Primary care in the treatment of functional gastrointestinal symptoms in Japan: prescription preferences and impression of results.

BACKGROUND: Functional gastrointestinal (GI) disorders are common in primary care. However, proper pharmacological approaches have not yet been established. The reason for a lack of proper approaches may be attributable to the lack in clarity of their pathogenesis and pathophysiology. Meta-analysis of pharmacological approaches to functional GI disorders failed to identify the solid cluster of patients' symptoms. AIM: The aim of this study is to assess the perspective of primary care doctors concerning prescriptions for functional GI symptoms, evaluate the efficacy of the drugs prescribed, and the need for medication for these symptoms. METHOD: Questionnaires were sent to primary care doctors, and a total of 149 responses were obtained. Efficacy of each medication was evaluated by the number of doctors favouring the category, and the respective impressions of prescriptions given. RESULTS: Symptoms of heartburn were well controlled by anti-secretory drugs (H2RAs and PPIs), while appetite loss and abdominal gurgling were not controlled by any medications. CONCLUSIONS: This survey reveals differences in need for various prescription drugs in functional GI symptoms.

Effect of diadenosine tetraphosphate (AP4A) on coronary arterial microvessels in the beating canine heart.

Diadenosine tetraphosphate (AP4A) can be released from activated platelets and the present study examined its effect on coronary arterial microvessels. The role of purinoceptors in the coronary microcirculation in vivo was also investigated. In open chest dogs, coronary arterioles were observed using a microscope with a floating objective. In Protocol 1, AP4A (1, 10, 100 and 1,000 micromol/L) was superfused onto the heart surface before and during the superfusion of 10 micromol/L of 8-phenyltheophylline (8-PT), a P1 purinoceptor blocker. In Protocol 2, AP4A (0.1, 1, 10, and 100 nmol x kg(-1) x min(-1)) was infused into the left anterior descending coronary artery before and during the superfusion of 10 micromol/L of 8-PT. In addition to 8-PT, 30 micromol/L of pyridoxalphosphate-6-azophenyl 2',4'-disulphonic acid (PPADS), a P2X purinoceptor blocker in Protocol 3, or 300 micromol/L of N(omega)-nitro-L-arginine (LNNA) in Protocol 4, was continuously superfused, and 4 doses of AP4A were cumulatively superfused as in Protocol 1. In Protocol 5, 10 micromol/L of alpha,beta-methylene ATP, an agonist of P2X purinoceptors, was superfused for 60 min. Superfused AP4A dilated arterioles in a dose-dependent manner. The magnitude of dilatation was greater in smaller arterioles (small vessel < or = 150 microm: 24.5+/-2.2% vs large vessel > 150 microm: 10.6+/-1.5% at a dose of 1,000 micromol/L, p<0.001). On the other hand, intraluminally applied AP4A also dilated arterioles, but no size dependency was shown. In the presence of 8-PT, vasodilatory responses to superfused and intraluminally applied AP4A were attenuated and the lower doses of AP4A constricted arterioles. This vasoconstrictor effect was not affected by PPADS. The vasodilatory effect of the higher doses of AP4A was almost abolished in the presence of LNNA. Alpha,beta-methylene ATP had no effect on coronary microvascular diameters. AP4A has bidirectional effects on coronary arterial microvessels: vasodilatory effects mediated by P1 purinoceptors and NO, which might be mediated by P2Y purinoceptors, and a vasoconstrictor effect, which is not mediated by P2X purinoceptors.

Role of pertussis toxin-sensitive G protein in metabolic vasodilation of coronary microcirculation.

