The spatial heterogeneity of myocardial perfusion and metabolism was studied in 11 anaesthetized dogs under resting conditions. In each heart local myocardial blood flow was assessed using the tracer microsphere technique in 256 samples (mean mass: 83.1 mg) taken from the left anterior ventricular wall. In the same samples, the following biochemical parameters were determined: accumulation of [3H]-deoxyglucose (a measure of glucose uptake), free cytosolic adenosine (S-adenosylhomocysteine accumulation technique, a measure of tissue oxygenation and a possible mediator of blood flow regulation), and the specific activities of oxidative (citrate synthase, cytochrome-c-oxidase) and glycolytic (hexokinase, phosphoglycerate kinase) enzymes. Capillary density and mitochondrial and myofibril volume densities were determined by morphometry. Myocardial perfusion in each sample (average 0.77 ml min-1 g-1) varied between 0.1 and 2.5 times the mean (coefficient of variation 0.30+/-0.02). [3H]-deoxyglucose was deposited locally in proportion to perfusion. Samples showing low flow (<0.2 ml min-1 g-1) did not exhibit increased levels of cytosolic adenosine. The specific activities of the oxidative and glycolytic enzymes, however, were uniformly distributed between low and high flow areas. Furthermore, capillary density and mitochondrial and myofibril densities were similar in high and low flow regions. The results show firstly that local glucose metabolism in the heart occurs in proportion to local blood flow, suggesting that high flow regions have a higher than average metabolic rate. Secondly, regions of low flow are not compromized by critical oxygenation and most likely have a lower than average oxygen demand and finally, the homogeneous distribution of oxidative and glycolytic enzymes, as well as the homogeneous myocardial ultrastructure, suggest that areas with high and low blood flow under resting conditions may increase their metabolic rate to similar levels when required.
Background-Left ventricular myocardial blood flow is spatially heterogeneous. The hypothesis we tested was whether myocardial areas with a steady-state flow Ͻ0.5 times mean flow are underperfused and areas with flow Ͼ1.5 times mean flow are overperfused. Methods and Results-In anesthetized beagle dogs (nϭ10), the relationship between local blood flow versus S-adenosylhomocysteine (SAH) concentration, a measure of the free intracellular adenosine concentration, and lactate, a measure of the myocardial NADH/NAD ϩ ratio, were determined under control conditions and after coronary constriction. Control local myocardial blood flow was 0.99Ϯ0.46 mL ⅐ min Ϫ1 ⅐ g Ϫ1 , with a coefficient of variation of 0.36Ϯ0.12 (nϭ256 per heart; sample wet mass, 125Ϯ30 mg). Tissue concentrations of SAH (3.4Ϯ2.5 nmol/g) and lactate (1.88Ϯ0.80 mol/g) were not elevated in low-flow samples. However, after coronary artery constriction, poststenotic blood flow decreased from 1.00Ϯ0.27 to 0.49Ϯ0.22 mL ⅐ min Ϫ1 ⅐ g Ϫ1 (PϽ0.04), with significant correlation between local SAH and flow (rϭϪ0.59) and lactate and flow (rϭϪ0.50). Although nearly all samples from control high-flow regions showed increased SAH concentrations if relative flow after stenosis was Ͻ1.0, control low-flow samples frequently displayed low SAH concentrations. The percent reduction in flow determined the changes in the local SAH and lactate concentration, independent of the local control blood flow. Conclusions-When the coronary inflow is unrestricted, the oxygen supply to control low-flow regions meets metabolic demand. Flow to control high-flow regions reflects a higher local demand rather than overperfusion. Thus, blood flow heterogeneity most likely reflects differences in aerobic metabolism. (Circulation. 1998;98:262-270.)
A 37-year-old female patient with systemic mastocytosis who was admitted with severe unexplained bleeding symptoms is studied. Laboratory procedures established the diagnosis of a patient-derived-heparin-like anticoagulant as a very rare hemostatic abnormality predisposing to bleeding. The patient died from refractory disease despite therapy with protamine, initiation of chemotherapy, and supportive measures. The case illustrates the clinical presentation and diagnosis of heparin-like anticoagulants. Etiology, pathophysiology, and therapeutic options are discussed.
Our results do not support the hypothesis that systemic Cpn, HSV or CMV- infection or evidence of Cpn-, HSV- or CMV-DNA in carotid plaques causes plaque destabilization and cerebral thromboembolism. Plaque infection could only be observed in cases with advanced atherosclerosis.
