Characteristics of coronary blood flow and transmural distribution in miniature pigs

1978 ◽  
Vol 235 (5) ◽  
pp. H601-H609 ◽  
Author(s):  
M. Sanders ◽  
F. C. White ◽  
T. M. Peterson ◽  
C. M. Bloor
Keyword(s):  
Blood Flow ◽  
Coronary Blood Flow ◽  
Vascular Resistance ◽  
Perfusion Pressure ◽  
Oxygen Demand ◽  
Coronary Artery Occlusion ◽  
Adenosine Infusion ◽  
Myocardial Oxygen Demand ◽  
Heavy Exercise ◽  
Miniature Pigs

The relationship between phasic systolic and diastolic coronary blood flow and its transmural distribution has been studied in 29 Yucatan miniature pigs at rest and during heavy exercise, with and without adenosine infusion (1.5 mg . kg-1 . min-1) and with and without a subtotal coronary artery occlusion. Altered factors that affected coronary flow included vascular resistance, perfusion pressure, myocardial oxygen demand, and extra-vascular pressure. The data indicate that, at rest, endomural perfusion is significantly dependent on diastolic blood flow. However, the ability of the myocardial vessels to autoregulate during systole as well as during diastole was clearly shown with the use of adenosine infusion. This ability to regulate flow intrinsically appeared to transcend the endocardial dependency on diastolic perfusion under certain stressful conditions, e.g., during heavy exercise, when the diastolic duration was significantly reduced. Systolic transmural perfusion may then become a significant factor in meeting the blood flow demands of the myocardium. However, due to gradients in vascular resistance, perfusion pressure, and oxygen demand, the coronary reserve of the epicardium appears to be greater than that of the endocardium under any condition.

scholarly journals Pharmacotherapy of angina pectoris

1982 ◽  
Vol 63 (1) ◽  
pp. 34-39
Author(s):  
R. A. Camburg
Keyword(s):  
Coronary Artery Disease ◽  
Blood Flow ◽  
Coronary Artery ◽  
Angina Pectoris ◽  
Coronary Blood Flow ◽  
Oxygen Demand ◽  
Lipid Lowering ◽  
Myocardial Oxygen Demand ◽  
Artery Disease ◽  
Antianginal Drugs

The key to the normal functioning of the heart muscle is the delivery of metabolites to it with blood, primarily oxygen, corresponding to the needs. When the balance between the supply of oxygen to the heart and its demand is imbalanced, myocardial ischemia occurs. This condition is a central link in the pathogenesis of the so-called coronary or ischemic heart disease (IHD). In 8994% of patients with coronary artery disease, it is caused by atherosclerosis of the coronary arteries and aorta [15, 21, 26]. Regarding the pathogenetic treatment of chronic forms of coronary artery disease (CHD), namely angina pectoris, one should dwell on such points as the normalization of the psychoemotional sphere (tranquilizers), an increase in coronary blood flow and oxygen delivery (coronary active agents, -adrenoactivators), a decrease in myocardial oxygen demand (R -adrenergic blockers, cordarone, calcium antagonists), redistribution of coronary blood flow from non-ischemic zones to ischemic zones (-blockers), hemodynamic restructuring (nitrates), switching myocardial metabolism to a reserve anaerobic pathway (gliosiz, nonahlazine), effect on blood circulation antibiotics ). All these agents used for the treatment of angina pectoris are called antianginal drugs and in some cases can be combined with analgesics, cardiac glycosides, anticoagulants, antiarrhythmic, lipid-lowering and other drugs for the complex treatment of IBO.

Canine coronary vasodepressor responses to hypoxia are abolished by 8-phenyltheophylline

1989 ◽  
Vol 257 (4) ◽  
pp. H1043-H1048 ◽  
Author(s):  
H. M. Wei ◽  
Y. H. Kang ◽  
G. F. Merrill
Keyword(s):  
Blood Flow ◽  
Coronary Blood Flow ◽  
Vascular Resistance ◽  
Perfusion Pressure ◽  
Coronary Perfusion Pressure ◽  
Coronary Perfusion ◽  
Coronary Vascular Resistance ◽  
Systemic Hypoxia ◽  
Dose Dependent ◽  
Vasodepressor Response