We have previously demonstrated that pertussis toxin (PTX)-sensitive G protein (G(PTX)) plays a major role in coronary microvascular vasomotion during hypoperfusion. We aimed to elucidate the role of G(PTX) during increasing metabolic demand. In 18 mongrel dogs, coronary arteriolar diameters were measured by fluorescence microangiography using a floating objective. Myocardial oxygen consumption (MVO(2)) was increased by rapid left atrial pacing. In six dogs, PTX (300 ng/ml) was superfused onto the heart surface for 2 h to locally block G(PTX). In eight dogs, the vehicle (Krebs solution) was superfused in the same way. Before and after each treatment, the diameters were measured during control (130 beats/min) and rapid pacing (260 beats/min) in each group. Metabolic stimulation before and after the vehicle treatment caused 8.6 +/- 1. 8 and 16.1 +/- 3.6% dilation of coronary arterioles <100 microm in diameter (57 +/- 8 microm at control, n = 10), respectively. PTX treatment clearly abolished the dilation of arterioles (12.8 +/- 2. 5% before and 0.9 +/- 1.6% after the treatment, P < 0.001 vs. vehicle; 66 +/- 8 microm at control, n = 11) in response to metabolic stimulation. The increases in MVO(2) and coronary flow velocity were comparable between the vehicle and PTX groups. In four dogs, 8-phenyltheophylline (10 microM, superfusion for 30 min) did not affect the metabolic dilation of arterioles (15.3 +/- 2.0% before and 16.4 +/- 3.8% after treatment; 84.3 +/- 11.0 microm at control, n = 8). Thus we conclude that G(PTX) plays a major role in regulating the coronary microvascular tone during active hyperemia, and adenosine does not contribute to metabolic vasodilation via G(PTX) activation.

Coronary microcirculation: physiology and pharmacology.

Coronary microvessels play a pivotal role in determining the supply of oxygen and nutrients to the myocardium by regulating the coronary flow conductance and substance transport. Direct approaches analyzing the coronary microvessels have provided a large body of knowledge concerning the physiological and pharmacological characteristics of the coronary circulation, as has the rapid accumulation of biochemical findings about the substances that mediate vascular functions. Myogenic and flow-induced intrinsic vascular controls that determine basal tone have been observed in coronary microvessels in vitro. Coronary microvascular responses during metabolic stimulation, autoregulation, and reactive hyperemia have been analyzed in vivo, and are known to be largely mediated by metabolic factors, although the involvement of other factors should also be taken into account. The importance of ATP-sensitive K(+) channels in the metabolic control has been increasingly recognized. Furthermore, many neurohumoral mediators significantly affect coronary microvascular control in endothelium-dependent and -independent manners. The striking size-dependent heterogeneity of microvascular responses to all of these intrinsic, metabolic, and neurohumoral factors is orchestrated for optimal perfusion of the myocardium by synergistic and competitive interactions. The regulation of coronary microvascular permeability is another important factor for the nutrient supply and for edema formation. Analyses of collateral microvessels and subendocardial microvessels are important for understanding the pathophysiology of ischemic hearts and hypertrophied hearts. Studies of the microvascular responses to drugs and of the impairment of coronary microvessels in diseased conditions provide useful information for treating microvascular dysfunctions. In this article, the endogenous regulatory system and pharmacological responses of the coronary circulation are reviewed from the microvascular point of view.

Effects of low doses of endothelin-1 on basal vascular tone and autoregulatory vasodilation in canine coronary microcirculation in vivo.

