlecan Laminin-like Globular Domain 3 Skeletal Muscle Neurosciences Physiological Processes
22	Signaling Components Involved in the Hormone Induced Translocation of ENaC in Cultured Adult Human Fungiform (HBO) Taste Cells Hojati, Deanna 01 January 2017 (has links) The amiloride-sensitive epithelial Na+ channel, ENaC, is the Na+-specific salt taste receptor in rodents. Compared to rodents, human salt taste perception is amiloride-insensitive. In rodents the ENaC is composed of aβg-subunits. Whereas humans express an additional subunit, the d-ENaC subunit. ENaC in human taste cells is composed of aβg-subunits or dβg-subunits, with the latter being amiloride-insensitive. Currently, it is not known if dβg-ENaC expression and trafficking is regulated by hormones and their downstream intracellular signaling effectors. The aim of this study is to investigate if arginine vasopressin (AVP), aldosterone, and cAMP regulate d-ENaC expression and trafficking in cultured fungiform human taste cells (HBO cells). Secondly, we want to demonstrate the expression of downstream signaling effectors involved in the trafficking of d-ENaC in HBO cells. Using molecular and immunocytochemical techniques, our results demonstrate that AVP, cAMP, and aldosterone increase expression of d-ENaC mRNA and protein in HBO cells. Furthermore, AVP, cAMP and aldosterone increased trafficking of the d-ENaC subunit from the cytosolic compartment to the apical pole of the HBO cells. Our results further demonstrate that HBO cells express several components of signaling cascade involved in ENaC translocation from cytosol to apical pole in HBO cells. The components of this signaling cascade include AVPR2, PKA, CREB, SGK-1, Nedd4-2, and GILZ-1. These hormones in mice and rats upregulate ENaC. Currently, we are not sure if these hormones affect ENaC this way in humans. By studying d-ENaC with these hormones, we are able to see how human ENaC is regulated in the tongue. delta ENaC HBO cells taste salt ENaC epithelial sodium channel fungiform Digestive, Oral, and Skin Physiology Physiological Processes
23	Using Light to Observe and Control Cellular Function: Improving Bioluminescence Imaging and Photocontrol of Rho GTPase Activation States: A Dissertation Harwood, Katryn R. 30 September 2011 (has links) The dynamic processes that occur at specific times and locations in cells and/or whole organisms during cellular division, migration, morphogenesis and development are critical. When these molecular events are not properly regulated, disease states can develop. Tools that can allow us to better understand the specific events that, when misregulated, result in disease development can also allow us to determine better ways to combat such misregulation. Specifically, tools that could allow us to better visualize cellular processes or those that allow us to control cellular functioning in a spatiotemporal manner could present great insight into the detailed inner workings of cells and/or whole organisms. Where chemistry and biology intersect presents a powerful starting point for the development of such tools. The first half of this thesis addresses tools to allow the better visualization of cellular events, in particular the intriguing process of bioluminescence and the work that has been done to better understand and optimize its utilization, particularly in living organisms. The novel work presented here details a parallel approach to improve our ability to observe cellular functioning specifically by improving bioluminescence imaging through the generation and characterization of mutant luciferase proteins that can better utilize novel small molecule luciferin substrates. The second half of this thesis discusses methods that have been developed to better control cellular events through the control of protein activity, specifically a family of proteins called the Rho GTPases. This family’s activation at specific times and locations is essential to proper cellular function and exemplifies the need for spatiotemporal control. Described are methods to control the activation states of the Rho GTPases to probe their cellular roles in a temporal and spatial manner using photosensitive small molecules. Taken together, the findings described herein demonstrate the application of chemistry to allow for the better observation and control of cellular processes, toward the ultimate goal of improving our understanding of the regulatory processes involved in the control of key factors leading to disease states. Cell Physiological Processes rho GTP-Binding Proteins Luminescent Measurements Amino Acids, Peptides, and Proteins Cells Cellular and Molecular Physiology
