Browsing by Subject "vagus"
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Item Dysfunctional neuroimmune pathways promote the development and maintenance of lupus hypertension(2020-05) Pham, Grace S.; Mathis, Keisa W.; Rickards, Caroline A.; Goulopoulou, Styliani; Cunningham, J. Thomas; Ma, Rong; Mathew, Stephen O.Hypertension afflicts nearly half of the adults in the United States and the majority of cases have no known cause. Chronic inflammation has been implicated in the development and maintenance of hypertension, and autoimmunity may comprise one of its sources. Hypertension is highly prevalent in the autoimmune disease systemic lupus erythematosus (SLE), in which chronic aberrant inflammation may be a causative factor. Endogenous neuroimmune pathways, such as the hypothalamic-pituitary-adrenal (HPA) axis and the cholinergic anti-inflammatory pathway, likely contribute to this phenomenon. The HPA axis is a classical neuroimmune mechanism that senses peripheral inflammation via afferent vagal fibers, culminating in the release of the anti-inflammatory hormone cortisol. Previous studies have characterized HPA axis dysfunction in SLE, but less is known about how this dysregulation specifically impacts the hypertension that occurs in the setting of SLE. A second neuroimmune interaction, the cholinergic anti-inflammatory pathway, is an efferent vagus nerve-to-spleen mechanism that relies on T cell-produced acetylcholine to quell inflammation in acute settings and may be hypoactive in chronic inflammatory diseases like SLE. Notably, both of these neuroimmune mechanisms depend on vagus nerve function, identifying the vagus as a potential target for neuromodulation. Furthermore, the relationship between chronic inflammation and hypertension validates the investigation of neuroimmune pathway dysfunction towards novel mechanisms of hypertension. Herewithin, the HPA axis and cholinergic anti-inflammatory pathway are investigated using the well-established NZBWF1 mouse model of lupus hypertension. Our findings are that (1) administration of an inflammatory stimulus that activates vagal afferents elicits comparable neuronal activation in the paraventricular nucleus of the hypothalamus, compared to control mice, despite heightened peripheral inflammation; (2) amplification of efferent vagus nerve activity reduces blood pressure and renal inflammation; and (3) chronic unilateral vagotomy paradoxically results in decreased blood pressure and renal inflammation. Taken together, these findings identify dysfunction in two neuroimmune pathways while demonstrating that interventions targeting these pathways may have therapeutic benefits in lupus hypertension. In terms of future impact, these results may promote continuing inquiry in a more recently discovered neuroimmune pathway (i.e., cholinergic anti-inflammatory pathway), as well as reinstate curiosity in an older, abandoned area of research (i.e., HPA).Item Local Enkephalins Modulate Vagal Control of Heart Rate(2001-05-01) Jackson, Keith E.; James L. Caffrey; H. Fred Downey; Michael W. MartinJackson, Keith E., Local Enkephalins Modulate Vagal Control of Heart Rate. Doctor of Philosophy (Biomedical Sciences), May 2001; 112pp; 7 tables; 22 figures; bibliography, 99 titles. Endogenous opioids, such as enkephalins, were first investigated for their ability to modulate pain. A body of evidence now supports opioid actions in many facets of regulation, including the cardiovascular system. Our laboratory is particularly interested in the ability of opioids to modulate autonomic function. Specifically, the role of the endogenous encephalin, methionine-enkephalin-arginine-phenylalanine (MEAP) was investigated to determine its ability to modulate parasympathetic function in the canine. To investigate MEAP’s response in the sinoatrial (SA) node a novel application of microdialysis was employed, whereby microdialysis was employed, whereby microdialysis probes were fabricated as described by Dr. David Van Wylen (38), and implanted in the SA node. After implantation of the probe, there was a significant attenuation of vagal function during the nodal application of MEAP. Specifically, vagally mediated bradcardia was reduced as compared to control, during the nodal application of MEAP. This inhibition of the vagus by MEAP was blocked by naltrindole, a selective delta antagonist. These data suggested that the vagolytic effects of MEAP were elicited via a delta opioid receptor. To test the hypothesis that MEAP’s effects were elicited through a delta opioid receptor mechanism, selective agonists and antagonists for the opioid receptors were utilized. An attenuation of vagal bradycardia was only observed during the infusion of a very selective delta opioid receptor agonist, deltorphin. A mu and kappa agonist showed no significant differences from control. Deltorphin was observed to elicit vagolytic effects in a similar concentration range as MEAP. However, deltorphin was more efficacious that MEAP. There was a significant attenuation of the deltorphin and MEAP’s vagolytic effects, during the co-infusion of the selective delta antagonist, naltrindole. The mu and kappa antagonists were both ineffective. These data further demonstrate that the observed vagolytic effect is linked to a delta opioid receptor. Endogenous MEAP. A series of experiments were undertaken to determine if endogenous MEAP could be demonstrated in the SA node and is so, was it similarly vagolytic. A preconditioning-like protocol was performed to produce intermittent local nodal ischemia to increase the local concentration of endogenous MEAP. The resulting MEAP was measured and was observed to be elevated during the periods of local nodal ischemia and return to control during reperfusion. Contrary to expectations an augmentation of vagal function was observed, during vagal stimulation. The augmented vagal bradycardia was only observed during ischemia, when MEAP was elevated and returned to control during each subsequent reperfusion. Therefore, there was a correlation between elevated MEAP concentrations and augmented vagal bradycardia. The delta antagonist, naltrindole, prevented the augmented vagal response, during nodal ischemia Glibenclamide, a selective KATP channel blocker, partially reversed the augmented vagal response. These data confirm that delta opiate receptors are involved in the augmented vagal bradycardia and that the mechanism may involve the activation of a KATP channel.