Anesthetized randomsource mongrel dogs of either sex were instrumented to investigate the effects of 8-phenyltheophylline on changes in coronary perfusion pressure caused by systemic hypoxia under conditions of controlled constant coronary blood flow. In the absence of 8-phenyltheophylline, coronary perfusion pressure decreased from 98 +/- 10 to 69 +/- 4 mmHg (P less than 0.05) at the end of 3 min of systemic hypoxia [arterial partial pressure of oxygen (PO2) = 23 +/- 2 mmHg]. Calculated coronary vascular resistance decreased concomitantly by 30 +/- 5% (P less than 0.05). In the presence of continuously infused 8-phenyltheophylline, equally severe hypoxia increased coronary perfusion pressure from 112 +/- 10 to 129 +/- 13 mmHg (P less than 0.05). Under these conditions, calculated coronary vascular resistance increased 14 +/- 3% (P less than 0.05). Dose-dependent attenuation of the coronary vasodilator response to exogenous adenosine under normoxic conditions was produced by 8-phenyltheophylline. In vehicle-treated dogs, repeat bolus injections of adenosine consistently lowered coronary perfusion pressure by 45 +/- 15%. The vasodepressor response did not vary from one injection to the next. These data demonstrate that under conditions of controlled constant coronary blood flow, treatment with 8-phenytheophylline abolishes coronary vasodilation caused by systemic hypoxia.

Regulation of Coronary Blood Flow During Exercise

2008 ◽  
Vol 88 (3) ◽  
pp. 1009-1086 ◽  
Author(s):  
Dirk J. Duncker ◽  
Robert J. Bache
Keyword(s):  
Heart Rate ◽  
Blood Flow ◽  
Exercise Training ◽  
Coronary Blood Flow ◽  
Oxygen Demand ◽  
Myocardial Oxygen Demand ◽  
Coronary Collateral ◽  
Resistance Vessels ◽  
Exercise Induced ◽  
Collateral Vessels