24	Comparison of Two Different Sprint Interval Training Work-to-Rest Ratios on Acute Metabolic and Inflammatory Responses HARNISH, CHRISTOPHER R 01 January 2014 (has links) High intensity exercise is believed to yield greater results on health and human performance than moderate intensity exercise. Extensive research indicates that not only do high-intensity interval training (HIT) and sprint interval training (SIT) produce significant improvements in cardiovascular fitness and disease, they may be more effective at improving long-term metabolic function, including insulin sensitivity (Si), by producing more mitochondria. Moreover, compliance rates for HIT and SIT participation are reported to be the same or better than traditional moderate intensity exercise. Because lack of time is often cited as major hindrance to exercise participation, SIT is also seen as a time efficient option to improve health and performance. It does appear, however, that repeated sessions of SIT are needed before overall improvements can be measured. SIT protocols employing maximal 30 sec sprints with ~5 min rest [a 1:9 work-to-rest ratio (W:R)], have garnered much of the research focus, while those using minimal rest periods, like Tabata which uses 20 sec sprints and 10 sec rest (2:1 W:R), have been ignored. This may omit a possible SIT option that could influence acute and chronic adaptations. The role of inflammatory cytokines on Si remains an area of continued research. While endurance exercise is thought to create an overall anti-inflammatory environment that stimulates improvement in Si, SIT is often viewed as pro-inflammatory. However, few studies have provided significant insight into cytokine release following SIT, and none haveexplored its impact on Si. In addition, the impact of W:R on cytokine remains speculative at best. Therefore, the examination of the effect of different sprint protocols of similar total work (kJ) on performance, metabolic function, and inflammatory response may provide valuable insight into these adaptive processes. SIT Cytokines Myokines Insulin Sensitivity Wingate Tabata OGTT Cardiovascular Diseases Cellular and Molecular Physiology Exercise Physiology Exercise Science Kinesiology Medical Immunology Medical Physiology Physiological Processes Sports Sciences
25	Dysregulation of microRNAs in Blood as Biomarkers for Diagnosing Prostate Cancer Daniel, Rhonda W. 01 January 2015 (has links) Prostate cancer is the most common noncutaneous cancer among men, yet current diagnostic methods are insufficient and more reliable diagnostic markers need to be developed. The answer that can bridge this gap and enable more efficient diagnoses may lie in microRNAs. These small, single stranded RNA molecules impact protein expression at the translational level and regulate important cellular pathways. Dysregulation of these small RNA molecules can have tumorigenic effects on cells and lead to many types of cancers. Currently the Prostate-Stimulating Antigen (PSA) is used as a diagnostic marker for prostate cancer. However, many factors can elevate PSA levels such as infections and certain medications, consequently leading to false positive diagnoses and unnecessary concern and over treatment with dire outcomes for the patient. Even worse, are the chances of false negative diagnoses, which result in prostate cancer not being diagnosed until its later stages. Therefore, although the use of the PSA level has had its uses in the clinic, it has failed to sufficiently bridge the gap or to distinguish indolent from aggressive disease. It has long been suggested in the literature that microRNAs are drastically altered throughout the course of cancer progression. Here, RNA sequencing was used to identify changes in miR expression profiles diagnostic for prostate cancer patients compared to non-patient controls. The RNA sequencing results were also used to identify normalization miRs to be used as endogenous controls. Confirmatory qRT-PCR was then used to corroborate these results for the top seven dysregulated miRs found from the RNA sequencing data. Data analysis of the Area Under the Curve (AUC) of the Receiver Operating Curves (ROC) of the selected miRs exhibited a better correlation with prostate cancer (AUC Range= 0.819- 0.950) than PSA (AUC of PSA=0.667). In summary, a panel of seven miRs are proposed, many of which have prostate specific targets, which would represent a significant improvement over current testing methods. PSA Prostate Cancer microRNAs biomarkers RNA sequencing Biochemistry Bioinformatics Circulatory and Respiratory Physiology Diagnosis Diseases Male Urogenital Diseases Molecular Biology Physiological Processes Therapeutics
26	Mild Traumatic Brain Injury and Associated Effects on the Auditory System Schairer, Kim S. 01 January 2012 (has links) No description available. mild TBI traumatic brain injury auditory system effects audiology Audiology and Speech-Language Pathology Medical Neurobiology Physiological Processes Speech and Hearing Science Speech Pathology and Audiology
