Vasodilator reactive oxygen species ameliorate perturbed myocardial oxygen delivery in exercising swine with multiple comorbidities.

Multiple common cardiovascular comorbidities produce coronary microvascular dysfunction. We previously observed in swine that a combination of diabetes mellitus (DM), high fat diet (HFD) and chronic kidney disease (CKD) induced systemic inflammation, increased oxidative stress and produced coronary endothelial dysfunction, altering control of coronary microvascular tone via loss of NO bioavailability, which was associated with an increase in circulating endothelin (ET). In the present study, we tested the hypotheses that (1) ROS scavenging and (2) ETA+B-receptor blockade improve myocardial oxygen delivery in the same female swine model. Healthy female swine on normal pig chow served as controls (Normal). Five months after induction of DM (streptozotocin, 3 × 50 mg kg-1 i.v.), hypercholesterolemia (HFD) and CKD (renal embolization), swine were chronically instrumented and studied at rest and during exercise. Sustained hyperglycemia, hypercholesterolemia and renal dysfunction were accompanied by systemic inflammation and oxidative stress. In vivo ROS scavenging (TEMPOL + MPG) reduced myocardial oxygen delivery in DM + HFD + CKD swine, suggestive of a vasodilator influence of endogenous ROS, while it had no effect in Normal swine. In vitro wire myography revealed a vasodilator role for hydrogen peroxide (H2O2) in isolated small coronary artery segments from DM + HFD + CKD, but not Normal swine. Increased catalase activity and ceramide production in left ventricular myocardial tissue of DM + HFD + CKD swine further suggest that increased H2O2 acts as vasodilator ROS in the coronary microvasculature. Despite elevated ET-1 plasma levels in DM + HFD + CKD swine, ETA+B blockade did not affect myocardial oxygen delivery in Normal or DM + HFD + CKD swine. In conclusion, loss of NO bioavailability due to 5 months exposure to multiple comorbidities is partially compensated by increased H2O2-mediated coronary vasodilation.

Questionnaire survey on cardiologists' view and management of coronary microvascular disease in clinical practice.

OBJECTIVE: We aimed to assess the opinion of Dutch cardiologists on coronary microvascular disease (CMD) and its management in clinical practice, and to assess the need for a CMD guideline among Dutch cardiologists. METHODS: We developed an online questionnaire including different aspects of CMD which was reviewed by an expert panel. The questionnaire was distributed by e­mail among all members of the Dutch Society of Cardiology. RESULTS: A total of 103 cardiologists (70% male) completed the questionnaire (response rate: 10%). Median age and years of experience as a cardiologist were 49 ± 15 and 12 ± 12 years, respectively. Overall, 93% of the cardiologists had considered the CMD diagnosis, 85% had ever made such a diagnosis, 90% had treated a patient with CMD, and 61% had referred patients to tertiary care. The median (interquartile range) self-rated knowledge level was 7.0 (2.0) (scale of 0-10). 84% rated their knowledge as sufficient (>5.5) and 58% viewed CMD as a disease entity. Overall, 61% and 17%, respectively, agreed that evidence-based diagnostic and treatment modalities for CMD do not exist, while 56% believed that CMD patients have a higher risk for cardiovascular disease and mortality. Finally, 82% of the responders stated that a CMD guideline is needed, and 91% wanted to receive the guideline once developed. DISCUSSION: Fifty-eight per cent of the responders recognise CMD as a separate disease entity. Our study underscores the need for a dedicated CMD guideline for Dutch cardiology practice. However, the response rate was low (10%), and it is likely that mainly cardiologists interested in CMD have participated in our study.

Animal models of heart failure with preserved ejection fraction.

Heart failure with preserved ejection fraction (HFpEF) constitutes a clinical syndrome in which the diagnostic criteria of heart failure are not accompanied by gross disturbances of systolic function, as assessed by ejection fraction. In turn, under most circumstances, diastolic function is impaired. Although it now represents over 50 % of all patients with heart failure, the mechanisms of HFpEF remain understood, precluding effective therapy. Understanding the pathophysiology of HFpEF has been restricted by both limited access to human myocardial biopsies and by the lack of animal models that fully mimic human pathology. Animal models are valuable research tools to clarify subcellular and molecular mechanisms under conditions where the comorbidities and other confounding factors can be precisely controlled. Although most of the heart failure animal models currently available represent heart failure with reduced ejection fraction, several HFpEF animal models have been proposed. However, few of these fulfil all the features present in human disease. In this review we will provide an overview of the currently available models to study HFpEF from rodents to large animals as well as present advantages and disadvantages of these models.