Exercise is the most important physiological stimulus for increased myocardial oxygen demand. The requirement of exercising muscle for increased blood flow necessitates an increase in cardiac output that results in increases in the three main determinants of myocardial oxygen demand: heart rate, myocardial contractility, and ventricular work. The approximately sixfold increase in oxygen demands of the left ventricle during heavy exercise is met principally by augmenting coronary blood flow (∼5-fold), as hemoglobin concentration and oxygen extraction (which is already 70–80% at rest) increase only modestly in most species. In contrast, in the right ventricle, oxygen extraction is lower at rest and increases substantially during exercise, similar to skeletal muscle, suggesting fundamental differences in blood flow regulation between these two cardiac chambers. The increase in heart rate also increases the relative time spent in systole, thereby increasing the net extravascular compressive forces acting on the microvasculature within the wall of the left ventricle, in particular in its subendocardial layers. Hence, appropriate adjustment of coronary vascular resistance is critical for the cardiac response to exercise. Coronary resistance vessel tone results from the culmination of myriad vasodilator and vasoconstrictors influences, including neurohormones and endothelial and myocardial factors. Unraveling of the integrative mechanisms controlling coronary vasodilation in response to exercise has been difficult, in part due to the redundancies in coronary vasomotor control and differences between animal species. Exercise training is associated with adaptations in the coronary microvasculature including increased arteriolar densities and/or diameters, which provide a morphometric basis for the observed increase in peak coronary blood flow rates in exercise-trained animals. In larger animals trained by treadmill exercise, the formation of new capillaries maintains capillary density at a level commensurate with the degree of exercise-induced physiological myocardial hypertrophy. Nevertheless, training alters the distribution of coronary vascular resistance so that more capillaries are recruited, resulting in an increase in the permeability-surface area product without a change in capillary numerical density. Maintenance of α- and ß-adrenergic tone in the presence of lower circulating catecholamine levels appears to be due to increased receptor responsiveness to adrenergic stimulation. Exercise training also alters local control of coronary resistance vessels. Thus arterioles exhibit increased myogenic tone, likely due to a calcium-dependent protein kinase C signaling-mediated alteration in voltage-gated calcium channel activity in response to stretch. Conversely, training augments endothelium-dependent vasodilation throughout the coronary microcirculation. This enhanced responsiveness appears to result principally from an increased expression of nitric oxide (NO) synthase. Finally, physical conditioning decreases extravascular compressive forces at rest and at comparable levels of exercise, mainly because of a decrease in heart rate. Impedance to coronary inflow due to an epicardial coronary artery stenosis results in marked redistribution of myocardial blood flow during exercise away from the subendocardium towards the subepicardium. However, in contrast to the traditional view that myocardial ischemia causes maximal microvascular dilation, more recent studies have shown that the coronary microvessels retain some degree of vasodilator reserve during exercise-induced ischemia and remain responsive to vasoconstrictor stimuli. These observations have required reassessment of the principal sites of resistance to blood flow in the microcirculation. A significant fraction of resistance is located in small arteries that are outside the metabolic control of the myocardium but are sensitive to shear and nitrovasodilators. The coronary collateral system embodies a dynamic network of interarterial vessels that can undergo both long- and short-term adjustments that can modulate blood flow to the dependent myocardium. Long-term adjustments including recruitment and growth of collateral vessels in response to arterial occlusion are time dependent and determine the maximum blood flow rates available to the collateral-dependent vascular bed during exercise. Rapid short-term adjustments result from active vasomotor activity of the collateral vessels. Mature coronary collateral vessels are responsive to vasodilators such as nitroglycerin and atrial natriuretic peptide, and to vasoconstrictors such as vasopressin, angiotensin II, and the platelet products serotonin and thromboxane A2. During exercise, ß-adrenergic activity and endothelium-derived NO and prostanoids exert vasodilator influences on coronary collateral vessels. Importantly, alterations in collateral vasomotor tone, e.g., by exogenous vasopressin, inhibition of endogenous NO or prostanoid production, or increasing local adenosine production can modify collateral conductance, thereby influencing the blood supply to the dependent myocardium. In addition, vasomotor activity in the resistance vessels of the collateral perfused vascular bed can influence the volume and distribution of blood flow within the collateral zone. Finally, there is evidence that vasomotor control of resistance vessels in the normally perfused regions of collateralized hearts is altered, indicating that the vascular adaptations in hearts with a flow-limiting coronary obstruction occur at a global as well as a regional level. Exercise training does not stimulate growth of coronary collateral vessels in the normal heart. However, if exercise produces ischemia, which would be absent or minimal under resting conditions, there is evidence that collateral growth can be enhanced. In addition to ischemia, the pressure gradient between vascular beds, which is a determinant of the flow rate and therefore the shear stress on the collateral vessel endothelium, may also be important in stimulating growth of collateral vessels.

Autoregulation of gastric blood flow and oxygen uptake

1981 ◽  
Vol 241 (2) ◽  
pp. G143-G149
Author(s):  
L. Holm-Rutili ◽  
M. A. Perry ◽  
D. N. Granger
Keyword(s):  
Blood Flow ◽  
Oxygen Uptake ◽  
Arterial Pressure ◽  
Vascular Resistance ◽  
Perfusion Pressure ◽  
Venous Pressure ◽  
Oxygen Demand ◽  
Gastric Blood Flow ◽  
Oxygen Extraction ◽  
Sympathetic Denervation

The purpose of this study was to determine whether the ability of the stomach to autoregulate blood flow and oxygen uptake is altered by sympathetic denervation. Blood flow, oxygen extraction, local arterial pressure, and venous pressure were continuously monitored in sympathetically innervated and denervated autoperfused dog stomach preparations. As perfusion pressure was reduced in increments from 120 to 20 mmHg in innervated preparations, blood flow and oxygen uptake decreased while oxygen extraction and vascular resistance increased. Reductions in perfusion pressure in denervated preparations resulted in a decrease in blood flow, oxygen uptake, and vascular resistance, whereas oxygen extraction increased. The ability of the stomach to regulate blood flow and oxygen uptake was significantly improved after denervation, i.e., vascular resistance decreased and oxygen uptake remained relatively constant when arterial pressure was reduced. Oxygen uptake in denervated stomachs was generally higher than that in innervated stomachs. Autoregulation of gastric blood flow therefore appears to be improved by denervation. The better autoregulation observed after denervation may result either from a reduction in sympathetic tone and/or the increase in gastric oxygen demand.