The plasma level of endothelin-1 (ET-1) increases in several cardiovascular disorders. The present study examined whether threshold doses of ET-1 affect vascular tone and autoregulatory vasodilation during a reduction in perfusion pressure in the coronary microcirculation in vivo. In anesthetized open-chest dogs, arterial microvessels in the epimyocardium were observed through a microscope equipped with a floating objective. In 6 dogs, ET-1 (10(-13) to 10(-8)mol/L) was superfused onto the epimyocardium in a cumulative fashion. In another set of dogs (n= 16), the perfusion pressure of the observed vascular bed was reduced to 60 mmHg (mild stenosis) and to 40 mmHg (severe stenosis) by a hydraulic occluder, and the microvascular responses were observed in the presence (n=9) or absence (n=7) of ET-1 (10(-12) or 10(-11) mol/L). ET-1 > or =10(-11) mol/L constricted coronary arterioles (< or =100 microm in diameter) and small arteries (>100 microm in diameter) in a dose-dependent fashion. ET-1 of 10(-12) mol/L affected neither the basal diameters nor the dilation of vessels during the pressure reduction. ET-1 of 10(-11) mol/L decreased the diameters of arterioles and small arteries before and during the mild and severe stenosis. However, ET-1 did not attenuate the percentage dilation of arterioles from the baseline in response to the mild and severe stenosis. The data indicates the following: (1) ET-1 at doses > or =10(-11) mol/L similarly constricts coronary arterioles and small arteries; (2) ET-1 at 10(-11) mol/L, which is slightly higher than the pathophysiological plasma level, increases the basal vascular tone, but does not attenuate the autoregulatory vasodilation of the coronary microcirculation.

Mechanisms of coronary microvascular dilation induced by the activation of pertussis toxin-sensitive G proteins are vessel-size dependent. Heterogeneous involvement of nitric oxide pathway and ATP-sensitive K+ channels.

G proteins are critically important mediators of many signal transduction systems. In the present study, we investigated the effect of direct activation of pertussis toxin (PTX)-sensitive G protein (GPTX) on coronary arterial microvascular tone in 37 open-chest anesthetized dogs in vivo. Coronary arterial microvessels on the surface of the beating left ventricle were visualized by performing fluorescence coronary microangiography using an intravital microscope with a floating objective system. Microvessels were divided into two groups, small microvessels (inner diameter, < or = 130 microns) and large microvessels (inner diameter, > 130 microns). Topically applied mastoparan (G protein activator, 10, 30, and 100 mumol/L) produced homogeneous microvascular dilation in a concentration-dependent manner (10 mumol/L, 7.9 +/- 2.0%; 30 mumol/L, 10.3 +/- 2.4%; and 100 mumol/L, 16.7 +/- 4.5% in small microvessels; 10 mumol/L, 5.3 +/- 1.2%; 30 mumol/L, 9.8 +/- 2.5%; and 100 mumol/L, 15.5 +/- 3.9% in large microvessels). These dilations were reversed to constriction by pretreatment with PTX (300 ng/mL, 2 hours) in both microvessel groups. Blockade of nitric oxide production by NG-nitro-L-arginine (LNNA, 300 mumol/L) offset the mastoparan-induced dilation in large microvessels but not in small microvessels. Cosuperfusion of glibenclamide (10 mumol/L) with LNNA produced constriction of all sizes of microvessels in response to mastoparan, whereas charybdotoxin (10 nmol/L) did not affect the mastoparan effect. Pretreatment with glibenclamide alone reversed mastoparan dilation to constriction in small microvessels, whereas it only offset the dilation without producing constriction in large microvessels. We conclude that the activation of GPTX produces homogeneous coronary arterial microvascular dilation and that the underlining mechanisms of the dilation are vessel size dependent. The L-arginine-nitric oxide pathway mediates the dilation only in large microvessels, whereas ATP-sensitive K+ channel activation plays a central role in the dilation of small microvessels when GPTX is directly activated. ATP-sensitive K+ channels are also involved in the dilation of large microvessels in a synergistic fashion with nitric oxide production.

Vasodilatory effect of nicorandil on coronary arterial microvessels: its dependency on vessel size and the involvement of the ATP-sensitive potassium channels.