Peripheral arterial tonometry cannot detect patients at low risk of coronary artery disease.

BACKGROUND: Endothelial dysfunction precedes coronary artery disease (CAD) and can be measured by peripheral arterial tonometry (PAT). We examined the applicability of PAT to detect a low risk of CAD in a chest pain clinic. METHODS: In 93 patients, PAT was performed resulting in reactive hyperaemia (RHI) and augmentation (AIx) indices. Patients were risk classified according to HeartScore, Diamond and Forrester pretest probability (DF), exercise testing (X-ECG), and computed tomography calcium scoring (CCS) and angiography (CTA). Correlations, risk group differences and prediction of revascularisation within 1 year were calculated. RESULTS: RHI correlated with HeartScore (r = - 0.21, p = 0.05), AIx with DF (r = 0.26, p = 0.01). However, both were not significantly different between normal and ischaemic X-ECG groups. In addition RHI and AIx were similar between low risk as compared with intermediate-to-high risk, based on risk algorithms (RHI: 1.98 (0.67) vs 1.94 (0.78); AIx: 0.0 (21) vs 5.0 (25); p = NS), or CCS and CTA (RHI: 1.99 (0.58) vs 1.89 (0.82); AIx: - 2.0 (24) vs 4.0 (25); p = NS). Finally, RHI and AIx failed to predict revascularisation (RHI: OR 1.42, CI 0.65-3.1; AIx: OR 1.02, CI 0.98-1.05). CONCLUSIONS: PAT cannot detect a low risk of CAD, possibly because RHI and AIx versus X-ECG, CCS and CTA represent independent processes.

Cell transplantation for cardiac regeneration: where do we stand?

During the last decade transplantation of cells into the heart has emerged as a novel therapy for the prevention and treatment of heart failure. Although various cell types have been used, most experience has been obtained with the progenitor cells of skeletal muscle, also called myoblasts, and a wide array of bone marrow-derived cell types. The first preclinical studies demonstrated an improvement in global and regional heart function that was attributed mainly to a direct contractile effect of the transplanted cells. Furthermore, it was suggested that multiple cell types are able to form true cardiomyocytes and truly 'regenerate' the myocardium. More recent studies have questioned these early findings. Other mechanisms such as paracrine effects on the infarct and remote myocardium, a reduction in adverse remodelling and improvement of mechanical properties of the infarct tissue likely play a more important role. On the basis of encouraging preclinical studies, multiple early-phase clinical trials and several randomised controlled trials have been conducted that have demonstrated the feasibility, safety and potential efficacy of this novel therapy in humans. This review summarises the available evidence on cardiac cell transplantation and provides an outlook on future preclinical and clinical research that has to fill in the remaining gaps. (Neth Heart J 2008;16:88-95.).

Role of K+ ATP channels and adenosine in the regulation of coronary blood flow during exercise with normal and restricted coronary blood flow.

Regulation of coronary vasomotor tone during exercise is incompletely understood. We investigated the contributions of K+ ATP channels and adenosine to the coronary vasodilation that occurs during exercise in the normal heart and in the presence of a coronary artery stenosis. Dogs that were chronically instrumented with a Doppler flow probe, hydraulic occluder, and indwelling catheter on the left anterior descending coronary artery were exercised on a treadmill to produce heart rates of approximately 200 beats/min. By graded inflation of the occluder to produce a wide range of coronary stenosis severities, we determined the coronary pressure-flow relation. K+ atp channel blockade with intracoronary glibenclamide (10-50 microgram/kg per min) decreased coronary blood flow during exercise at coronary pressures within and below the autoregulatory range, indicating that coronary K+ ATP channel activation is critical for producing coronary vasodilation with either normal arterial inflow or when flow is restricted by a coronary artery stenosis. Adenosine receptor blockade with intravenous 8-phenyltheophylline (5 mg/kg) had no effect on coronary flow at pressures within the autoregulatory range but decreased flow at pressures < 55 mmHg. In contrast, in the presence of K+ ATP channel blockade, the addition of adenosine receptor blockade further decreased coronary flow even at coronary pressures in the autoregulatory range, indicating increased importance of the vasodilator influence of endogenous adenosine during exercise when K+ atp channels are blocked. Intracoronary adenosine (50 microgram/kg per min) increased coronary flow at perfusion pressures both within and below the autoregulatory range. In contrast, selective K+ ATP channel activation with intracoronary pinacidil (0.2-5.0 microgram/kg per min) increased flow at normal but not at lower coronary pressures (< 55 mmHg). This finding demonstrates that not all K+ ATP channels are activated during exercise at pressures in the autoregulatory range, but that most K+ ATP channels are recruited as pressures approach the lower end of the autoregulatory plateau. Thus, K+ ATP channels and endogenous adenosine play a synergistic role in maintaining vasodilation during exercise in normal hearts and distal to a coronary artery stenosis that results in myocardial hypoperfusion during exercise.

