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Chronic Ventricular Sympathectomy : Effects on Myocardial MetabolismAdix Longlet, Nancy J. 08 1900 (has links)
Chronic ventricular sympathectomy elicits changes in the coronary circulation, myocardial oxygen consumption and size of infarction resulting fromcoronary occlusion. These changes indicate a change occurring in the basic metabolism of the heart in response to the removal of its sympathetic nervous input. This hypothesis was tested using two groups of dogs, a shamoperated control and a ventricular sympathectomized group. The sympathectomy procedure was an intrapericardial surgical technique which selectively removes ventricular sympathetic input. Four weeks after surgery, left ventricular tissue samples were obtained and rapidly frozen to -80°C. Selected metabolic variables were then compared between the two groups.
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Diabetes and Coronary Surgery : Metabolic and clinical studies on diabetic patients after coronary surgery with special reference to cardiac metabolism and high-dose GIKSzabó, Zoltán January 2001 (has links)
Introduction An increasing proportion of the patients undergoing cardiac surgery have diabetes mellitus, in particular type II diabetes. In spite of this, diabetic patients have received limited attention in this setting. Although diabetes is a metabolic disease cardiac metabolism in association with surgery has previously not been explored in diabetics. This investigation was carried out to describe the metabolic state of the heart in diabetics after cardiac surgery and to study if it is accessible to metabolic intervention with high-dose GIK. Also, the potential hazards associated with such a regime in clinical practice were evaluated. Furthermore, a comparison of the outcome in diabetic and nondiabetic patients after coronary surgery was done. Methods Myocardial metabolism and how it was influenced by high-dose GIK was assessed with coronary sinus catheter technique in a prospective randomized study on 20 type II diabetic patients undergoing CABG (paper I, II). Safety issues concerning high-dose GIK were assessed in two retrospective studies. The potential role of metabolic interventions for neurological injury was assessed in a cohort of 775 consecutive patients undergoing CABG or combined CABG + valve surgery, in whom metabolic interventions gradually replaced traditional treatment for postoperative heart failure (paper III). A detailed analysis of blood glucose and electrolyte control was done in all cases (n=89) receiving high-dose GIK during one year (paper IV). The hemodynamic impact of highdose GIK was assessed with standard postoperative monitoring including Swan-Ganz catheters (paper II, IV). Outcome and prognosis after CABG in diabetic patients (n=540) were compared with nondiabetics (n=2239) with the aid of the institutional database comprising all isolated CABG procedures from 1995-1999 (paper V). Results The metabolism of the diabetic heart after CABG was characterized by predominant uptake of FFA and restricted uptake of carbohydrate substrates. A high extraction rate of beta-hydroxybutyric acid and glutamate was also found. Alanine was released from the heart (paper I). High-dose GIK induced a shift towards uptake of carbohydrates, in particular lactate, at the expense of FFA and betahydroxybutyric acid (paper II). A substantial systemic glucose uptake was found during high-dose GIK treatment but the uptake tended to be lower and blood glucose higher if adrenergic drugs were used or/and if the patient was a diabetic (paper IV). High-dose GIK was associated with beneficial effects on cardiac output both in the prospective and retrospective analyses (paper II, IV). No evidence for untoward neurological effects associated with GIK treatment was found. History of cerebrovascular disease was the most important risk factor for postoperative cerebral complications and in general markers for advanced atherosclerotic disease were found to be of importance (paper III). High-dose GIK in clinical practice was associated with acceptable blood glucose and electrolyte control and no serious adverse events were recorded (paper IV). Patients with diabetes undergoing CABG had an acceptable short-term mortality that did not differ significantly from non-diabetic patients. However, diabetic patients had a higher early postoperative morbidity particularly with regard to stroke, renal- and infectious complications. Also, long-term survival was markedly reduced in diabetic patients, particularly in insulin treated patients (paper V). Comments FFA were the main source of energy for the heart in type II diabetics after CABG whereas the uptake of carbohydrates was restricted. The high extraction rates of beta-hydroxybutyric acid and glutamate may represent an adaptation to the unfavorable metabolic situation of the post-ischemic diabetic heart. High-dose GIK can be used in type II diabetic patients after cardiac surgery to promote carbohydrate uptake at the expense of FFA and beta-hydroxybutyric acid. The magnitude of this shift was sufficient to account for the entire myocardial oxygen consumption assuming that the substrates extracted were oxidized. This could have implications for the treatment of the diabetic heart in association with surgery and ischemia. Provided careful monitoring high-dose GIK can be safely used in clinical practice and this treatment deserves further evaluation in the treatment of postoperative heart failure. High-dose GIK also provides a means for strict blood glucose control and as substantial amounts of glucose can be infused even in critically ill patients, it may prove useful for nutrition in critical care. Several of the risk factors for neurological injury identified constitute markers for advanced atherosclerotic disease, thus, also providing an explanation for the increased risk of neurological injury in diabetics after cardiac surgery. Short-term mortality was acceptable in diabetics after CABG. However, further efforts are warranted to address postoperative morbidity and late outcome. This represents a challenge as diabetic patients are accounting for an increasing proportion of the patients undergoing CABG. / On the day of the public defence the status of article IV was: Submitted and the title of article IV was in the printed version: High-dose GIK in cardiac surgery - clinical safety issues and lessons learned.