We aimed to clarify the size dependency of nicorandil-induced dilation in coronary microcirculation and the involvement of adenosine triphosphate (ATP)-sensitive potassium channels. Coronary arterial microvessels were observed through a microscope equipped with a floating objective in anesthetized open-chest dogs (n = 29). Heart rate and mean aortic pressure were maintained at control level. In 16 dogs, nicorandil was infused into the coronary in a cumulative fashion (0.1, 1.0, 10, and 100 micrograms/kg/min, for 5 min for each dose). In 13 dogs, glibenclamide (10 microM) was topically applied onto the observed area, and nicorandil was similarly infused. Nicorandil dilated vessels < 100 microns in diameter at all applied doses in a dose-dependent manner. Glibenclamide abolished the dilation of these vessels at the lower two doses. Vessels > 100 microns in diameter dilated only at the two higher doses and the dilation was not affected by glibenclamide. These data suggest that the vessels < 100 microns are more sensitive to this agent than other size vessels, and that ATP-sensitive potassium channels are involved in the nicorandil-induced dilation of vessels smaller than 100 microns, whereas the dilation of other size vessels occurs independently of this channel.

Effect of an ATP sensitive potassium channel opener, levcromakalim, on coronary arterial microvessels in the beating canine heart.

OBJECTIVE: The aim was to clarify the site in the coronary microcirculation that is dilated by an ATP sensitive potassium channel opener, levcromakalim, and to examine whether the magnitude of dilatation is size dependent. METHODS: Coronary arterial microvessels were observed through an intravital microscope equipped with a floating objective in beating canine left ventricles in situ. Flow velocity of the left anterior descending coronary artery was measured with a suction-type Doppler probe. Heart rate and aortic pressure were maintained at control levels throughout the experiments. Three doses of levcromakalim (0.01-1.0 microgram.kg-1.min-1) or a single dose (1.0 microgram.kg-1.min-1) were infused into the coronary artery in groups, with or without intracoronary glibenclamide pretreatment (200 or 400 micrograms.kg-1). The effect of levcromakalim on different sized vessels was assessed by dividing them into three groups according to control diameter (small, internal diameter < 100 microns; medium, > or = 100, < 200 microns; large, > or = 200 microns). RESULTS: The lowest dose of levcromakalim dilated only the small vessels. The two higher doses dilated vessels of all sizes, but the magnitude of dilatation was greater in the small vessel group than in the other two groups. Coronary resistance significantly decreased dose dependently during the infusion of 0.1 and 1.0 microgram.kg-1.min-1 of levcromakalim. Pretreatment with glibenclamide markedly attenuated the levcromakalim induced dilatation of all vessel groups and the reduction in coronary vascular resistance. CONCLUSIONS: Levcromakalim heterogeneously dilates coronary arterial microvessels via the opening of ATP sensitive potassium channels, and small vessels are more sensitive to levcromakalim.

Pertussis toxin-sensitive G protein mediates coronary microvascular control during autoregulation and ischemia in canine heart.

GTP-binding regulatory proteins (G proteins) regulate various biological functions, but their participation in controlling coronary microvascular tone has not been established yet. The goal of the present study was to elucidate the role of pertussis toxin (PTX)-sensitive G protein in regulating coronary microvascular tone during autoregulation and ischemia. In 42 open-chest dogs, coronary arterial microvessels on the surface of the left ventricle were directly observed by epi-illuminated fluorescence microangiography using a floating objective system. PTX (300 ng/mL) was superfused onto the surface of the left ventricle for 2 hours to block Gi and G(o) protein in epimyocardial coronary microvessels in vivo. PTX superfusion caused no change in the resting diameters of microvessels and significantly blocked the vasoconstriction induced by BHT 920 (a selective alpha 2-agonist). After pretreatment with PTX or its vehicle, the left anterior descending coronary artery (LAD) was occluded by a hydraulic occluder to reduce coronary perfusion pressure (CPP) in a stepwise fashion. A mild stenosis (CPP, 60 mm Hg), a severe stenosis (CPP, 40 mm Hg), and complete occlusion were sequentially produced. Coronary flow velocity in the LAD distal to the stenotic site was continuously monitored. In both PTX and vehicle groups, flow velocity did not significantly decrease during mild stenosis, proving that transmural coronary autoregulatory function was well preserved in the preparation. During severe stenosis and complete occlusion, the coronary flow velocity significantly decreased. In the vehicle group, microvessels < 100 microns in inner diameter significantly dilated in response to the reduction in perfusion pressure (mild stenosis, 6.2 +/- 1.9%; severe stenosis, 21.1 +/- 4.4%; and complete occlusion, 16.8 +/- 5.9%; P < .05 versus baseline diameters). In the PTX group, microvessels did not dilate during each occlusion level (mild stenosis, -2.0 +/- 0.9%; severe stenosis, -3.9 +/- 1.9%; and complete occlusion, -13.4 +/- 2.9%; P < .05 versus vehicle group). PTX did not affect the microvascular dilation caused by nitroprusside. The present data indicate that PTX-sensitive G protein is crucially involved in microvascular control during autoregulation and ischemia.