Endogenous adenosine mediates coronary vasodilation during exercise after K(ATP)+ channel blockade.

The mechanism of coronary vasodilation produced by exercise is not understood completely. Recently, we reported that blockade of vascular smooth muscle K(ATP)+ channels decreased coronary blood flow at rest, but did not attenuate the increments in coronary flow produced by exercise. Adenosine is not mandatory for maintaining basal coronary flow, or the increase in flow produced by exercise during normal arterial inflow, but does contribute to coronary vasodilation in hypoperfused myocardium. Therefore, we investigated whether adenosine opposed the hypoperfusion produced by K(ATP)+ channel blockade, thereby contributing to coronary vasodilation during exercise. 11 dogs were studied at rest and during exercise under control conditions, during intracoronary infusion of the K(ATP)+ channel blocker glibenclamide (50 micrograms/kg per min), and during intracoronary glibenclamide in the presence of adenosine receptor blockade. Glibenclamide decreased resting coronary blood flow from 45 +/- 5 to 35 +/- 4 ml/min (P < 0.05), but did not prevent exercise-induced increases of coronary flow. Glibenclamide caused an increase in myocardial oxygen extraction at the highest level of exercise with a decrease in coronary venous oxygen tension from 15.5 +/- 0.7 to 13.6 +/- 0.8 mmHg (P < 0.05). The addition of the adenosine receptor antagonist 8-phenyltheophylline (5 mg/kg intravenous) to K(ATP)+ channel blockade did not further decrease resting coronary blood flow but did attenuate the increase in coronary flow produced by exercise. This was accompanied by a further decrease of coronary venous oxygen tension to 10.1 +/- 0.7 mmHg (P < 0.05), indicating aggravation of the mismatch between oxygen demand and supply. These findings are compatible with the hypothesis that K+ATP channels modulate coronary vasomotor tone both under resting conditions and during exercise. However, when K(ATP)+ channels are blocked, adenosine released from the hypoperfused myocardium provides an alternate mechanism to mediate coronary vasodilation in response to increases in oxygen demand produced by exercise.

CECR1-mediated cross talk between macrophages and vascular mural cells promotes neovascularization in malignant glioma.

Glioblastomas (glioblastoma multiforme, GBM) are most malignant brain tumors characterized by profound vascularization. The activation of macrophages strongly contributes to tumor angiogenesis during GBM development. Previously, we showed that extracellular adenosine deaminase protein Cat Eye Syndrome Critical Region Protein 1 (CECR1) is highly expressed by M2-like macrophages in GBM where it defines macrophage M2 polarization and contributes to tumor expansion. In this study, the effect of CECR1 in macrophages on tumor angiogenesis was investigated. Immunohistochemical evaluation of GBM tissue samples showed that the expression of CECR1 correlates with microvascular density in the tumors, confirming data from the TCGA set. In a three-dimensional co-culture system consisting of human pericytes, human umbilical vein endothelial cells and THP1-derived macrophages, CECR1 knockdown by siRNA and CECR1 stimulation of macrophages inhibited and promoted new vessel formation, respectively. Loss and gain of function studies demonstrated that PDGFB mRNA and protein levels in macrophages are modulated by CECR1. The proangiogenic properties of CECR1 in macrophages were partially mediated via paracrine activation of pericytes by PDGFB-PDGFRß signaling. CECR1-PDGFB-PDGFRß cross-activation between macrophages and pericytes promoted pericyte migration, shown by transwell migration assay, and enhanced expression and deposition of periostin, a matrix component with proangiogenic properties. CECR1 function in (M2-like) macrophages mediates cross talk between macrophages and pericytes in GBM via paracrine PDGFB-PDGFRß signaling, promoting pericyte recruitment and migration, and tumor angiogenesis. Therefore, CECR1 offers a new portent target for anti-angiogenic therapy in GBM via immune modulation.

Alterations in myofilament function contribute to left ventricular dysfunction in pigs early after myocardial infarction.