Diaphragmatic perfusion heterogeneity during exercise with inspiratory resistive breathing

1990 ◽  
Vol 68 (5) ◽  
pp. 2177-2181 ◽  
Author(s):  
M. Manohar
Keyword(s):  
Blood Flow ◽  
Exercise Capacity ◽  
Vascular Resistance ◽  
Maximal Exercise ◽  
Perfusion Pressure ◽  
Work Of Breathing ◽  
Regional Distribution ◽  
Resistive Breathing ◽  
Exercise Induced

Regional distribution of diaphragmatic blood flow (Q; 15-microns-diam radionuclide-labeled microspheres) was studied in normal (n = 7) and laryngeal hemiplegic (LH; n = 7) ponies to determine whether the added stress of inspiratory resistive breathing during maximal exercise may cause 1) redistribution of diaphragmatic Q and 2) crural diaphragmatic Q to exceed that in maximally exercising normal ponies. LH-induced augmentation of already high exertional work of breathing resulted in diminished locomotor exercise capacity so that maximal exercise in LH ponies occurred at 25 km/h compared with 32 km/h for normal ponies. The costal and crural regions received similar Q in both groups at rest. However, exercise-induced increments in perfusion were significantly greater in the costal region of the diaphragm. At 25 km/h, costal diaphragmatic perfusion was 154 and 143% of the crural diaphragmatic Q in normal and LH ponies. At 32 km/h, Q in costal diaphragm of normal ponies was 136% of that in the crural region. Costal and crural diaphragmatic Q in LH ponies exercised at 25 km/h exceeded that for normal ponies but was similar to the latter during exercise at 32 km/h. Perfusion pressure for the three conditions was also similar. It is concluded that diaphragmatic perfusion heterogeneity in exercising ponies was preserved during the added stress of inspiratory resistive breathing. It was also demonstrated that vascular resistance in the crural and costal regions of the diaphragm in maximally exercised LH ponies remained similar to that in maximally exercising normal ponies.

Contribution of extravascular compression to reduction of maximal coronary blood flow

1992 ◽  
Vol 262 (1) ◽  
pp. H68-H77
Author(s):  
F. L. Abel ◽  
R. R. Zhao ◽  
R. F. Bond
Keyword(s):  
Blood Flow ◽  
Coronary Blood Flow ◽  
Coronary Flow ◽  
Perfusion Pressure ◽  
Left Ventricular Pressure ◽  
Coronary Perfusion Pressure ◽  
Left Ventricular ◽  
Ventricular Pressure ◽  
Coronary Perfusion ◽  
Storage Site

Effects of ventricular compression on maximally dilated left circumflex coronary blood flow were investigated in seven mongrel dogs under pentobarbital anesthesia. The left circumflex artery was perfused with the animals' own blood at a constant pressure (63 mmHg) while left ventricular pressure was experimentally altered. Adenosine was infused to produce maximal vasodilation, verified by the hyperemic response to coronary occlusion. Alterations of peak left ventricular pressure from 50 to 250 mmHg resulted in a linear decrease in total circumflex flow of 1.10 ml.min-1 x 100 g heart wt-1 for each 10 mmHg of peak ventricular to coronary perfusion pressure gradient; a 2.6% decrease from control levels. Similar slopes were obtained for systolic and diastolic flows as for total mean flow, implying equal compressive forces in systole as in diastole. Increases in left ventricular end-diastolic pressure accounted for 29% of the flow changes associated with an increase in peak ventricular pressure. Doubling circumferential wall tension had a minimal effect on total circumflex flow. When the slopes were extrapolated to zero, assuming linearity, a peak left ventricular pressure of 385 mmHg greater than coronary perfusion pressure would be required to reduce coronary flow to zero. The experiments were repeated in five additional animals but at different perfusion pressures from 40 to 160 mmHg. Higher perfusion pressures gave similar results but with even less effect of ventricular pressure on coronary flow or coronary conductance. These results argue for an active storage site for systolic arterial flow in the dilated coronary system.

scholarly journals Determinants of Cerebrovascular Reserve in Patients with Significant Carotid Stenosis

2020 ◽  
Author(s):  
Joseph P Archie
Keyword(s):  
Blood Flow ◽  
Cerebral Blood Flow ◽  
Carotid Artery ◽  
Carotid Stenosis ◽  
Vascular Resistance ◽  
Cerebral Perfusion ◽  
Perfusion Pressure ◽  
Systemic Arterial Pressure ◽  
Patient Specific ◽  
Flow Reserve