Effect of calcitonin gene-related peptide on coronary microvessels and its role in acute myocardial ischemia.

BACKGROUND: Calcitonin gene-related peptide (CGRP) is a potent dilator of epicardial conduit vessels and is released during myocardial ischemia in humans. However, the effect of CGRP on coronary arterial microvessels is still unclear, and it is unknown if CGRP modulates the tone of coronary arterial microvessels during acute myocardial ischemia. METHODS AND RESULTS: Epimyocardial microvessels were observed through a microscope equipped with a floating objective system in anesthetized open-chest dogs. Heart rate and aortic pressure were maintained at control levels. Flow velocity of the left anterior descending coronary artery (LAD) was measured with a suction-cup Doppler probe. When CGRP was cumulatively infused into the LAD (0.05, 0.5, 5.0, and 50 pmol/kg per minute) or superfused (0.03, 0.3, 3.0, and 30 nmol/L) over the left ventricular surface, arterial control microvessels > 100 microns in diameter dilated dose dependently at dosages of 0.5 to 50 pmol/kg per minute (infused) or 0.3 to 30 nmol/L (superfused), but those < 100 microns dilated only at the highest dose, and those > 100 microns had greater dilation in both groups. Only the highest dose of CGRP (infused) significantly increased coronary flow. The superfusion of CGRP(8-37) (CGRP receptor antagonist, 300 nmol/L) did not affect the control diameters of coronary arterial microvessels but completely abolished CGRP-induced vasodilation at the same doses (infused and superfused). However, 300 nmol/L of CGRP(8-37) did not affect the response of coronary arterial microvessels to the LAD occlusion in any size. CONCLUSIONS: CGRP preferentially dilates the coronary arterial microvessels > 100 microns in diameter but has only a small effect on those < 100 microns. Endogenous CGRP does not modulate the tone of coronary arterial microvessels during acute myocardial ischemia in beating canine hearts.

The role of ATP-sensitive potassium channels in regulating coronary microcirculation.

The ATP-sensitive potassium channel (K+ATP channel) is known to exist in blood vessels and to regulate vascular tone. We examined the role of this channel in coronary arteriolar vasomotion during coronary autoregulation, ischemia, reactive hyperemia and endothelium-dependent response by acetylcholine in vivo. Experiments were performed with anesthetized open-chest dogs. Coronary arterioles were directly observed in situ by means of a floating objective system or a stroboscopic epi-illumination system synchronized with cardiac motion. Small arterioles less than 100 microns in internal diameter dilated in response to reduction in perfusion pressure (perfusion pressure: 60, 40, 25 mm Hg). Glibenclamide, a selective blocker of the K+ATP channel, reversed the dilation. Reactive hyperemia produced by 20-second occlusion of the left anterior descending coronary artery resulted in arteriolar dilation, the magnitude of which was greater in smaller arterioles than in larger ones. Glibenclamide significantly inhibited the dilation in both large and small arterioles. Acetylcholine (ACh) produced dilation in arterioles of all sizes. NG-monomethyl L-arginine, a competitive inhibitor of nitric oxide synthesis, abolished the dilation of large arterioles, but failed to abolish the dilation in small arterioles. Glibenclamide, however, did not have any additional inhibitory effect on ACh-induced arteriolar dilation. Thus, we conclude that the K+ATP channel plays an important role in coronary microvascular vasomotion during autoregulation, ischemia and reactive hyperemia, but not during endothelium-dependent vasodilation induced by ACh in vivo.