Myocardial infarction (MI) initiates cardiac remodeling, depresses pump function, and predisposes to heart failure. This study was designed to identify early alterations in Ca2+ handling and myofilament proteins, which may contribute to contractile dysfunction and reduced beta-adrenergic responsiveness in postinfarct remodeled myocardium. Protein composition and contractile function of skinned cardiomyocytes were studied in remote, noninfarcted left ventricular (LV) subendocardium from pigs 3 weeks after MI caused by permanent left circumflex artery (LCx) ligation and in sham-operated pigs. LCx ligation induced a 19% increase in LV weight, a 69% increase in LV end-diastolic area, and a decrease in ejection fraction from 54+/-5% to 35+/-4% (all P<0.05), whereas cardiac responsiveness to exercise-induced increases in circulating noradrenaline levels was blunted. Endogenous protein kinase A (PKA) was significantly reduced in remote myocardium of MI animals, and a negative correlation (R=0.62; P<0.05) was found between cAMP levels and LV weight-to-body weight ratio. Furthermore, SERCA2a expression was 23% lower after MI compared with sham. Maximal isometric force generated by isolated skinned myocytes was significantly lower after MI than in sham (15.4+/-1.5 versus 19.2+/-0.9 kN/m2; P<0.05), which might be attributable to a small degree of troponin I (TnI) degradation observed in remodeled postinfarct myocardium. An increase in Ca2+ sensitivity of force (pCa50) was observed after MI compared with sham (DeltapCa50=0.17), which was abolished by incubating myocytes with exogenous PKA, indicating that the increased Ca2+ sensitivity resulted from reduced TnI phosphorylation. In conclusion, remodeling of noninfarcted pig myocardium is associated with decreased SERCA2a and myofilament function, which may contribute to depressed LV function. The full text of this article is available online at http://circres.ahajournals.org.

Time course and mechanism of myocardial catecholamine release during transient ischemia in vivo.

BACKGROUND: Elevated concentrations of norepinephrine (NE) have been observed in ischemic myocardium. We investigated the magnitude and mechanism of catecholamine release in the myocardial interstitial fluid (MIF) during ischemia and reperfusion in vivo through the use of microdialysis. METHODS AND RESULTS: In 9 anesthetized pigs, interstitial catecholamine concentrations were measured in the perfusion areas of the left anterior descending coronary artery (LAD) and the left circumflex coronary artery. After stabilization, the LAD was occluded for 60 minutes and reperfused for 150 minutes. During the final 30 minutes, tyramine (154 nmol. kg(-1). min(-1)) was infused into the LAD. During LAD occlusion, MIF NE concentrations in the ischemic region increased progressively from 1. 0+/-0.1 to 524+/-125 nmol/L. MIF concentrations of dopamine and epinephrine rose from 0.4+/-0.1 to 43.9+/-9.5 nmol/L and from <0.2 (detection limit) to 4.7+/-0.7 nmol/L, respectively. Local uptake-1 blockade attenuated release of all 3 catecholamines by >50%. During reperfusion, MIF catecholamine concentrations returned to baseline within 120 minutes. At that time, the tyramine-induced NE release was similar to that seen in nonischemic control animals despite massive infarction. Arterial and MIF catecholamine concentrations in the left circumflex coronary artery region remained unchanged. CONCLUSIONS: Myocardial ischemia is associated with a pronounced increase of MIF catecholamines, which is at least in part mediated by a reversed neuronal reuptake mechanism. The increase of MIF epinephrine implies a (probably neuronal) cardiac source, whereas the preserved catecholamine response to tyramine in postischemic necrotic myocardium indicates functional integrity of sympathetic nerve terminals.

Angiotensin-converting enzyme inhibition and angiotensin II type 1 receptor blockade prevent cardiac remodeling in pigs after myocardial infarction: role of tissue angiotensin II.

