Cardiovascular response to closed-loop intraneural stimulation of the right vagus nerve: a proof-of-concept study.

Vagus nerve stimulation (VNS) is an FDA-approved technique for the neuromodulation of the autonomic nervous system. There are many therapeutic applications where VNS could be used as a therapy, such as cardiovascular diseases, epilepsy, depression, and inflammatory conditions. Cardiovascular applications are particularly relevant, since cardiovascular diseases are the top causes of death worldwide. VNS clinical trials have been performed in the last 15 years for the treatment of heart failure (HF), achieving controversial results. Typically VNS is applied with a cuff electrode placed around the nerve, in an open-loop or cardiac synchronized design. The effectiveness of this approach is hindered by the multifunctional nature of the VN, which is involved in a variety of homeostatic controls. When a high current is applied, adverse effects arise from the stimulation of undesired fibers. An alternative strategy is represented by intraneural stimulation, which can guarantee higher selectivity. Moreover, closed-loop modalities allow the delivery of electrical current inside the nerves only if needed, with a reduced risk of untargeted nerve activation and lower energy consumption. Here we propose a closed-loop intraneural stimulation of the right cervical VN in a clinically relevant animal model. The intraneural was designed according to the internal structure of the VN. A threshold-based closed-loop algorithm was developed using HR as a control variable to produce a chronotropic effect.Clinical Relevance-This work analyzes the closed-loop intraneural VNS for the treatment of cardiovascular disorders, and supports the possibility of developing fully implantable devices with a high degree of selectivity in stimulation and prolonged lifespan.

Animal models of dilated cardiomyopathy for translational research.

Animal models of cardiovascular disease have proved critically important for the discovery of pathophysiological mechanisms and for the advancement of diagnosis and therapy. They offer a number of advantages, principally the availability of adequate healthy controls and the absence of confounding factors such as marked differences in age, concomitant pathologies and pharmacological treatments. Dilated cardiomyopathy (DCM) is the third cause of heart failure (HF) and is characterized by progressive ventricular dilation and functional impairment in the absence of coronary lesions and/or hypertension. Over the past thirty years, investigators have developed numerous small and large animal models to study this very complex syndrome. Genetically modified mice are the most widely and intensively utilized research animals and allow high throughput studies on DCM. However, to translate discoveries from basic science into medical applications, research in large animal models becomes a necessary step. An accurate large animal model of DCM is pacing-induced HF. It is obtained by continuous cardiac pacing at a frequency three- to fourfold higher than the spontaneous heart rate and is mostly applied to dogs, but also to pigs, sheep and monkeys. To date, this model can still be considered a gold standard in HF research.

Fatty acids are important for the Frank-Starling mechanism and Gregg effect but not for catecholamine response in isolated rat hearts.

In some pathophysiological conditions myocardial metabolism can switch from mainly long chain fatty acid (LCFA) oxidation to mainly glucose oxidation. Whether the predominant fatty acid or glucose oxidation affects cardiac performance has not been defined. In a buffer perfused isovolumetrically contracting rat heart, oxidation of endogenous pool LCFA was avoided by inhibiting carnitine-palmitoyl-transferase I (CPT-I) with oxfenicine (2 mM). In order to restore fatty acid oxidation, hexanoate (1 mM), which bypasses CPT-I inhibition, was added to the perfusate. Three groups of hearts were subjected to either an increase in left ventricular volume (VV, +25%) or an increase in coronary flow (CF, +50%), or inotropic stimulation with isoproterenol (10(-8) and 10(-6) m). The increase in VV (the Frank-Starling mechanism) increased rate-pressure product (RPP) by 21 +/- 2% under control conditions, but only by 6 +/- 2% during oxfenicine-induced CPT-I inhibition. The contractile response to changes in VV recovered after the addition of hexanoate. Similar results were obtained in hearts, in which an increase in CF was elicited (the Gregg phenomenon). Isoproterenol caused a similar increase in contractility regardless of the presence of oxfenicine or hexanoate. In all groups, a commensurate increase in oxygen consumption accompanied the increase in contractility. The fatty acid oxidation is necessary for an adequate contractile response of the isolated heart to increased pre-load or flow, whereas the inotropic response to adrenergic beta-receptor stimulation is insensitive to changes in substrate availability.