AbstractIntroductionIn patients with 70% to 99% diameter carotid artery stenosis cerebral blood flow reserve may be protective of future ischemic cerebral events. Reserve cerebral blood flow is created by brain auto-regulation. Both cerebral blood flow reserve and cerebrovascular reactivity can be measured non-invasively. However, the factors and variables that determine the availability and magnitude and of reserve blood flow remain poorly understood. The availability of reserve cerebral blood flow is a predictor of stroke risk. The aim of this study is to employ a hemodynamic model to predict the variables and functional relationships that determine cerebral blood flow reserve in patients with significant carotid stenosis.MethodsA basic one-dimensional, three-unit (carotid, collateral and brain) energy conservation fluid mechanics blood flow model is employed. It has two distinct but adjacent blood flow components with normal cerebral blood flow at the interface. In the brain auto-regulated blood flow component cerebral blood flow is maintained normal by reserve flow. In the brain pressure dependent blood flow component cerebral blood flow is below normal because cerebral perfusion pressure is below the lower threshold value for auto-regulation. Patient specific values of collateral vascular resistance are determined from a model solution using clinically measured systemic and carotid arterial stump pressures. Collateral vascular resistance curves illustrate the model solutions for reserve and actual cerebral blood flow as a function of percent diameter carotid artery stenosis and mean systemic arterial pressure. The threshold cerebral perfusion pressure value for auto-regulation is assumed to be 50 mmHg. Normal auto-regulated regional cerebral blood flow is assumed to be 50 ml/min/100g. Cerebral blood flow and reserve blood flow solutions are given for systemic arterial pressures of 80, 90, 100, 110 and 120 mmHg and for three patient specific collateral vascular resistance values, Rw = 1.0 (mean patient value), Rw = 0.5 (lower 1 SD) and Rd = 3.0 (upper 1 SD).ResultsReserve cerebral blood flow is only available when a patients cerebral perfusion pressure is in the normal auto-regulatory range. Both actual and reserve cerebral blood flows are primarily from the carotid circulation when carotid stenosis is less than 60% diameter. Between 60% and 75% stenosis the remaining carotid blood flow reserve is utilized and at higher degrees of stenosis all reserve flow is from the collateral circulation. The primary independent variables that determine actual and reserve cerebral blood flow are mean systemic arterial pressure, degree of carotid stenosis and patient specific collateral vascular resistance. Approximate 16% of patients have collateral vascular resistance greater than 5.0 and are predicted to be at high risk of cerebral ischemia or infarction with progression to severe carotid stenosis or occlusion. The approximate 50% of patients with a collateral vascular resistance less than 1.0 are predicted to have adequate cerebral blood flow with progression to carotid occlusion, and most maintain some reserve. Clinically measured values of cerebral blood flow reserve or cerebrovascular reactivity are predicted to be unreliable without consideration of systemic arterial pressure and degree of carotid stenosis. Reserve cerebral blood flow values measured in patients with only moderate 60% to 70% carotid stenosis are in general too high and variable to be of clinical value, but are most reliable when measured near 80% diameter stenosis and considered as percent of the maximum reserve blood flow. Patient specific measured reserve blood flow values can be inserted into the model to calculate the collateral vascular resistance.ConclusionsPredicting cerebral blood flow reserve in patients with significant carotid stenosis is complex and multifactorial. A simple cerebrovascular model predicts that patient specific collateral vascular resistance is an excellent predictor of reserve cerebral blood flow in patients with significant carotid stenosis. Cerebral blood flow reserve measurements are of limited value without accounting for systemic pressure and actual percent carotid stenosis. Asymptomatic patients with severe carotid artery stenosis and a collateral vascular resistance greater than 1.0 are at increased risk of cerebral ischemia and may benefit from carotid endarterectomy.