Microvascular sites and mechanisms responsible for reactive hyperemia in the coronary circulation of the beating canine heart.

Our aim was to elucidate the site and mechanism responsible for reactive hyperemia in coronary circulation. In in vivo beating canine hearts, microvessels of the left anterior descending coronary artery (LAD) were observed through a microscope equipped with a floating objective. Flow velocity of the LAD was measured with a suction-type Doppler probe. The LAD was occluded for 20 or 30 seconds and then released, and reactive hyperemia was observed before and after 8-phenyltheophylline (7.5 mg/kg i.v.) or glibenclamide (200 micrograms/kg into the LAD) infusion. During the occlusion, only arterial microvessels smaller than 100 microns in diameter dilated. Dilation of those vessels was partially attenuated by 8-phenyltheophylline and completely abolished with glibenclamide. In the early phase of reactive hyperemia, all arterial microvessels dilated, and the magnitude of peak dilation was greater in vessels smaller than 100 microns compared with those larger than 100 microns. Vasodilation during reactive hyperemia ceased within 60 seconds in vessels smaller than 100 microns but was sustained for more than 120 seconds in those larger than 100 microns. 8-Phenyltheophylline did not change peak dilation of arterial microvessels but reduced dilation after the peak. Glibenclamide remarkably attenuated dilation of all arterial microvessels in the whole phase of reactive hyperemia. These results indicate that all arterial microvessels are responsible for reactive hyperemia after coronary artery occlusions of 20-30 seconds, but there is greater participation of vessels smaller than 100 microns in the early phase of reactive hyperemia. Dilation of vessels larger than 100 microns assumes an important role in the later phase. ATP-sensitive K+ channels mediate dilation of arterial microvessels both in brief ischemia and reactive hyperemia.

Effects of nitroglycerin on the coronary microcirculation in normal and ischemic myocardium.

Nitroglycerin dilates conduit coronary vessels and only transiently increases flow, however the effects of nitroglycerin in the microcirculation of normal myocardium and during myocardial ischemia have not been assessed. The goal of this investigation was to determine the effects of steady-state levels of nitroglycerin on the microcirculation of normal and ischemic myocardium. Microvessels on the left ventricle were viewed using stroboscopic epi-illumination in anesthetized, open-chest dogs. Myocardial perfusion was measured with radioactive microspheres. Aortic pressure and heart rate were kept constant by an aortic snare and left atrial pacing. Microvessel diameters were measured under control conditions and during steady-state infusion of nitroglycerin (n = 11, 0.01-100 micrograms kg-1 min-1, i.v.). Nitroglycerin selectively dilated arteries from 201 to 386 microns, but had no effect on large arterioles less than 200 microns. Total coronary vascular resistance remained constant except at the highest dose. When mean coronary pressure was decreased to 35 mm Hg, small arterioles less than 100 microns dilated. Diameters of larger arterioles decreased. Nitroglycerin (10 micrograms kg-1 min-1, i.v., n = 8) selectively dilated microvessels greater than 200 microns in the region distal to the stenosis, although myocardial perfusion was not affected. Thus, nitroglycerin altered the distribution of microvascular resistance without altering overall resistance. We conclude that steady-state infusion of nitroglycerin selectively dilates coronary arterial microvessels greater than 200 microns. During decreased perfusion pressure, recruitable vasodilation in response to nitroglycerin is due to dilation of microvessels greater than 200 microns.

Effects of alpha and beta adrenergic blockade on coronary arterial microvessels in the beating canine heart.