Nitric oxide-mediated arteriolar dilation after endothelial deformation.

Previously, we frequently observed dilation of arterioles after agonist-induced constrictions. We hypothesized that deformation of the endothelium during decreases in diameter of isolated arterioles elicits the release of nitric oxide (NO). In isolated arterioles of rat mesentery, phenylephrine (PE, 10(-7) M)-, U-46619 (10(-7) M)-, and KCl (50 mM)-induced constrictions were followed by potent dilations. Inhibition of NO synthase with N(omega)-nitro-L-arginine (L-NNA, 2 x 10(-4) M) or removal of the endothelium significantly enhanced constriction and reduced the postconstriction dilation. In the presence of 80 mmHg of intraluminal pressure, an increase in extraluminal pressure (P(e)) to 75 mmHg for 20 s and 1 and 2 min decreased vessel diameter. After release of P(e), arterioles dilated as a function of the duration of diameter reduction by P(e). Removal of the endothelium or administration of L-NNA significantly diminished the post-P(e) dilations. In cultured mesenteric arteriolar endothelial cells (EC), PE, U-46619, or KCl did not increase, whereas ACh did increase, the production of NO, as measured by a fluorometric assay for nitrite. Furthermore, when EC, cultured on a stretched silicone membrane, were subjected to deformation by shortening the membrane to 50% of its original length, NO release increased significantly. Based on all of the above, we propose that deformation of EC per se elicits release of NO, a mechanism that modulates arteriolar constriction.

In vitro system to study realistic pulsatile flow and stretch signaling in cultured vascular cells.

We developed a novel real-time servo-controlled perfusion system that exposes endothelial cells grown in nondistensible or distensible tubes to realistic pulse pressures and phasic shears at physiological mean pressures. A rate-controlled flow pump and linear servo-motor are controlled by digital proportional-integral-derivative feedback that employs previously digitized aortic pressure waves as a command signal. The resulting pressure mirrors the recorded waveform and can be digitally modified to yield any desired mean and pulse pressure amplitude, typically 0-150 mmHg at shears of 0.5-15 dyn/cm(2). The system accurately reproduces the desired arterial pressure waveform and cogenerates physiological flow and shears by the interaction of pressure with the tubing impedance. Rectangular glass capillary tubes [1-mm inside diameter (ID)] are used for real-time fluorescent imaging studies (i. e., pH(i), NO, Ca(2+)), whereas silicon distensible tubes (4-mm ID) are used for more chronic (i.e., 2-24 h) studies regarding signal transduction and gene expression. The latter have an elastic modulus of 12.4. 10(6) dyn/cm(2) similar to in vivo vessels of this size and are studied with the use of a benchtop system. The new approach provides the first in vitro application of realistic mechanical pulsatile forces on vascular cells and should facilitate studies of phasic shear and distension interaction and pulsatile signal transduction.

NO metabolites accumulate in erythrocytes in proportion to carbon dioxide and bicarbonate concentration.

It is not known whether the ratio between the concentrations of NO metabolites (NOx) in plasma (pNOx) and in erythrocytes (eNOx) is constant or correlates with chemical parameters of the blood. We measured pH, PO(2), and PCO(2) and calculated bicarbonate concentration in 19 blood samples from the aorta, coronary sinus, and leg veins of 7 dogs. Erythrocytes were then separated by centrifugation and lysed with distilled water, and the lysate was ultrafiltered with a molecular cutoff of 50 kDa to remove the hemoglobin. NOx were measured in plasma and in the ultrafiltrate. NOx concentration was higher in erythrocytes, with eNOx/pNOx ranging from 4.38 to 14.60. Linear and significant correlations were found between the natural logarithm of eNOx/pNOx and PCO(2) (r = 0.70, P < 0.001) or bicarbonate concentration (r = 0.72, P < 0.001). These results demonstrate, for the first time, that plasma NOx cannot be considered as a constant fraction of the total NOx in blood but varies dramatically in proportion to the CO(2)/bicarbonate concentration. To prevent an underestimation of venous-arterial difference of NOx across organs, NOx should be measured in whole blood.

Myocardial glucose uptake is regulated by nitric oxide via endothelial nitric oxide synthase in Langendorff mouse heart.