BACKGROUND: The mechanisms behind the beneficial effects of renin-angiotensin system blockade after myocardial infarction (MI) are not fully elucidated but may include interference with tissue angiotensin II (Ang II). METHODS AND RESULTS: Forty-nine pigs underwent coronary artery ligation or sham operation and were studied up to 6 weeks. To determine coronary angiotensin I (Ang I) to Ang II conversion and to distinguish plasma-derived Ang II from locally synthesized Ang II, (125)I-labeled and endogenous Ang I and II were measured in plasma and in infarcted and noninfarcted left ventricle (LV) during (125)I-Ang I infusion. Ang II type 1 (AT(1)) receptor-mediated uptake of circulating (125)I-Ang II was increased at 1 and 3 weeks in noninfarcted LV, and this uptake was the main cause of the transient elevation in Ang II levels in the noninfarcted LV at 1 week. Ang II levels and AT(1) receptor-mediated uptake of circulating Ang II were reduced in the infarct area at all time points. Coronary Ang I to Ang II conversion was unaffected by MI. Captopril and the AT(1) receptor antagonist eprosartan attenuated postinfarct remodeling, although both drugs increased cardiac Ang II production. Captopril blocked coronary conversion by >80% and normalized Ang II uptake in the noninfarcted LV. Eprosartan did not affect coronary conversion and blocked cardiac Ang II uptake by >90%. CONCLUSIONS: Both circulating and locally generated Ang II contribute to remodeling after MI. The rise in tissue Ang II production during angiotensin-converting enzyme inhibition and AT(1) receptor blockade suggests that the antihypertrophic effects of these drugs result not only from diminished AT(1) receptor stimulation but also from increased stimulation of growth-inhibitory Ang II type 2 receptors.

Nitric oxide inhibition impairs blood flow during exercise in hearts with a collateral-dependent myocardial region.

OBJECTIVES: We sought to determine the importance of nitric oxide (NO) production in maintaining coronary blood flow during exercise in hearts with collateral-dependent myocardium. BACKGROUND: Coronary collateral vessels demonstrate endothelium-mediated NO-dependent vasodilation in response to agonists such as acetylcholine. However, the contribution of endogenous NO production to maintaining vasodilation of coronary collateral vessels during exercise has not been previously studied. METHODS: Collateral vessel growth was induced in 13 chronically instrumented dogs by intermittent 2-min occlusions, followed by permanent occlusion of the left anterior descending coronary artery (LAD). One week after permanent LAD occlusion, myocardial blood flow was measured with microspheres during rest and treadmill exercise at 6.4 km/h at a 15% grade. Measurements were then repeated after blockade of NO production with N-nitro-L-arginine (LNNA) (20 mg/kg body weight intravenously). RESULTS: LNNA caused a 62 +/- 4% (mean +/- SEM) inhibition of the coronary vasodilation produced by acetylcholine. During rest conditions, LNNA caused a slight decrease in blood flow to the collateral region (p = NS), with no change in normal zone blood flow. During exercise, LNNA caused a decrease in mean blood flow to the collateral region (from 2.24 +/- 0.19 to 1.78 +/- 0.26 ml/min per g after LNNA, p < 0.05). This decrease resulted from a near doubling of the collateral vascular resistance (p < 0.05), with a trend toward an increase in small vessel resistance in the collateral zone. LNNA also reduced myocardial blood flow to the normal region during exercise (from 2.99 +/- 0.24 to 2.45 +/- 0.28 ml/min per g, p < 0.05) as the result of a 44 +/- 13% increase in coronary vascular resistance (p < 0.05). CONCLUSIONS: NO contributes to the maintenance of coronary collateral blood flow during exercise. In contrast to the normal heart, endogenous NO production also maintains blood flow in remote myocardial regions during exercise. These results suggest that control of blood flow during exercise in normal myocardium is altered by the presence of an occluded coronary artery.

Regulation of coronary vasomotor tone under normal conditions and during acute myocardial hypoperfusion.

Ischemia generally has been assumed to cause maximal vasodilation of the coronary resistance vessels. However, recent observations have demonstrated that during ischemia, the coronary microvessels can retain some degree of vasodilator reserve and remain responsive to vasoconstrictor stimuli. Traditional understanding of coronary blood flow regulation envisioned an array of resistance vessels that respond homogeneously to local myocardial metabolic needs. Although coronary arterioles (<100 microm) do respond to myocardial metabolic activity, recent studies have demonstrated that up to 40% of total coronary resistance resides in small arteries 100-400 microm in diameter. Vasoconstriction of these small arteries is capable of decreasing blood flow, but they are minimally responsive to the metabolic effects of the resultant flow reduction. The lack of metabolic vasoregulation of the resistance arteries explains, at least in part, the observation that myocardial ischemia does not predictably cause maximal resistance vessel dilation. In addition, vasoconstrictor influences can compete with metabolic vasodilator activity in coronary arterioles. These findings suggest that pharmacologic vasodilators acting at the microvascular level might be therapeutically useful in patients with ischemic heart disease. Unfortunately, when myocardial ischemia results from a flow-limiting coronary stenosis, nonselective pharmacologic vasodilation of the resistance vessels can worsen subendocardial ischemia by decreasing intravascular pressure to produce coronary steal and by worsening of stenosis severity. Selective dilation of small arteries in ischemic regions might have potential for enhancing blood flow. A critical property of an effective agent is that it not interfere with metabolic vasoregulation at the arteriole level, so that dilation of small arteries in adequately perfused regions would be countered by compensatory vasoconstriction of the arterioles to prevent coronary steal.