Myocardial blood flow and coronary reserve in chronically anemic fetal lambs

1999 ◽  
Vol 277 (1) ◽  
pp. R306-R313 ◽  
Author(s):  
Lowell E. Davis ◽  
A. Roger Hohimer ◽  
Mark J. Morton
Keyword(s):  
Blood Flow ◽  
Myocardial Blood Flow ◽  
Coronary Blood Flow ◽  
Coronary Flow ◽  
Adenosine Infusion ◽  
Fetal Sheep ◽  
Coronary Reserve ◽  
Flow Reserve ◽  
Coronary Conductance ◽  
The Difference

Chronic fetal anemia produces large compensatory increases in coronary blood flow in the near-term fetal lamb. To determine if increased coronary flow in anemic fetuses is associated with decreased coronary flow reserve or, alternatively, an increase in coronary conductance, we measured maximal coronary artery conductance during adenosine infusion before and during anemia. Isovolemic hemorrhage over 7 days reduced hematocrit from 30.6 ± 2.7 to 15.8 ± 2.4% ( P < 0.02) and the oxygen content from 7.3 ± 1.4 to 2.6 ± 0.4 ml/dl ( P < 0.001). Coronary blood flow increased from control (202 ± 60) to 664 ± 208 ml ⋅ min−1 ⋅ 100 g−1 with adenosine to 726 ± 169 ml ⋅ min−1 ⋅ 100 g−1 during anemia and to 1,162 ± 250 ml ⋅ min−1 ⋅ 100 g−1 (left ventricle) during anemia with adenosine infusion (all P< 0.001). Coronary conductance, determined during maximal vasodilation, was 18.2 ± 7.7 before and 32.8 ± 11.9 ml ⋅ min−1 ⋅ 100 g−1 ⋅ mmHg−1during anemia ( P < 0.001). Coronary reserve, the difference between resting and maximal myocardial blood flow interpolated at 40 mmHg, was unchanged in control and anemic fetuses (368 ± 142 and 372 ± 201 ml/min). Because hematocrit affects viscosity, anemic fetuses were transfused with blood to acutely increase the hematocrit back to control, and conductance was remeasured. Coronary blood flow decreased 57.3 ± 18.9% but was still 42.6 ± 18.9% greater than control. We conclude that in chronically anemic fetal sheep coronary conductance is increased and coronary reserve is maintained, and this is attributed in part to angiogenesis as well as changes in viscosity.

K+ATP channels and adenosine are not necessary for coronary autoregulation

1997 ◽  
Vol 273 (3) ◽  
pp. H1299-H1308 ◽  
Author(s):  
D. W. Stepp ◽  
K. Kroll ◽  
E. O. Feigl
Keyword(s):  
Carbon Dioxide ◽  
Blood Flow ◽  
Coronary Blood Flow ◽  
Left Main Coronary Artery ◽  
Perfusion Pressure ◽  
Carbon Dioxide Tension ◽  
Coronary Pressure ◽  
Adenosine Concentration ◽  
The Face

Autoregulation is defined as the intrinsic ability of an organ to maintain constant flow in the face of changing perfusion pressure. The present study evaluated the role of several potential mediators of coronary autoregulation: interstitial adenosine, ATP-sensitive K+ (K+ATP) channels, and myocardial oxygen and carbon dioxide tensions as reflected by coronary venous oxygen and carbon dioxide tensions. The left main coronary artery was cannulated, and blood was perfused at controlled pressures in closed-chest dogs. Interstitial adenosine concentration was estimated from arterial and venous adenosine concentrations with a previously described mathematical model. Autoregulation of coronary blood flow was observed between 100 and 60 mmHg. Glibenclamide, an inhibitor of K+ATP channels, reduced coronary blood flow by 19% at each perfusion pressure, but autoregulation was preserved. After stepwise reductions in coronary pressure to values > or = 70 mmHg, adenosine concentrations did not increase above basal levels. Adenosine concentration was elevated at 60 mmHg, suggesting a role for adenosine at the limit of coronary autoregulation. Adenosine is not required because glibenclamide, an inhibitor of adenosine-mediated vasodilation, did not reduce autoregulation or increase adenosine concentration. Coronary venous oxygen and carbon dioxide tensions were little changed during autoregulation before the inhibition of K+ATP channels and adenosine vasodilation with glibenclamide. However, coronary venous carbon dioxide tension rose progressively with decreasing coronary pressure after glibenclamide. The increase in carbon dioxide indirectly suggests that carbon dioxide-mediated vasodilation compensated for the loss of K+ATP-channel function. In summary, neither K+ATP channels nor adenosine is necessary to maintain coronary flow in the autoregulatory range of coronary arterial pressure from 100 to 60 mmHg.

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