Browsing by Subject "Cognitive Neuroscience"
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Item Activities of Daily Living and Cardiovascular Risk Factors' Impact on Cardiovascular Disease (CVD) and Cognitive Functioning: A Three Stage Longitudinal Model(2005-05-01) Bozo, Ozlem; Guarnaccia, Charles A.; Hall, James; Kelly, KimberlyBozo, Ozlem, Activities of Daily Living and Cardiovascular Risk Factors’ Impact on Cardiovascular Disease (CVD) and Cognitive Functioning: A Three Stage Longitudinal Model. Doctor of Philosophy (Health Psychology), May, 2005, 122 pp., 23 tables, 4 figures, references, 50 titles. The purpose of this study was to examine the longitudinal relationship of daily living (ADL), cardiovascular risk factors, and cardiovascular diseases to predict the future cognitive functioning of older Americans who are between the ages of 51 and 61 at the time of initial assessment. Three waves of the Health and Retirement Study (HRS) database between the years of 1992 and 2002 were examined with path analysis. The longitudinal hypotheses of the study were that (1) ADLs would positively predict future cognitive functioning, (2) ADLs would negatively predict future cardiovascular risk factors, (3) ADLS would negatively predict future cardiovascular diseases, (5) cardiovascular risk factors would negatively predict future cognitive functioning, (6) cardiovascular disease would negatively predict future cognitive functioning, (7) cardiovascular risk factors would mediate the relationship between ADLS and cardiovascular disease, and (8) cardiovascular disease would mediate the relationship between cardiovascular risk factors and cognitive functioning. The results of the analyses indicate that there was no effect of cardiovascular disease on cognitive functioning; however, there were significant effects of cardiovascular risk factors on cognitive functioning that ranged between B=-/021 and B=-/145. Moreover, it was found that cardiovascular risk factors mediate the relationship between ADLs and cognitive functioning, while cardiovascular disease does not. These results suggest that addressing cardiovascular risk factors may be more important than addressing existing cardiovascular disease to protect future cognitive functioning. This shows the importance of primary/secondary prevention versus tertiary interventions.Item Chemokine CXCL8 Mediated Intercellular Interactions in HIV-1 associated Dementia(2013-12-01) Mamik, Manmeet K.; Ghorpade, AnujaThis dissertation explores the role of chemokine CXCL8 during human immune deficiency virus (HIV)-1 infection in the brain. Chemokine CXCL8 is an important neutrophil chemoattractant implicated in various neurodegenerative disorders. It is upregulated in the brains and cerebrospinal fluid of HIV-1 infected individuals suggesting its potential role in HIV-1 associated neuroinflammation. Astrocytes are known to be the major contributors to the CXCL8 pool. Interleukin (IL)-1β activated astrocytes exhibit significant upregulation of CXCL8. In order to determine the signaling pathways involved in CXCL8 regulation in astrocytes, we employed pharmacological inhibitors for non-receptor Src homology-2 domain-containing protein tyrosine phosphatase (SHP) 2 and mitogen-activated protein kinases (MAPK) pathway and observed reduced expression of CXCL8 following IL-1β stimulation. Thus, our findings suggest an important role for SHP2 in CXCL8 expression in astrocytes during inflammation, as SHP2, directly or indirectly, modulates p38 and extracellular signal regulated kinase (ERK) MAPK in the signaling cascade leading to CXCL8 production. In the post-antiretroviral therapy (ART) era, low level of productive replication of HIV-1 in brain is a critical component of neuropathogenesis regulation. HIV-1 replication is a complex mechanism involving both host and viral factors. The majority of viral replication in brain occurs in perivascular macrophages and/or 2 microglia. In this study, we investigated the effect of CXCL8 on productive infection of HIV-1 in human monocytes-derived macrophages (MDM) and primary human microglia. The results show that CXCL8 mediates productive infection of HIV-1 in MDM and microglia via receptors CXCR1 and CXCR2 and induces HIV-1 long terminal repeat (LTR) promoter activity. Detailed understanding of astrocyte signaling and HIV-1 replication, as presented in the thesis, will be relevant to glial-neuronal interactions, which are central to neuroinflammation in HIV-1 and many other neurodegenerative conditions. Also, modulation of levels of CXCL8 can be a therapeutic strategy for control of productive HIV-1 replication in the brain.Item Met-Enkephalin-Arg-Phe (MERF) and Metabolism of MERF Across the Canine Heart Vascular Bed(2000-08-01) Pearlman, Eric Brian; Barbara Barron; Patricia A. Gwirtz; Michael L. SmithPearlman, Eric B., Met-Enkephalin-Arg-Phe (MERF) and Metabolism of MERF Across the Canine Heart Vascular Bed. Master of Science (Biomedical Science), August, 2000, 37 pp., 3 tables, 11 figures, references, 20 titles. Methionine enkephalin arginine phenylalanine (MERF) has been shown to be co-stored with catecholamines in vesicles. The catecholamines appear to decrease the degradation rate of 3H-MERF in vitro. The aim of this study is to investigate the spillover and metabolism of MERF across the canine heart vascular bed. I hypothesize that 3H-MERF is either degraded in the plasma or taken up and degraded by the heart. I further hypothesize that the exogenous catecholamine, isoproterenol, inhibits or reduces the rate of MERF degradation. Mongrel dogs were anesthetized and instrumented to record cardiovascular parameters, infuse 3H-MERF, and obtain blood samples across the heart. Blood samples were taken before and after stopping 3H-MERF infusion to evaluate kinetics, show steady state, and test the effect of treatments. Steady state concentration of 3H-MERF was observed after 30 min of infusion. Chromatography separated intact from degraded 3H-MERF. Three experimental groups were used: control, propranolol plus isoproterenol, and propranolol only. Blockade of β-receptors was necessary to prevent changes in coronary blood flow. Propranolol bolus (0.2 mg/kg) was administered IV at 50 min. 3 μg/min isoproterenol or 0.5 ml/min normal saline was infused starting at 70 min until the end of sample collection. The 3H-MERF venous-arterial (V-A) difference prior to treatment was negative, indicating degradation in the plasma or uptake and degradation by the heart. The 75 min V-A difference was used to calculate the effect of the infusions on the degradation or uptake of the 3H-MERF; this value was unchanged by any treatment. Spillover of 3H-MERF was significantly lower in the propranolol + isoproterenol dogs (p [less than] 0.05) compared to propranolol only treatment at 75 min. Heart rate was significantly lower for the propranolol only group compared to control. Blood pressure and change in coronary flow were unchanged. In conclusion, isoproterenol does not affect the metabolism of 3H-MERF across the canine heart vascular bed. Propranolol, however, does increase the intact 3H-MERF in the plasma, but additional β adrenergic blockade agents need to be investigated to determine the mechanism by which this takes place.Item Sexually Dimorphic Anxiety-Like Interoceptive Discriminative Stimuli(1997-12-01) Jung, Marianna E.; Walls, Cleatus; Downey, H. Fred; Forster, MichaelJung, Marianna E., Sexually Dimorphic Anxiety-Like Interoceptive Discriminative Stimuli. Doctor of Philosophy (Biomedical Sciences), December 1997, 150 pp, introduction, 2 chapters, discussion, bibliography, 109 titles. This study compared gender differences in the anxiogenic stimuli induced by either a GABA-A antagonist, pentylenetetrazol (PTZ) or by a 5-HT1b/2 agonist, m-chlorophenylpiperazine (m-CPP) before and during ethanol withdrawal (EW). Rats were trained to discriminate either PTZ (16mg/kg, IP) or m-CPP (1.2 mg/kg, IP) from saline in a two lever choice task for food reward. Male and female rats were gonadectomized or sham-operated, and ovariectomized (OVX) female rats were tested during replacement treatment with 17β estradiol (2.5 mg, 21 day release, sc). The dose-response for the discrimination of the interoceptive stimulus (IDS) produced by PTZ (0-16 mg/kg) or m-CPP (0 to 1.2 mg/kg) was measured under all hormonal conditions. For m-CPP trained rats, latency to first lever-press response was also tested. Results: sham and estradiol-replaced female rats had higher ED50s for discrimination of the PTZ or m-CPP IDS than intact males or OVX rats. There is a dose-related impairment of operant responding after mCPP injection. Sham and estradiol replaced OVX rats showed an increased delay to the initiation of response after m-CPP injection as compared to sham or castrated male rats or OVX rats that showed no effect at the doses tested. Rats then received a chronic ethanol diet (6.5%) for 10 days. At twelve hours of ethanol withdrawl, they were tested for lever selection after saline injection. Fewer sham female and estradiol-replaced female rats responded on the drug lever during acute EW as compared to sham male, castrated or OVX rats. In general, the anxiogenic drug lever selection of OVX rats resembled that of male rats but was restored toward that of sham female rats by estradiol replacement. Castration did not alter the response of male rats to either PTZ or mCPP. Serum β –estradiol concentrations were determined by radioimmunoassay for sham, OVX, and estradiol-replaced female rats. The concentration was significantly higher in hormone-replaced female rats than in OVX. The estradiol concentration in sham female rats showed a cyclic pattern over 4 consecutive days, but this