Autonomic control of cardiovascular performance and whole body O2 delivery and utilization in swine during treadmill exercise.

OBJECTIVE: The present study determined the role of the autonomic nervous system (ANS) in the regulation of systemic and pulmonary circulation and of O2 delivery and utilization in swine at rest and during graded treadmill exercise. METHODS: Instrumented swine (n = 12) were subjected to treadmill exercise (1-5 km/h) under control conditions and in the presence of single and combined beta-adrenergic, alpha-adrenergic and muscarinic (M) receptor blockade. RESULTS: Exercise produced a four-fold increase in body O2 consumption, due to a doubling of both cardiac output and the arterio-mixed-venous O2 content difference. The latter resulted from an increase in O2 extraction, from 45 +/- 1% at rest to 74 +/- 1% at 5 km/h, as the O2 carrying capacity [haemoglobin concentration (Hb)] increased by only approximately 10%. The increase in cardiac output resulted from a doubling of the heart rate and a small (< 10%) increase in stroke volume. The mean aortic pressure (MAP) was unchanged, implying a 50% decrease in systemic vascular resistance (P < or = 0.05). In contrast, exercise had no significant effect on pulmonary vascular resistance. The sympathetic division of the ANS controlled O2 delivery via beta-adrenoceptors (heart rate and contractility) and Hb concentration via alpha-adrenoceptor-mediated splenic contraction. In addition, the sympathetic division modulated systemic vascular tone via alpha- and beta-adrenoceptors, but also exerted a vasodilator influence on the pulmonary circulation via beta-adrenoceptors. The parasympathetic division controlled O2 delivery in part directly (heart rate) and in part indirectly via inhibition of beta-adrenoceptor activity (heart rate and contractility), even during heavy exercise. In addition, the parasympathetic division exerted a direct vasodilator influence on the pulmonary, but not on the systemic, circulation. CONCLUSIONS: Thus, in swine, in a manner similar to that in humans, both the sympathetic and parasympathetic division of the ANS contribute to cardiovascular homeostasis during exercise up to levels of high intensity.

Effect of inhibition of nitric oxide formation on coronary blood flow during exercise in the dog.

OBJECTIVE: The aim was to test the hypothesis that nitric oxide (or a related compound) contributes to the coronary vasodilatation during physiological increases of myocardial O2 consumption that occur with exercise. METHODS: Active hyperaemia associated with graded treadmill exercise and coronary reactive hyperaemia were examined in chronically instrumented awake dogs during control conditions and after administration of the nitric oxide synthase inhibitor, N-nitro-L-arginine (LNNA). RESULTS: LNNA blunted the response to intracoronary acetylcholine, with an 80(SEM 6)% decrease in the maximum acetylcholine induced coronary vasodilatation, but did not alter the response to sodium nitroprusside. Increases of myocardial oxygen requirements during treadmill exercise were associated with progressive increases of coronary blood flow. LNNA caused a significant increase in arterial pressure at rest and during exercise, and this was associated with slightly but significantly higher myocardial oxygen consumption. Coronary blood flow-during exercise was also slightly higher after LNNA, while coronary vascular resistance was unchanged. Coronary sinus PO2 was slightly but significantly lower during exercise after LNNA, indicating that coronary vasodilatation in response to the increased myocardial oxygen demands during exercise was slightly blunted by LNNA. LNNA did not alter the peak increase in blood flow during reactive hyperaemia following a 15 s coronary occlusion, but decreased the duration of the response and decreased reactive hyperaemia debt repayment from 300(56)% during control conditions to 182(36)% after LNNA (p < 0.01). CONCLUSIONS: LNNA antagonised coronary vasodilatation in response to acetylcholine and blunted coronary reactive hyperaemia, but did not substantially impair the coronary vasodilatation associated with increased myocardial oxygen requirements produced by exercise. These findings fail to support an essential role for nitric oxide in coronary resistance vessel dilatation during exercise in the dog.

Endogenous adenosine and coronary vasoconstriction in hypoperfused myocardium during exercise.