27	EEG Study of Effortful Listening Ryan, David B., Eckert, Mark A., Sellers, Eric W., Schairer, Kim S., Smith, Sherri L. 05 November 2017 (has links) Adults with hearing loss typically experience difficulty understanding speech and report increased mental effort or listening effort (Pichora-Fuller et al. 2016). Over time, or in difficult listening conditions, listening effort can cause stress and mental fatigue, contributing to negative psychosocial consequences (e.g., social withdrawal) or limited/discontinued hearing-aid use (Eckert, et al., 2016; Pichora-Fuller, 2007). Additionally, the amount of listening effort required to recognize speech varies by individual and by listening condition (Pichora-Fuller, Kramer, Eckert, et al., 2016). Therefore, having a way to measure and account for listening effort in individual hearing aid fittings and aural rehabilitation plans may improve satisfaction and eventual hearing aid retention in those with hearing loss. Few objective measures are available to reliably predict listening effort in real world environments and many effort-related measures do not consider the specific neural systems that underlie listening effort (Zekveld et al., 2010; Smith et al. 2016; McMahon et al. 2016). The purpose of this study is to evaluate an electroencephalogram (EEG)-based method for quantifying listening effort based on the power of the cortical EEG response. Spectral power estimates within different EEG frequency domains that represent the activity of attention-related neural systems were calculated and included: (1) low-frequency alpha (8-10 Hz; LFA) power that has been associated with increased working memory task demands (Klimesch, 1999); (2) high-frequency alpha (10-13 Hz; HFA) power that has been associated with semantic memory and cognitive demands (Klimesch, 1999); and (3) theta (4-7 Hz) power that has been associated with encoding information (Klimesch, 1999) and increased listening effort (Wisniewski et al., 2015). The EEG data was collected during administration of the Words-In-Noise test (WIN; Wilson et al., 2003) and the Word Auditory Recognition and Recall Measure (WARRM; Smith et al., 2016) that induce listening effort due to low signal-to-noise ratio and due to auditory working memory demand, respectively. The results of correlations among EEG power in the three frequency ranges, WIN performance, WAARM performance, and self-report measures of listening effort will be presented. These results will be supported by independent component source analysis of EEG frequencies for regions of interest predicted to contribute to listening effort, including the frontal midline, auditory cortex, and parietal lobe. The EEG measures are expected to collectively explain task performance and self-reported listening effort. EGG cognitive systems effortful listening audiology Audiology and Speech-Language Pathology Physiological Processes Speech and Hearing Science Speech Pathology and Audiology
28	DEVELOPMENT AND VALIDATION OF A SEMI-PHYSIOLOGICAL PHARMACOKINETIC (PBPK) MODEL TO PREDICT SYSTEMIC AND PULMONARY EXPOSURES AFTER INTRAVENOUS, ORAL ADMINISTRATION AND PULMONARY INHALATION OF SELECTED DRUGS, BUDESONIDE, TOBRAMYCIN AND CIPROFLOXACIN, IN HUMANS Hanna, Bishoy 01 January 2018 (has links) Using a semi-PBPK modeling/quantitative meta-analysis approach, this project investigated what factors affect pulmonary and systemic exposures of Budesonide (BUD), Tobramycin (TOB), and Ciprofloxacin (CIP) after inhalation: Three structurally different pulmonary disposition models were developed for each drug, including pulmonary absorption (all three), excretion (TOB and CIP) and sequestration (TOB) in a peripheral and central lung compartment. Systemic disposition parameters were estimated using available human mean plasma (cp(t)) and sputum (cs(t)) concentration profiles after IV administration, and GI absorption parameters were estimated from these profiles after oral administration. Pulmonary disposition parameters were estimated from cp(t) and cs(t) profiles after inhalation using various devices along with their published pulmonary deposition characteristics. Appropriate covariate models accounted for effects of Cystic Fibrosis on the systemic disposition/GI absorption for TOB and CIP. Monte Carlo Simulations (MCS) were used to optimize parameters and validate the final models and parameter spaces against published data. Despite limited available data, especially cs(t) for BUD and CIP (after IV administration), the point estimates for the final model parameters were mechanistically plausible for all three drugs and consistent with their known differences in physicochemical and ADME properties. Model predictions adequately described the observed cp(t) and cs(t) profiles as well as exposure metrics across studies. As the most lipophilic drug, BUD showed the fastest pulmonary absorption rates and highest Fpul (83%). TOB, a very hydrophilic drug, exhibited (intracellular) pulmonary sequestration, resulting in slow pulmonary absorption and excretion and low Fpul (10%). CIP - as zwitterion - showed relatively slow pulmonary absorption and excretion, leading to low Fpul (8%); pulmonary excretion accounted for 27% of CIP overall elimination. Results of a formal parameter sensitivity analysis demonstrated that, for all three drugs, after inhalation, (1) their systemic exposures (cp(t)) depend primarily on CLtot along with Fpul/sequestration combined with Foral; (2) increasing pulmonary exposures (cs(t)) can be accomplished by slowing down pulmonary absorption rates (kca) and/or slowing down mucociliary clearance from the lungs into the GI tract (kcm) – affirming the overall hypothesis guiding the project. TOBRAMYCIN CIPROFLOXACIN BUDESONIDE MODELING SIMULATION PHARMACOKINETIC Medical Pharmacology Medical Sciences Pharmaceutics and Drug Design Pharmacy and Pharmaceutical Sciences Physiological Processes