OBJECTIVE: The aim was to clarify the effects of alpha and beta adrenergic blockade on coronary arterial microvessels and to assess the role of alpha and beta adrenergic tone in normally beating hearts. METHODS: 47 anaesthetised open chest dogs were studied. The diameters of epicardial arterial microvessels were measured in beating hearts using an incident light fluorescence microscope equipped with a floating objective. Drugs were infused into the left anterior descending coronary artery keeping the heart rate and aortic pressure at control levels. To examine the effect of alpha adrenergic blockade, phentolamine (100 micrograms.kg-1) was given in the absence or presence of beta adrenergic blockade (propranolol 50 micrograms.kg-1). To examine the effect of beta adrenergic blockade, propranolol (50 micrograms.kg-1) or three doses of ICI 118,551 (a selective beta 2 antagonist, 0.1, 0.5, and 1.0 microgram.kg-1.min-1) was given. RESULTS: Coronary arterial microvessels were divided into three groups according to the control diameters (D) of small (D less than 100 microns), medium (100 less than or equal to D less than 200 microns) and large (D greater than or equal to 200 microns) groups. In the absence of beta adrenergic blockade, phentolamine significantly dilated all vessel groups: small +19.6 (SEM 5.6)%, medium +5.8(2.3)%, large +5.3(0.9)%. In the presence of beta adrenergic blockade, the vasodilator effect of phentolamine was completely abolished. Propranolol constricted all vessel groups: small -3.6(1.1)%, medium -4.8(1.0)%, large -3.5(1.0)%. ICI 118,551 significantly constricted the large vessel group [-2.5(0.6)%] at the mid dose, and the medium and large vessel groups [medium -3.1(0.8)%, large -3.5(1.3)%] at the highest dose. CONCLUSIONS: These data indicate that (1) the vasodilator effect of phentolamine is induced by beta adrenergic stimulation; (2) resting alpha adrenergic tone of coronary arterial microvessels is minimal in normally beating hearts, and (3) resting beta adrenergic tone may play a physiological role in coronary arterial microvessels, and beta 2 adrenergic tone predominates in arterial microvessels greater than 100 microns in diameter.

Coronary microvascular resistance in hypertensive cats.

Chronic systemic hypertension has been shown to alter the distribution of vascular resistance in many microvascular beds. The purposes of this study were to assess the effects of chronic systemic hypertension on the pressure distribution in the coronary microcirculation and to determine the microvascular site where coronary vascular resistance is increased. Cats were made hypertensive using a one-kidney, one-wrap model (Page model). A servonulling system was used to directly measure pressures in the epimyocardial microvessels of the beating left ventricle in normotensive and hypertensive cats. In chronically hypertensive cats, mean arterial pressure was 153 +/- 5 mm Hg compared with 98 +/- 3 mm Hg in normotensive cats (p less than 0.05). Left ventricular mass was increased approximately 34% in hypertensive cats (9.4 +/- 0.3 versus 7.0 +/- 0.3 g, p less than 0.05). Myocardial perfusion measured using radiolabeled microspheres was not different between hypertensive and normal cats. Coronary vascular resistance of the left ventricle was increased in hypertensive cats (0.90 +/- 0.08 versus 0.66 +/- 0.05 mm Hg x min x 100 g/ml, p less than 0.05). Microvascular pressures were measured in three groups of microvessels: small, less than 200 microns; medium, 200-300 microns; and large, greater than or equal to 300 microns. Mean microvascular pressures of large, medium, and small arterial microvessels in hypertensive cats were 144 +/- 8, 127 +/- 6, and 115 +/- 7 mm Hg, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Neuropeptide Y modulates vasoconstriction in coronary microvessels in the beating canine heart.