pattern did not correlate with any difference in IDS. Blood ethanol concentration (BEC) was determined using head space gas chromatography. BEC was higher in intact female rats than in intact male rats after ethanol injection (2 g/kg, ip), but did not differ during EW. Conclusions: females produce less anxiogenic IDS in response to either GABA inhibition or 5-HT1b/2 activation, but are more impaired by m-CPP in their ability to initiate operant responses than male rats. In addition, fewer intact females developed a spontaneous IDS during EW than males which is not the result of lower BEC. Estrogen appears to play a trophic role in altering responsiveness to anxiogenic stimuli.Item The Effects of Short-Term Intermittent Hypoxic Apneas on Sympathetic Nerve Activity and the Chemoreflex Control of Sympathetic Nerve Activity in Humans(2004-05-01) Cutler, Michael J.; Smith, Michael L.; Raven, Peter B.; Downey, H. FredCutler, Michael J., The Effects of Short-Term Intermittent Hypoxic Apneas on Sympathetic Nerve Activity and the Chemorelex Control of Sympathetic Nerve Activity in Humans. Doctor of Philosophy (Integrative Physiology), May 2004. Obstructive sleep apnea is associated with sustained elevation of muscle sympathetic nerve activity (MSNA) and altered chemoreflex control of MSNA both of which likely play an important role in the development of hypertension in these patients. Hypoxia is postulated to be primary stimulus for elevated daytime MSNA and altered chemoreflex control of MSNA both of which likely play an important role in the development of hypertension in these patients. Hypoxia is postulated to be the primary stimulus for elevated daytime MSNA and altered chemoreflex control of MSNA in OSA patients. Recently, short-term exposure to hypoxia was shown to produce sustained elevation of MSNA. Therefore, we studied the effects of 20 min of intermittent voluntary hypoxic apneas (to mimic OSA) on MSNA and the chemoreflex control of MSNA during 180 min post exposure. Also, we compared MSNA and chemoreflex control of MSNA for 180 min following either 20 min of intermittent voluntary hypoxic apneas, hypercapnic hypoxia, or isocapnic hypoxia. Consistent with our hypotheses, both total MSNA and MSNA burst frequency were elevated following 20 min of intermittent hypoxic apnea compared to baseline (p [less than] 0.05). Both total MSNA and MSNA burst frequency remained elevated throughout the 180 min recovery period and were statistically different from time control subjects throughout this period (p [less than] 0.05). Additionally, a significant main effect for chemoreflex control of SNA was observed following 20 min of intermittent hypoxic apneas (p [less than] 0.001). Specifically, the MSNA response to a single hypoxic apnea was attenuated 1 min post exposure compared to baseline (p [less than] 0.001), became augmented within 30 min of recovery, and remained augmented through 165 min of recovery (p [less than] 0.05). Finally, comparison of treatment groups (hypoxic apnea, hypercapnic hypoxia, and isocapnic hypoxia) revealed no differences in resting MSNA (p=0.50) and the chemoreflex control of MSNA (p=0.69) during recovery. Therefore, these data support the hypothesis that short-term exposure to intermittent hypoxic apneas resulted in sustained elevation of MSNA and altered chemoreflex control of MSNA. Furthermore, these responses appear to be mediated by hypoxia.Item The Role of Advanced Glycation End Products in Brain Aging(2007-10-01) Thangthaeng, Nopporn; Michael J. Forster; Tina MachuThangthaeng, Nopporn, The Role of Advanced Glycation End Products in Brain Aging. Doctor of Philosophy (Biomedical Sciences), October, 2007, 178 pp., 9 tables, 6 figures, bibliography, 213 titles. Glycoxidation is a process of post-translational modification of proteins, involving both glycation and oxidation that ultimately generated advanced glycation end products (AGEs). Glycoxidation, which pay promote oxidative stress and disrupt protein structure and function, is hypothesized to be responsible for pathological conditions related to aging, diabetes, neurodegenerative diseases, and degenerative ophthalmic diseases. Previous studies have demonstrated that AGEs accumulate in the brains of aged animals and humans, yet few studies have directly addressed the possibility that AGEs are a cause of age-related brain dysfunction. Therefore, the overall purpose of the present studies was to examine the role AGEs in normal brain again and the associated decline in cognitive and psychomotor function. In order to achieve the goals, two different approaches were taken. The first approach involved (i) determining whether or not AGEs accumulated in different regions of the brain as a function of age and (ii) determining whether these changes were correlated with individual differences in the ability of old mice to perform in tests