OBJECTIVE: The coronary circulation has been shown to remain responsive to vasodilator and vasoconstrictor stimuli during myocardial ischaemia. The aim of this study was to investigate whether endogenous adenosine attenuates coronary vasoconstriction caused by the thromboxane A2 analogue, U46619. METHODS: Nine chronically instrumented dogs were studied during treadmill exercise in the presence of a coronary stenosis which resulted in distal left circumflex coronary artery hypoperfusion. Myocardial blood flow was assessed with radioactive microspheres during exercise prior to and during intracoronary infusion of U46619 (0.01 microgram.kg-1 x min-1), in the absence and the presence of adenosine receptor blockade with intravenous 8-phenyltheophylline (5 mg.kg-1) and intracoronary adenosine deaminase (50 units.kg-1). Distal coronary pressure was maintained constant during the control stenosis and the three interventions, at 49(SEM 3), 50(3), 50(3), and 50(3) mm Hg. RESULTS: During control exercise mean myocardial blood flow was 0.91(0.09) ml.min-1 x g-1 in the stenosis region and 2.54(0.28) in the normal region. With no change in distal coronary pressure, U46619 decreased mean myocardial blood flow to 0.70(0.10) ml.min-1 x g-1 (p < 0.05). Adenosine blockade alone decreased myocardial blood flow in the stenosis region to 0.60(0.07) ml.min-1 x g-1 (p < 0.05 v control stenosis), indicating that endogenous adenosine contributed to coronary vasodilatation in the ischaemic region. However, adenosine blockade did not augment the vasoconstriction in response to U46619 [mean myocardial blood flow 0.49(0.05) ml.min-1 x g-1], indicating that endogenous adenosine did not attenuate the vasoconstriction caused by U46619. CONCLUSIONS: Endogenous adenosine contributed to dilatation of resistance vessels in hypoperfused myocardium of exercising dogs in the absence as well as in the presence of U46619. However, endogenous adenosine did not attenuate the magnitude of the vasoconstrictor response to U46619. These findings are best explained by observations that thromboxane A2 and adenosine act on coronary vascular segments of different size.

Nitric oxide contributes to the regulation of vasomotor tone but does not modulate O(2)-consumption in exercising swine.

OBJECTIVE: The role of nitric oxide (NO) in the regulation of vasomotor tone and tissue O(2)-consumption is incompletely understood. We therefore determined the contribution of endogenous NO to regulation of systemic, pulmonary and coronary vasomotor tone and myocardial (MV(O(2))) and whole body (BV(O(2))) O(2)-consumption in exercising swine. METHODS AND RESULTS: Exercise (1-5 km/h) up to 85% of maximum heart rate in 11 swine produced a 4-fold increase in BV(O(2)), which was accommodated for by 2-fold increases in both cardiac output (CO) and body O(2)-extraction. The NO synthase inhibitor N(omega)-nitro-L-arginine (NLA, 20 mg/kg, i.v.) increased mean aortic pressure by 30 mmHg both at rest and during exercise, due to a decrease in systemic vascular conductance from 37+/-2 to 22+/-1 ml/min mmHg(-1) at rest and from 88+/-3 to 60+/-3 ml/min mmHg(-1) at 5 km/h (all P< or =0.05 versus control). NLA produced vasoconstriction at rest and at 5 km/h in virtually all regional beds but did not affect the exercise-induced redistribution of CO. NLA increased mean pulmonary artery pressure from 15+/-1 to 21+/-1 mmHg at rest and from 30+/-2 to 40+/-2 mmHg at 5 km/h, due to a decrease in pulmonary vascular conductance (all P< or =0.05). BV(O(2)) remained unchanged and consequently the decrease in CO resulted in a compensatory increase in O(2)-extraction. NLA in a dose of 40 mg/kg produced similar responses. NLA had no significant effect on myocardial O(2)-demand or MV(O(2)) either at rest or during exercise, but decreased coronary vascular conductance which resulted in a decrease in coronary venous PO(2) from 24.5+/-1.1 to 21.9+/-0.8 mmHg at rest and from 23.5+/-0.5 to 21.0+/-0.6 mmHg at 5 km/h (all P< or =0. 05). CONCLUSIONS: Endogenous NO dilates the systemic, pulmonary and coronary vascular bed, but does not modify MV(O(2)) or BV(O(2)) in swine at rest and during exercise.

Endothelium dependent vasodilatation following brief ischaemia and reperfusion in anaesthetised swine.