Although the role of nitric oxide (NO) in the modulation of vascular tone has been studied and well understood, its potential role in the control of myocardial metabolism is only recently evident. Several lines of evidence indicate that NO regulates myocardial glucose metabolism; however, the details and mechanisms responsible are still unknown. The aim of this study was to further define the role of NO in the control of myocardial glucose metabolism and the nitric oxide synthase (NOS) isoform responsible using transgenic animals lacking endothelial NOS (ecNOS). In the present study, we examined the regulation of myocardial glucose uptake using isometrically contracting Langendorff-perfused hearts from normal mice (C57BL/6J), mice with defects in the expression of ecNOS [ecNOS (-/-)], and its heterozygote [ecNOS (+/-)], and wild-type mice [ecNOS (+/+)] (n=6, respectively). In hearts from normal mice, little myocardial glucose uptake was observed. This myocardial glucose uptake increased significantly in the presence of N(omega)-nitro-L-arginine methyl ester (L-NAME). Similarly, in the hearts from ecNOS (-/-), glucose uptake was much greater than in normal mice, whereas myocardial glucose uptake of ecNOS (+/-) and ecNOS (+/+) mice was not different from normal mice. In addition, myocardial glucose uptake of ecNOS (+/-) and ecNOS (+/+) mice increased significantly in the presence of L-NAME. At a workload of 800 g. beats/min, L-NAME increased glucose uptake from 0.1+/-0.1 to 3+/-0.4 microg/min x mg in ecNOS (+/-) mice and from 0.2+/-0.1 to 2.7+/-0.7 microg/min x mg in ecNOS (+/+) mice. Furthermore, in the hearts from ecNOS (-/-) mice, 8-bromoguanosine 3':5'-cyclic monophosphate (8-Br-cGMP), a cGMP analog or S-nitroso-N-acetylpenicillamine (SNAP), a NO donor essentially shut off glucose uptake, and in hearts from ecNOS (+/-) mice, 1H-[1,2,4]oxadiazolo[4,3,-a]quinoxalin-1-one (ODQ), an inhibitor of cGMP, increased the glucose uptake significantly. These results indicate clearly that cardiac NO production regulates myocardial glucose uptake via a cGMP-dependent mechanism and strongly suggest that ecNOS plays a pivotal role in this regulation. These findings may be important in the understanding of the pathogenesis of the diseases such as ischemic heart disease, heart failure, diabetes mellitus, hypertension, and hypercholesterolemia, in which NO synthesis is altered and substrate utilization by the heart changes.

Cytokines are not a requisite part of the pathophysiology leading to cardiac decompensation.

An increase in circulating levels of proinflammatory cytokines has been proposed as an important pathogenic factor contributing to cardiac injury during chronic heart failure. To determine whether plasma levels of the cytokines tumor necrosis factor-alpha (TNF-alpha) and interleukin-6 (IL-6) increase during pacing-induced heart failure, we paced the hearts of seven dogs at 210 beats/min for 3 weeks and at 240 beats/min for an additional week to induce severe clinical signs of cardiac decompensation. Hemodynamic measurements and blood samples from the aorta and coronary sinus (CS) were taken at control, at 3 weeks, and in end-stage failure. Decompensated heart failure occurred at 29 +/- 1.8 days, when left ventricular (LV) end-diastolic pressure was 25 +/- 1.3 mmHg, LV systolic pressure was 92 +/- 4 mmHg, mean arterial pressure was 77 +/- 3 mmHg, and dP/dtmax was 1219 +/- 73 (all P < 0.05 vs control). Arterial concentration of IL-6 was 12 +/- 4.0 U/ml at control, 11 +/- 2.7 U/ml at 3 weeks, and 10 +/- 1.7 U/ml in end-stage failure (NS). At the same time points, IL-6 in CS plasma was 12 +/- 3.5, 13 +/- 2.8 and 11 +/- 2.4 U/ml, respectively (NS vs control and vs arterial concentrations). TNF-alpha did not reach detectable concentrations in arterial or CS blood at any time. TNF-alpha and IL-6 concentrations did not increase in arterial blood, were not released in the CS from the heart during the development of pacing-induced heart failure, and can not universally be implicated in the pathogenesis of all forms of cardiac dysfunction. Our findings are consistent with other data from patients in which severe heart failure was not associated with increased levels of circulating cytokines.