Homocysteine may have deleterious effects on the cardiovascular system. It has been hypothesized that these effects may be brought about by a decrease in the adenosine concentration via the S-adenosylhomocysteine hydrolase reaction. A requirement for this causal relationship is proof of a reduction in vascular adenosine concentration during conditions of elevated homocysteine concentrations. In the present communication we summarize published data obtained during systematic variation of the arterial homocysteine concentration. Most of the results reported show that an increase in homocysteine concentration to 100 microM is associated with a 20-50% decrease in vascular adenosine concentration and an increase in tissue S-adenosylhomocysteine level. Homocysteine effects on the adenosine concentration seem to be more pronounced under conditions of impaired oxygenation. Further experiments, in particular on organs and tissue that release high amounts of homocysteine, i.e., the liver, are warranted to study the potential effects of homocysteine on vascular and tissue adenosine concentrations and consequent effects on organ function. The evidence obtained may be relevant for future assessment of risk indicators in conjunction with homocysteine pathogenicity, which might potentially be extended to measurements of adenosine or S-adenosylhomocysteine levels.
It is well established that myocardial blood flow is heterogeneous on the local level. During recent years comprehensive studies have been undertaken to assess the relation between myocardial metabolism and spatial blood flow heterogeneity. Based on the type of measurements two major groups of studies have been performed: enzyme activity and tissue metabolite level assessments. Enzyme activity measurements have provided only limited insight into the coupling of local metabolism and flow. This is probably due to the fact that, in addition to estimated Vmax values, local substrate affinity (Km values) and substrate concentrations affect the metabolite fluxes. However, the latter two variables remain normally unknown. In contrast, valuable insight has been obtained concerning flow-metabolism matching from tissue metabolite measurements, especially when connected with mathematical model analyses. The latter permitted the calculation of metabolic flux rates (e.g., production of oxidation water, citric acid cycle flux, glucose uptake, fatty acid uptake) or the translation of the metabolic indexes into physiologically meaningful local metabolite concentrations (e.g., free cytosolic adenosine). The bottom line of the studies reported to date is that the broad range of myocardial flows observed under resting control conditions correlates with local metabolism possibly affected by spatial differences in adrenergic stimulation. Thus, high flow samples exhibit a higher oxidative metabolism than low flow samples. As a result the flow threshold below which local myocardial ischemia ensues is higher in control high flow samples. The importance of these findings with respect to local flow-metabolism matching is underlined by the finding that the probability of developing an infarction following ischemia/reperfusion is related to the functional state of the myocardium under control conditions, i.e., the local level of flow-metabolism matching.
The concentration of heat-shock proteins of 70 kD (HSP70) in heart tissue has been shown to increase during transient myocardial ischaemia and to persist during several hours of reperfusion. In this study the relationship between the local myocardial HSP70 concentration and blood flow was addressed for control physiological conditions and acute myocardial ischaemia. A specific aim of this study was to address the question of whether low flow areas under control physiological conditions have undergone a transient ischaemia during the preceding hours and thus may be in a state of hibernation or stunning. In 12 anaesthetized, open-chest beagle dogs (6 control and 6 with 60-min coronary artery stenosis) heart rate, mean aortic pressure, mean arterial partial pressure of O2 and partial pressure of CO2 averaged 85+/-16 beats/min, 94+/-14 mmHg, 102+/-17 mmHg and 39+/-6 mmHg, respectively. Regional HSP70 and myocardial blood flow (RMBF) were measured using an HSP70-enzyme-linked immunosorbent assay and the tracer microsphere technique, respectively, in samples of 250 mg wet mass. In the control group the mean RMBF was 1.06+/-0.59 ml.min-1.g-1 and the local HSP70 concentration was 7.08+/-1.03 microg/mg cytosolic protein. Myocardial HSP70 showed a blood flow-independent regional biological heterogeneity, equivalent to a coefficient of variation of 0.31. Local HSP70 concentrations did not differ (P>0.05) between control low and high flow samples, 6.16+/-1.0 vs 6.08+/-0.75 microg/mg cytosolic protein, respectively. However, after 60 min of coronary artery occlusion the local HSP70 concentration increased from 7.08 +/-1.03 to 13.43+/-3.19 microg/mg cytosolic protein (P<0. 001). There was a significant inverse relationship between the percent reduction of local blood flow and HSP70 (r=-0.56, P<0.001). From these results it is concluded that: (1) low flow samples under control physiological conditions are unlikely to be in a state of hibernation or stunning since their HSP70 concentration is normal and (2) the increase in the local HSP70 concentration during myocardial ischaemia reflects the degree of impairment of O2 delivery.
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