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Hemodynamic and cardiometabolic studies in patients with distributive circulatory dysfunctions : with special reference to the effects of the beta-1-adrenoreceptor agonist prenalterolReiz, Sebastian January 1979 (has links)
A total of 49 patients were studied, using invasive hemodynamic techniques with systemic arterial, pulmonary artery and right atrial pressure recordings together with thermodilution cardiac output determinations. Sixteen of the patients were also subjected to cardiometabolic studies, using measurement of coronary sinus blood flow by the continuous thermodilution technique and analyses of oxygen content and lactate concentration in the systemic and coronary circulation. A common denominator in the five investigations was, that a distributive cardiovascular dysequilibrium was either induced (for surgical or anaesthesiological reasons) or already present due to a pathological condition. Thoracic epidural block from T 1 to T 12 induced marked decrease in systemic blood pressure due to vasodilation and impairment of cardiac performance. Prenalterol administration effectively abolished the low blood pressure by its marked inotropic action, having no effect on systemic vascular resistance. Myocardial oxygen consumption changed in parallel with the changes in cardiac work following both thoracic epidural block and prenalterol. Coronary vascular resistance was markedly decreased by the block and was not affected by prenalterol. It is suggested, that the critically low perfusion pressure is the main cause of the coronary vasodilation and that alpha-blockade induced by the thoracic epidural block is of less importance. The combination of a thoracic epidural block from T 1 to T 12 and selective ßi-stimulation with prenalterol was an effective way to modify the cardiovascular response to infrarenal aortic cross clamping. This treatment transferred the patients to a more favourable cardiac function curve and possibly facilitated the redistribution of blood flow in association with clamping. In association with declamping of the infrarenal aorta or the common iliac arteries, volume loading to a slightly elevated left ventricular filling pressure shortly before declamping was an effective way to counteract the expected blood pressure drop. A normal left ventricular filling pressure prior to declamping did not prevent the blood pressure drop following declamping. It is suggested, that mismatching between vascular volume and blood volume is the main cause of declamping hypotension. In patients with low resistance, distributive septic shock caused by gram negative bacteremias and signs of impaired cardiac function, prenalterol effectively reversed the hypotension and improved tissue perfusion by selectively increasing cardiac output. In parallel to the increased cardiac work, an increase in myocardial metabolic demand was demonstrated. / digitalisering@umu.se
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Impaired cardiovascular responses to glucagon-like peptide 1 in metabolic syndrome and type 2 diabetes mellitusMoberly, Steven Paul 30 January 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Recent advancements in the management of systemic glucose regulation in obesity/T2DM include drug therapies designed to utilize components of the incretin system specifically related to glucagon-like peptide 1 (GLP-1). More recently, GLP-1 has been investigated for potential cardioprotective effects. Several investigations have revealed that acute/sub-acute intravenous administration of GLP-1 significantly reduces myocardial infarct size following ischemia/reperfusion injury and improves cardiac contractile function in the settings of coronary artery disease, myocardial ischemia/reperfusion injury, and heart failure. Despite an abundance of data indicating that intravenous infusion of GLP-1 is cardioprotective, information has been lacking on the cardiac effects of iv GLP-1 in the MetS or T2DM population. Some important questions this study aimed to address are 1) what are the direct, dose-dependent cardiac effects of GLP-1 in-vivo 2) are the cardiac effects influenced by cardiac demand (MVO2) and/or ischemia, 3) does GLP-1 effect myocardial blood flow, glucose uptake or total oxidative metabolism in human subjects, and 4) are the cardiac effects of GLP-1 treatment impaired in the settings of obesity/MetS and T2DM. Initial studies conducted in canines demonstrated that GLP-1 had no direct effect on
coronary blood flow in-vivo or vasomotor tone in-vitro, but preferentially increased myocardial glucose uptake in ischemic myocardium independent of effects on cardiac contractile function or coronary blood flow. Parallel translational studies conducted in the humans and Ossabaw swine demonstrate that iv GLP-1 significantly increases myocardial glucose uptake at rest and in response to increases in cardiac demand (MVO2) in lean subjects, but not in the settings of obesity/MetS and T2DM. Further investigation in isolated cardiac tissue from lean and obese/MetS swine indicate that this impairment in GLP-1 responsiveness is related to attenuated activation of p38-MAPK, independent of alterations in GLP-1 receptor expression or PKA-dependent signaling. Our results indicate that the affects of GLP-1 to reduce cardiac damage and increase left ventricular performance may be impaired by obesity/MetS and T2DM.
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