Bovine polymerized hemoglobin increases cardiac oxygen consumption and alters myocardial substrate metabolism in conscious dogs: role of nitric oxide.

We investigated the effect of bovine polymerized hemoglobin-based oxygen carrying (HBOC) solution on myocardial oxygen consumption (MVO2) and substrate use. At 15 min after the end of HBOC infusion (20% blood volume, i.v.) in nine permanently instrumented conscious dogs, mean arterial pressure and coronary blood flow were both increased by 41+/-5% and 93+/-20% (p<0.01) without affecting late diastolic coronary resistance and left ventricular dP/dtmax. Administration of HBOC did not affect arterial PO2 or O2 content, but significantly decreased coronary sinus PO2 and O2 content by 21+/-3% and 36+/-3%, respectively. MVO2 was increased from 7.2+/-0.8 to 15+/-1.8 ml O2/min (p<0.01). Despite an increase in triple product from 44+/-2 to 56+/-3 (p<0.01) 15 min after HBOC, the ratio of MVO2 and triple product was markedly elevated by 62+/-19%. Myocardial free fatty acid consumption was decreased from 14+/-1 to 4.5+/-2.2 microEq/min, whereas consumption of lactate increased from 19+/-6 to 69+/-10 micromol/ min and that of glucose increased from 1.0+/-0.5 to 10+/-3 mg/min (all p values, <0.05). These metabolic changes were not observed in dogs that received angiotensin II at a dose used (20-40 ng/kg/min, i.v.) to match those hemodynamic effects of HBOC. These results suggest that administration of HBOC increases coronary blood flow and MVO2 and shifts cardiac metabolism from using free fatty acid to using lactate and glucose in conscious dogs at rest. These metabolic changes are independent of the HBOC-induced change in hemodynamics.

Specificity of synergistic coronary flow enhancement by adenosine and pulsatile perfusion in the dog.

1. Coronary flow elevation from enhanced perfusion pulsatility is synergistically amplified by adenosine. This study determined the specificity of this interaction and its potential mechanisms. 2. Mean and phasic coronary flow responses to increasing pulsatile perfusion were assessed in anaesthetized dogs, with the anterior descending coronary artery servoperfused to regulate real-time physiological flow pulsatility at constant mean pressure. Pulsatility was varied between 40 and 100 mmHg. Hearts ejected into the native aorta whilst maintaining stable loading. 3. Increasing pulsatility elevated mean coronary flow +11.5 +/- 1.7 % under basal conditions. Co-infusion of adenosine sufficient to raise baseline flow 66 % markedly amplified this pulsatile perfusion response (+82. 6 +/- 14.3 % increase in mean flow above adenosine baseline), due to a leftward shift of the adenosine-coronary flow response curve at higher pulsatility. Flow augmentation with pulsatility was not linked to higher regional oxygen consumption, supporting direct rather than metabolically driven mechanisms. 4. Neither bradykinin, acetylcholine nor verapamil reproduced the synergistic amplification of mean flow by adenosine and higher pulsatility, despite being administered at doses matching basal flow change with adenosine. 5. ATP-sensitive potassium (KATP) activation (pinacidil) amplified the pulse-flow response 3-fold, although this remained significantly less than with adenosine. Co-administration of the phospholipase A2 inhibitor quinacrine virtually eliminated adenosine-induced vasodilatation, yet synergistic interaction between adenosine and pulse perfusion persisted, albeit at a reduced level. 6. Thus, adenosine and perfusion pulsatility specifically interact to enhance coronary flow. This synergy is partially explained by KATP agonist action and additional non-flow-dependent mechanisms, and may be important for modulating flow reserve during exercise or other high output states where increased flow demand and higher perfusion pulsatility typically co-exist.

Sustained vessel dilation induced by increased pulsatile perfusion of porcine carotid arteries in vitro.

