Your search keyword '"Richmond, K. N."' showing total 3 results

1. Feedforward sympathetic coronary vasodilation in exercising dogs.

Author

Gorman MW, Tune JD, Richmond KN, and Feigl EO

Subjects

Adenosine blood, Adrenergic alpha-Antagonists pharmacology, Adrenergic beta-Antagonists pharmacology, Animals, Aorta physiology, Blood Pressure physiology, Coronary Circulation drug effects, Coronary Vessels innervation, Coronary Vessels physiology, Dogs, Feedback physiology, Male, Myocardium metabolism, Oxygen Consumption drug effects, Oxygen Consumption physiology, Phentolamine pharmacology, Propranolol pharmacology, Vasodilation drug effects, Coronary Circulation physiology, Physical Exertion physiology, Sympathetic Nervous System physiology, Vasodilation physiology

Abstract

The hypothesis that exercise-induced coronary vasodilation is a result of sympathetic activation of coronary smooth muscle beta-adrenoceptors was tested. Ten dogs were chronically instrumented with a flow transducer on the circumflex coronary artery and catheters in the aorta and coronary sinus. During treadmill exercise, coronary venous oxygen tension decreased with increasing myocardial oxygen consumption, indicating an imperfect match between myocardial blood flow and oxygen consumption. This match was improved after alpha-adrenoceptor blockade with phentolamine but was significantly worse than control after alpha + beta-adrenoceptor blockade with phentolamine plus propranolol. The response after alpha-adrenoceptor blockade included local metabolic vasodilation plus a beta-adrenoceptor vasodilator component, whereas the response after alpha + beta-adrenoceptor blockade contained only the local metabolic vasodilator component. The large difference in coronary venous oxygen tensions during exercise between alpha-adrenoceptor blockade and alpha + beta-adrenoceptor blockade indicates that there is significant feedforward beta-adrenoceptor coronary vasodilation in exercising dogs. Coronary venous and estimated myocardial interstitial adenosine concentrations did not increase during exercise before or after alpha + beta-adrenoceptor blockade, indicating that adenosine levels did not increase to compensate for the loss of feedforward beta-adrenoceptor-mediated coronary vasodilation. These results indicate a meaningful role for feedforward beta-receptor-mediated sympathetic coronary vasodilation during exercise.

Published

2000

2. Quantitative analysis of feedforward sympathetic coronary vasodilation in exercising dogs.

Author

Gorman MW, Tune JD, Richmond KN, and Feigl EO

Subjects

Adrenergic beta-Agonists pharmacology, Animals, Coronary Circulation drug effects, Coronary Circulation physiology, Coronary Vessels chemistry, Dogs, Dose-Response Relationship, Drug, Epinephrine blood, Epinephrine pharmacology, Extracellular Space chemistry, Feedback physiology, Models, Cardiovascular, Myocardium metabolism, Norepinephrine analysis, Norepinephrine blood, Oxygen Consumption physiology, Receptors, Adrenergic, beta physiology, Vasodilation drug effects, Coronary Vessels innervation, Coronary Vessels physiology, Physical Exertion physiology, Sympathetic Nervous System physiology, Vasodilation physiology

Abstract

Recent experiments demonstrate that feedforward sympathetic beta-adrenoceptor coronary vasodilation occurs during exercise. The present study quantitatively examined the contributions of epinephrine and norepinephrine to exercise coronary hyperemia and tested the hypothesis that circulating epinephrine causes feedforward beta-receptor-mediated coronary dilation. Dogs (n = 10) were chronically instrumented with a circumflex coronary artery flow transducer and catheters in the aorta and coronary sinus. During strenuous treadmill exercise, myocardial oxygen consumption increased by approximately 3.9-fold, coronary blood flow increased by approximately 3.6-fold, and arterial plasma epinephrine concentration increased by approximately 2.4-fold over resting levels. At arterial concentrations matching those during strenuous exercise, epinephrine infused at rest (n = 6) produced modest increases (18%) in flow and myocardial oxygen consumption but no evidence of direct beta-adrenoceptor-mediated coronary vasodilation. Arterial norepinephrine concentration increased by approximately 5. 4-fold during exercise, and coronary venous norepinephrine was always higher than arterial, indicating norepinephrine release from cardiac sympathetic nerves. With the use of a mathematical model of cardiac capillary norepinephrine transport, these norepinephrine concentrations predict an average interstitial norepinephrine concentration of approximately 12 nM during strenuous exercise. Published dose-response data indicate that this norepinephrine concentration increases isolated coronary arteriolar conductance by approximately 67%, which can account for approximately 25% of the increase in flow observed during exercise. It is concluded that a significant portion of coronary exercise hyperemia ( approximately 25%) can be accounted for by direct feedforward beta-adrenoceptor coronary vascular effects of norepinephrine, with little effect from circulating epinephrine.

Published

2000

3. Role of K(ATP)(+) channels and adenosine in the control of coronary blood flow during exercise.

Author

Richmond KN, Tune JD, Gorman MW, and Feigl EO

Subjects

ATP-Binding Cassette Transporters, Adenosine blood, Animals, Blood Pressure drug effects, Blood Pressure physiology, Dogs, Glyburide pharmacology, Heart Rate drug effects, Heart Rate physiology, Hypoglycemic Agents pharmacology, KATP Channels, Male, Myocardium metabolism, Oxygen Consumption physiology, Potassium Channel Blockers, Potassium Channels, Inwardly Rectifying, Vasodilation drug effects, Adenosine physiology, Coronary Circulation physiology, Physical Exertion physiology, Potassium Channels physiology

Abstract

The present study was designed to examine the role of ATP-sensitive potassium (K(ATP)(+)) channels during exercise and to test the hypothesis that adenosine increases to compensate for the loss of K(ATP)(+) channel function and adenosine inhibition produced by glibenclamide. Graded treadmill exercise was used to increase myocardial O(2) consumption in dogs before and during K(ATP)(+) channel blockade with glibenclamide (1 mg/kg iv), which also blocks adenosine mediated coronary vasodilation. Cardiac interstitial adenosine concentration was estimated from arterial and coronary venous values by using a previously tested mathematical model (Kroll K and Stepp DW. Am J Physiol Heart Circ Physiol 270: H1469-H1483, 1996). Coronary venous O(2) tension was used as an index of the balance between O(2) delivery and myocardial O(2) consumption. During control exercise, myocardial O(2) consumption increased approximately 4-fold, and coronary venous O(2) tension fell from 19 to 14 Torr. After K(ATP)(+) channel blockade, coronary venous O(2) tension was decreased below control vehicle values at rest and during exercise. However, during exercise with glibenclamide, the slope of the line of coronary venous O(2) tension vs. myocardial O(2) consumption was the same as during control exercise. Estimated interstitial adenosine concentration with glibenclamide was not different from control vehicle and was well below the level necessary to overcome the 10-fold shift in the adenosine dose-response curve due to glibenclamide. In conclusion, K(ATP)(+) channel blockade decreases the balance between resting coronary O(2) delivery and myocardial O(2) consumption, but K(ATP)(+) channels are not required for the increase in coronary blood flow during exercise. Furthermore, interstitial adenosine concentration does not increase to compensate for the loss of K(ATP)(+) channel function.

Published

2000