of cognitive and psychomotor function. Age-associated accumulation of CML, a predominant form of AGEs in vivo, and expression of receptor for AGEs (RAGE) protein, inferred from densitometry quantification of immunoblots in different regions of the brain, were assessed by comparing groups of 8-or 25-month old mice. The 25-month-old mice were administered a series of behavioral tests to assess cognitive and psychomotor function prior to assessment of glycation status. In the second approach, groups of mature (6 mos) and older mice (18 mos) were fed with a control diet or a diet enriched with galactose (49% of caloric content), an intervention that was expected to promote formation of AGEs. The mice were subsequently tested for impairment of their cognitive and psychomotor functions after 8 weeks on the assigned diet. Upon completion of the behavioral tests (after 14 weeks on diet), amounts of CML and RAGE protein were assessed through densitometric analyses of the immunoblots. The main findings from the first approach were that (i) there was a robust increase in CML content and expression of RAGE protein in the aged mouse brain that occurred in a region-specific manner; (ii) the relative amounts of CML and RAGE were not closely associated with the degree of age-related impairment of mice tested for brain function. The main findings from the second approach were that high dietary galactose: (i) failed to induce aged-like behavioral impairments in young/mature mice; (ii) exacerbated age-related impairment of some psychomotor functions and (iii) had no significant effects on glycation status or oxidative damage. Comparison of the experimental outcomes from the first and second approaches was complicated by a difference in the fat content of the diets fed to the mice in the two studies, which had an apparent effect on the amounts of AGEs and protein oxidation present in young mice. However, considering the results of the two studies independently warrants the following conclusions: (i) Amounts of AGEs do not predict individualized brain aging as assessed by neurobehavioral impairment and may instead by largely reflective of chronological age. (ii) Diets enriched with galactose may produce deleterious effects in older mice that do not involve a change in oxidative damage or glycation status. Overall, these studies provide little support for a specific role of glycoxidation in normal brain aging. It is impossible that the extent of accrual of AGEs in the normally aging brain is insufficient to affect cellular function, whereas larger accumulations of AGEs may be associated with various pathological conditions discussed in the literature.Item Translational Control by Estrogen-Induced Signaling in Primary Rat Hippocampal Neurons(2008-07-01) Smith, Lonell T.; Simpkins, James; Das, Hriday K.; Machu, Tina K.Smith, Lonell T., Estrogen-Induced Signaling in Primary Rat Hippocampal Neurons. Masters (Biomedical Sciences). July 2008. 53 pages, 1 illustration, 7 figures. 37 titles. Abstract. The enhancing effects of 17-beta estradiol (E2) on performing cognitive tasks has been well demonstrated in laboratory mice, rats, and primates. Also there is ample clinical evidence indicating E2 enhances memory and reduces risk for Alzheimer’s disease. Furthermore, by increasing the capacity for long-term potentiation (LTP) in the hippocampus, E2 effectively increases the synaptic plasticity of this brain region in a manner that correlates with memory formation. The molecular mechanisms underlying LTP and synaptic plasticity have largely focused on the role of E2-induced signal transduction in the nucleus, and regulation of plasticity related gene expression at the transcriptional level. Conversely, the idea that E2-incuded signaling regulates at the level of translation and may play a role in these processes has yet to be explored. Recently, extracellular signal-regulated kinase (ERK) and mammalian target of rapamycin (mTOR) signaling pathways have been shown to couple synaptic activation to protein synthesis machinery. Here we investigate translational control by E2-induced ERK and mTOR signaling in primary neuronal culture. E2-induced signaling resulted in enhanced phosphorylation of ribosomal protein (S6) and eIF4E binding protein 1 (4EBP1) in an ERK and mTOR-dependent manner. Neuronal activity-dependent ERK and mTOR signaling have been shown to induce translation of a diverse array of dendritic resident mRNAs, including α-CaMKII and GluR1 subunits. Using a green fluorescent protein (GFP) translational reporter, we demonstrated that E2 stimulates GFP protein synthesis. We have also demonstrated that E2 treatment of hippocampal neurons increases surface expression of GluR1. Taken together, our results provide a mechanism by which E2 modulates the components necessary for persistent forms of LTP and long-term depression (LTD).