Arterial pulse pressure (PP) increases with exertional stress and ageing, and can modify vessel diameter in smaller vessels. To test if PP must exceed a certain range to influence vessel diameter, and determine if such effects are endothelium-dependent or intrinsic to vascular viscoelasticity, eight fresh excised porcine carotid artery segments were perfused with modified Krebs-Henseleit by a servo-controlled system generating physiological arterial pressure waveforms. In a separate group of vessels (n = 10), the endothelium was mechanically removed. Vessel external diameter was measured by video edge-detection. Vessels partially preconstricted with noradrenaline were perfused at 9 mL min(-1) mean flow, at mean pressure of 90 or 120 mmHg, and zero PP. PP alone was then increased to 40, 70, or 120 mmHg at 1 Hz cycling rate for 5 min, then returned to zero and vessel diameter measured immediately thereafter. The protocol was repeated after 10-20 min stabilization. Mean vessel diameter rose proportionally with PP only once PP exceeded 40 mmHg, with maximal increases of 6-9% at a PP of 120 mmHg. Similar responses were obtained in vessels with and without a functional endothelium, at both mean pressures. Thus, when exposed to higher than normal resting PP, conduit arteries dilate owing to the stress-relaxation response of their viscoelastic wall. This mechanism of PP-mediated vascular dilatation may contribute to enhanced organ perfusion when small resistance arteries are already dilated.

Kinin-mediated coronary nitric oxide production contributes to the therapeutic action of angiotensin-converting enzyme and neutral endopeptidase inhibitors and amlodipine in the treatment in heart failure.

Increasing evidence suggests that angiotensin-converting enzyme (ACE) inhibitors can increase vascular nitric oxide (NO) production. Recent studies have found that combined inhibition of ACE and neutral endopeptidase (NEP) may have a greater beneficial effect in the treatment of heart failure than inhibition of ACE alone. Amlodipine, a calcium channel antagonist, has also been reported to have a favorable effect in the treatment of patients with cardiac dysfunction. The purpose of this study was to determine whether and the extent to which all of these agents used in the treatment of heart failure stimulate vascular NO production. Heart failure was induced by rapid ventricular pacing in conscious dogs. Coronary microvessels were isolated from normal and failing dog hearts. Nitrite, the stable metabolite of NO, was measured by the Griess reaction. ACE and NEP inhibitors and amlodipine significantly increased nitrite production from coronary microvessels in both normal and failing dog hearts. However, nitrite release was reduced after heart failure. For instance, the highest concentration of enalaprilat, thiorphan, and amlodipine increased nitrite release from 85 +/- 4 to 156 +/- 9, 82 +/- 7 to 139 +/- 8, and 74 +/- 4 to 134 +/-10 pmol/mg (all *p <.01 versus control), respectively, in normal dog hearts. Nitrite release in response to the highest concentration of these two inhibitors and amlodipine was reduced by 41% and 31% and 32% (all #p <.01 versus normal), respectively, in microvessels after heart failure. The increase in nitrite induced by either ACE or NEP inhibitors or amlodipine was entirely abolished by Nw-nitro-L-arginine methyl ester, HOE 140 (a B2-kinin receptor antagonist), and dichloroisocoumarin (a serine protease inhibitor) in both groups. Our results indicate that: 1) there is an impaired endothelial NO production after pacing-induced heart failure; 2) both ACE and NEP are largely responsible for the metabolism of kinins and modulate canine coronary NO production in normal and failing heart; and 3) amlodipine releases NO even after heart failure and this may be partly responsible for the favorable effect of amlodipine in the treatment of heart failure. Thus, the restoration of reduced coronary vascular NO production may contribute to the beneficial effects of these agents in the treatment of heart failure.

Nitric oxide controls cardiac substrate utilization in the conscious dog.

OBJECTIVES: The aim of this study was to determine whether the acute inhibition of nitric oxide (NO) synthase causes changes in cardiac substrate utilization which can be reversed by a NO donor. METHODS: NO synthase was blocked by giving 30 mg/kg of nitro-L-arginine (NLA) i.v. to 15 chronically instrumented dogs. Hemodynamics and blood samples from aorta and coronary sinus were taken at control and at 1 and 2 h after NLA. In five dogs, 0.4 mg/kg of the NO donor 3754 was given i.v. 1 h after NLA. In six dogs, angiotensin II was infused over 2 h (20-40 ng/kg/min) to mimic the hemodynamic effects of NLA. RESULTS: Two h after NLA: mean arterial pressure was 153 +/- 4 mmHg; MVO2 increased by 38%; cardiac uptake of lactate and glucose increased, respectively, from 20.0 +/- 5.0 to 41.0 +/- 9.3 mumol/min and from 1.1 +/- 0.7 to 6.8 +/- 1.5 mg/min (all P < 0.05 vs. control). Cardiac uptake of free fatty acids decreased by 43% after 1 h (P < 0.05) and returned to control values at 2 h. Cardiac respiratory quotient increased from 0.76 +/- 0.03 to 1.05 +/- 0.07, indicating a shift to carbohydrate oxidation. All these changes were reversed by the NO donor. In the dogs receiving angiotensin II infusion, MVO2 increased by 28% and lactate uptake doubled (both P < 0.05), but no other metabolic changes where observed. CONCLUSIONS: The acute inhibition of NO synthase by NLA causes a switch from fatty acids to lactate and glucose utilization by the heart which can be reversed by a NO donor, suggesting an important regulatory action of NO on cardiac metabolism.