29	Pharmacodynamics of Monoamine Transporter Releasing Agents and Reuptake Inhibitors Holloway, Alexa 01 January 2019 (has links) Ligands of the human monoamine transporters encompass a wide range of both illicit and therapeutic drugs that act upon neural circuitry related to reward, motivation, and the processing of salient stimuli. The present study utilizes two methods for analyzing transporter substrates and inhibitors in order to characterize activity and assess potency. The first measures transient changes in intracellular calcium as a surrogate for transporter activity by harnessing the electrical coupling of monoamine transporters and L-type calcium channels. This is used to analyze novel chimera of the strong hDAT inhibitors methylphenidate and 𝛼-PPP in order to assess the contribution of specific moieties to potency. The observed reduction in potency suggests that methylphenidate may bind to the transporter in a manner distinct from 𝛼-PPP, as chimera would otherwise be expected to show similar activity to parent compounds. These results highlight the importance of 𝛼-carbon substituents and the relatively small contribution of beta-carbon groups to inhibitor potency at hDAT, while the lack of activity at hSERT suggests potency is not strongly influenced by beta-carbon or N-alkyl substituents. In order to further characterize drug-transporter interaction, a method was developed to analyze the kinetics of binding and unbinding using both known and novel hNET ligands, including a series of N-alkyl derivatives of 4-methylamphetamine. The study emphasizes the importance of both association and dissociation kinetics to affinity and sets up a methodological framework with two ways for determining Kd, with notable advantages over current models. The results indicate that lengthening the N-alkyl chain of 4-methylamphetamine leads to a decrease in potency and a shift in activity from substrate to blocker, with the results of N-propyl 4-methylamphetamine in particular indicating the potential existence of multiple low-affinity binding sites, each with distinct on and off kinetics. The implications of these results help elucidate the mechanism of action of transporter ligands and set up a framework for future studies that can more specifically classify the interaction between transporters and inhibitors or releasing agents. human monoamine transporters kinetics potency methylphenidate N-alkyl 4-methylamphetamine potency Amino Acids, Peptides, and Proteins Biological and Chemical Physics Medical Biophysics Medical Physiology Other Chemicals and Drugs Physiological Processes
30	The Effectiveness of Resistance Exercises in the Management of Medial Tibial Stress Syndrome Bard, Amanda E 01 April 2013 (has links) Medial tibial stress syndrome (MTSS) is a stress and overuse injury that presents as pain on the medial aspect of the lower two-thirds of the tibia. It is most often caused by repetitive actions on hard surfaces such as running, marching, and dancing. Individuals most affected by MTSS are runners, members of the military, dancers, and athletes that play soccer, volleyball and basketball. While MTSS has a relatively standard presentation of pain on the medial aspect of the tibia, it can occasionally be mistaken for other injuries such as stress fractures or compartment syndrome. If a diagnosis is unsure, methods such as x-ray, bone-scan, and MRI can be utilized to better obtain the correct diagnosis. A variety of treatments exist for MTSS including, ice, massage, muscle strengthening, and rest. A combination of these various techniques is most often what is employed. In this study, the effectiveness of a set of resistance ankle exercises in combination with ice and massage was tested and compared to that of ice and massage alone. The hypothesis was that athletes receiving the exercises as part of their treatment, in addition to the icing and massaging, would have a greater decrease in pain from MTSS than athletes just receiving ice and massage as treatment. The exercises would strengthen the muscles of the lower leg that, when weak, can contribute to the development of MTSS. Results indicated that the exercises yielded a more significant decrease in pain from MTSS than ice and massage alone. medial tibial stress syndrome exercises treatment rehabilitation athletes running injuries Kinesiotherapy Medical Anatomy Medical Physiology Medical Sciences Musculoskeletal System Physical Therapy Physiological Processes

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