STUDY OBJECTIVE: The aim as to compare the responses of intracoronary infusions of ATP, an endothelium dependent vasodilator, with adenosine following brief ischaemia (10 min) and reperfusion in a model of myocardial stunning. DESIGN: In group 1 (n = 6), coronary blood flow and endocardial (endo) and epicardial (epi) percent segment length shortening were measured in the distribution of the left anterior descending coronary artery before and during maximal intracoronary infusions of either adenosine or ATP (20 micrograms.kg-1.min-1). Measurements were obtained before and after myocardial stunning both at control heart rate and during atrial pacing (150 beats.min-1). In group 2 (n = 6), myocardial blood flows by microspheres and arterial-venous lactate and oxygen differences were determined following the same ischaemia-reperfusion protocol to characterise transmural changes in blood flow and metabolism in this model of stunning. EXPERIMENTAL MATERIAL: The experiments were done on 12 anaesthetised swine, weight 25-39 kg. MEASUREMENTS AND MAIN RESULTS: In group 1, baseline endo and epi segment length shortening were 16(SD 3)% and 14(6)% and following reperfusion were reduced to 10(4)% and 8(6)% respectively (p less than 0.05). Prior to stunning, minimal coronary resistances during adenosine and ATP were 0.81(0.40) and 0.76(0.25) mm Hg.min.ml-1 respectively and following reperfusion were 0.86(0.31) (NS) and 0.85(0.23) (NS) mm Hg.min.ml-1 respectively. Infusion of either vasodilator enhanced function by 30% following reperfusion whereas no such effect was observed prior to ischaemia. In group 2, no maldistribution of blood flow was observed following the same ischaemia-reperfusion protocol to account for this vasodilator enhancement in function. Percent lactate extraction values were 29(11)% and 25(14)% at preischaemic control and paced heart rates respectively, and following reperfusion were lowered to 0(12)% without pacing (p less than 0.05) and -1(34)% during pacing (p less than 0.05). CONCLUSIONS: Brief ischaemia and reperfusion in swine induces myocardial stunning without altering the vasodilator responses of either ATP, an endothelium dependent vasodilator, or adenosine. Recruitment in postischaemic segment length shortening was observed during infusions of both vasodilators at a time when maldistribution of flow was not observed. Possible mechanisms include either enhanced washout of lactate from the reperfused myocardium or greater utilisation of substrates during higher blood flows.

Dobutamine restores the reduced efficiency of energy transfer from total mechanical work to external mechanical work in stunned porcine myocardium.

OBJECTIVE: In order to determine whether the relatively high oxygen consumption of stunned myocardium is related to decreased mechanical efficiency, myocardial oxygen consumption (MVO2) and its major determinants were studied in 10 open chest anaesthetised pigs. METHODS: According to the time varying elastance concept, MVO2 is determined by contractility (Emax) and total mechanical work (PLA), which is the sum of the external work (EW) and potential energy (PE). Mechanical efficiency (EW/MVO2) equals the product of EW/PLA (= efficiency of energy transfer or EET) and PLA/MVO2. Emax is the slope of the end systolic pressure-segment length relationship, determined by gradually clamping the aorta. PLA is the area enclosed by the end systolic pressure-segment length relationship and the pressure-segment length trajectory. EW is the area of the pressure-segment length loop. Systemic haemodynamics, regional segment shortening, and MVO2 were determined at baseline, during stunning (two sequences of 10 min occlusion and 30 min of reperfusion), after a subsequent 50 beats.min-1 increase in heart rate by atrial pacing and additional infusion of 2 micrograms.kg-1.min-1 dobutamine. RESULTS: Stunning decreased segment shortening from 18.2(SEM 1.9)% to 10.2(1.5)%, MVO2 from 4.16(0.27) x 10(-2) to 2.84(0.25) x 10(-2) mumol.beat-1.g-1, and Emax from 47(9) to 23(3) mm Hg.mm-1 (all p < 0.05). PLA decreased by 13(4)%, as EW decreased by 42(6)%, and PE tended to increase. Although EET decreased from 0.58(0.04) to 0.40(0.03) (p < 0.05), there was no decrease in the mechanical efficiency, as an increase in PE caused an increase in PLA/MVO2 which compensated for the decrease in EET. Dobutamine infusion increased Emax and EW per beat to 120(23)% and 67(8)% of baseline, respectively, while MVO2 [4.12(0.53) mumol.beat-1.g-1] and EET [0.57(0.04)] returned to baseline. CONCLUSIONS: In stunned myocardium, mechanical efficiency is not decreased despite a decrease in EET. The increase in EET after dobutamine may explain the lack of the excessive increase in MVO2.