Reduced nitric oxide production and altered myocardial metabolism during the decompensation of pacing-induced heart failure in the conscious dog.

The aim of the present study was to determine whether cardiac nitric oxide (NO) production changes during the progression of pacing-induced heart failure and whether this occurs in association with alterations in myocardial metabolism. Dogs (n=8) were instrumented and the heart paced until left ventricular end-diastolic pressure reached 25 mm Hg and clinical signs of severe failure were evident. Every week, hemodynamic measurements were recorded and blood samples were withdrawn from the aorta and the coronary sinus for measurement of NO metabolites, O2 content, free fatty acids (FFAs), and lactate and glucose concentrations. Cardiac production of NO metabolites or consumption of O2 or utilization of substrates was calculated as coronary sinus-arterial difference times coronary flow. In end-stage failure, occurring at 29+/-1.6 days, left ventricular end-diastolic pressure was 25+/-1 mm Hg, left ventricular systolic pressure was 92+/-3 mm Hg, mean arterial pressure was 75+/-2.5 mm Hg, and dP/dtmax was 1219+/-73 mm Hg/s (all P<0.05). These changes in hemodynamics were associated with a fall of cardiac NO metabolite production from 0.37+/-0.16 to -0.28+/-0.13 nmol/beat (P<0.05). O2 consumption and lactate uptake did not change significantly from control, while FFA uptake decreased from 0.16+/-0.03 to 0.05+/-0.01 microEq/beat and glucose uptake increased from -2.3+/-7.0 to 41+/-10 microgram/beat (P<0.05). The cardiac respiratory quotient also increased significantly by 28%. In 14 normal dogs the same measurements were performed at control and 1 hour after we injected 30 mg/kg of nitro-L-arginine, a competitive inhibitor of NO synthase .O2 consumption increased from 0.05+/-0.002 mL/beat at control to 0.071+/-0.003 mL/beat after nitro-L-arginine, while FFA uptake decreased from 0.1+/-0.01 to 0.06+/-0.01 microEq/beat, lactate uptake increased from 0.15+/-0.04 to 0.31+/-0.03 micromol/beat, glucose uptake increased from 8.2+/-5.0 to 35.4+/-9.5 microgram/beat, and RQ increased by 23% (all P<0.05). Our results indicate that basal cardiac production of NO falls below normal levels during cardiac decompensation and that there are shifts in substrate utilization. This switch in myocardial substrate utilization also occurs after acute pharmacological blockade of NO production in normal dogs.

Pulse pressure-related changes in coronary flow in vivo are modulated by nitric oxide and adenosine.

Acute increases in arterial pulsatile load imposed on the left ventricle can increase coronary flow without commensurate changes in myocardial oxygen consumption. One explanation is that augmenting pulsatile perfusion at the same mean pressure itself stimulates flow by releasing endothelium-mediated vasorelaxant factors such as NO. The present study tested this hypothesis and determined whether NO and adenosine modulate this response. In open-chest anesthetized dogs, the distal left anterior descending coronary artery (LAD) was whole-blood-perfused by a novel servopump system to control mean and pulsatile perfusion pressure within the isolated vascular bed. Central aortic pressure was measured, stored to computer memory, and then digitally modified (varying the pulse pressure [PP]) to generate a real-time servocommand that was still synchronous with ventricular contraction. Left heart workload was unchanged. LAD flow was measured before and after increasing the PP (to 60 to 100 mm Hg) from baselines of either 0 or 40 mm Hg. With normal basal coronary vascular tone, raising the PP increased flow (+9 +/- 2% at a PP of 100 mm Hg). This response was markedly amplified (+39 +/- 8%) when basal tone was first partially reduced by adenosine. Competitive inhibition of NO synthase by N omega-monomethyl-L-arginine reduced acetylcholine and PP-dependent flow responses by 50%. Thus, enhanced pulsatile perfusion increases in vivo coronary flow in part by triggering NO release. The marked augmentation of the PP response with reduced basal coronary tone from adenosine suggests that this mechanism may play a role in improving myocardial perfusion during exercise.

Adverse influence of systemic vascular stiffening on cardiac dysfunction and adaptation to acute coronary occlusion.

BACKGROUND: [corrected] Age is an independent risk factor for increased mortality from ischemic heart disease. Arterial stiffening with widening of the pulse pressure may contribute to this risk by exacerbating cardiac dysfunction after total coronary artery occlusion. METHODS AND RESULTS: To test the above hypothesis, 14 open-chest dogs underwent surgery in which the intrathoracic aorta was bypassed with a stiff plastic tube. Directing ventricular outflow through the bypass widened the arterial pulse pressure from 41 to 115 mm Hg at similar mean pressure and flow. Hearts ejecting into the native aorta (NA) exhibited only modest dysfunction after two minutes of mid-left anterior descending coronary artery occlusion. However, the same occlusion applied during ejection into the bypass tube (BT) induced far more severe cardiodepression (ie, systolic pressure fell by -41+/-10 mm Hg for BT versus -15+/-3 mm Hg for NA, and end-systolic volume rose by 15+/-3 versus 6+/-2 mL), with a threefold greater decline in ejection fraction. This disparity was not due to higher baseline work loads because total pressure-volume area was similar in both cases. Furthermore, marked increases in basal work load and wall stress induced by angiotensin II infusion (in four additional studies) did not reproduce this behavior. Although peak systolic chamber stress was greater with the BT, this did not increase systolic dyskinesis as measured in the central ischemic zone. However, the total mass of myocardium that was rendered severely ischemic (ie, flow reduced by > or = 80%) was twice as large with BT ejection, likely expanding the region of dyskinesis. This disparity may relate to altered phasic coronary flow during BT ejection, which displays marked enhancement of systolic flow and renders the heart more vulnerable to diminished mean and systolic perfusion pressures. CONCLUSIONS: Cardiac ejection into a stiff systemic vasculature augments cardiac dysfunction and ischemia due to coronary occlusion by tightening the link between cardiac systolic performance and myocardial perfusion. This may contribute to the higher mortality risk from ischemic heart disease due to age.

Minimal role of nitric oxide in basal coronary flow regulation and cardiac energetics of blood-perfused isolated canine heart.

1. The role of nitric oxide (NO) in the regulation of basal coronary perfusion and ventricular chamber energetics was studied in isovolumetrically contracting isolated blood-perfused canine hearts. Hearts were cross-perfused by a donor animal prior to isolation, and chamber volume controlled by a servo-pump. Coronary sinus flow and arterial-coronary sinus oxygen difference were measured to determine energetic efficiency. 2. NO synthase (NOS) was competitively inhibited by NG-monomethyl-L-arginine (L-NMMA; 0.5 mg kg-1, intracoronary), resulting in a reduction of acetylcholine (50 micrograms min-1)-induced flow augmentation from 143 to 62% (P < 0.001). 3. NOS inhibition had no significant effect on basal coronary flow. Coronary pressure-flow relationships were determined at a constant cardiac workload by varying mean perfusion pressure between 20 and 150 mmHg. Neither the shape of the relationship, nor the low-pressure value at which flow regulation was substantially diminished were altered by NOS inhibition. 4. Myocardial efficiency was assessed by the relationship between myocardial oxygen consumption and total pressure-volume area (PVA), with cavity volume altered to generate varying PVAs. This relative load-independent measure of energetic efficiency was minimally altered by NOS inhibition. 5. These results contrast with isolated crystalloid-perfused heart experiments and suggest that in hearts with highly controlled ventricular loading and whole-blood perfusion, effects of basal NO production on coronary perfusion and left ventricular energetics are minimal.