The purpose of this study was to determine whether neuropeptide Y has a direct vasoconstrictor effect at low doses, mimicking the physiological plasma concentration on the specific site(s) of coronary arterial microvessels in in situ beating canine left ventricles. Coronary microvessels were directly observed by means of an intravital microscope and video system equipped with a floating objective. Epi-illuminated fluorescence coronary microangiography was performed in open-chest anesthetized dogs (n = 14) to examine the changes in internal diameter of epimyocardial arterial microvessels. Flow velocity of fluorescently labeled microshperes in capillaries was also measured (n = 6). To eliminate secondary effects of neuropeptide Y on coronary microvessels via autonomic nervous modulation, experiments were conducted under pharmacological blockade of the regional autonomic nervous system by intracoronary injection of propranolol, 50 micrograms/kg; phentolamine, 100 micrograms/kg; and atropine, 5 micrograms/kg. Aortic pressure and heart rate were kept constant during the experiments. Intracoronary infusion of three different doses of neuropeptide Y (1, 10, and 100 pmol/kg/min) for 5 minutes significantly constricted small microvessels (less than 100 microns in diameter) (-5.2 +/- 1.4%, -8.5 +/- 1.5%, and -14.0 +/- 1.7%; p less than 0.05 versus before neuropeptide Y at each dose), medium microvessels (100-200 microns in diameter) (-5.5 +/- 1.6%, -10.6 +/- 1.8%, and -16.8 +/- 2.1%, p less than 0.05 versus before neuropeptide Y at each dose), and large microvessels (greater than 200 microns in diameter) (-3.6 +/- 0.6%, -5.8 +/- 0.8%, and -10.0 +/- 1.1%; p less than 0.05 versus before neuropeptide Y at each dose) in a dose-dependent manner. Capillary flow velocity was reduced by 17.2 +/- 3.1% by an intracoronary dose of 100 pmol/kg/min of neuropeptide Y (p less than 0.05). The present study indicates that low doses of neuropeptide Y exert a homogeneous direct vasoconstrictor effect on various sizes of coronary arterial microvessels and reduce capillary flow velocity. These results suggest that neuropeptide Y may play a physiological role in modulating coronary microvascular tone.

Understanding the coronary circulation through studies at the microvascular level.

Studies of the coronary circulation have divided vascular resistances into three large components: large vessels, small resistance vessels, and veins. Studies of the epicardial microcirculation in the beating heart using stroboscopic illumination have suggested that resistance is more precisely controlled in different segments of the circulation. Measurements of coronary pressure in different sized arteries and arterioles have indicated that under normal conditions, 45-50% of total coronary vascular resistance resides in vessels larger than 100 microns. This distribution of vascular resistance can be altered in a nonuniform manner by a variety of physiological (autoregulation, increases in myocardial oxygen consumption, sympathetic stimulation) and pharmacological stimuli (norepinephrine, papaverine, dipyridamole, serotonin, vasopressin, nitroglycerin, adenosine, and endothelin). Studies of exchange of macromolecules in the microcirculation using fluorescent-labeled dextrans have also identified the size of the small pore (35-50 A) in coronary microvessels that can be altered by myocardial ischemia. Studies of the coronary microcirculation have demonstrated that the control of vascular resistance is extremely complex, and mechanisms responsible for these heterogeneous responses need further examination.

Heterogeneous changes in epimyocardial microvascular size during graded coronary stenosis. Evidence of the microvascular site for autoregulation.

The purpose of this study was to determine the coronary microvascular sites of autoregulation. The epimyocardial coronary microcirculation was observed through an intravital microscope by stroboscopic epi-illumination in anesthetized open-chest dogs (n = 20). Aortic pressure and heart rate were held constant by an aortic snare and atrial pacing, respectively. Distal pressure of the left anterior descending coronary artery was controlled by a screw occluder on the proximal left anterior descending coronary artery and monitored with a 24-gauge plastic cannula inserted into the branch or distal portion of the left anterior descending coronary artery. Distal pressure of the left anterior descending coronary artery was stepwisely reduced to 59 +/- 1 mm Hg (mild stenosis, n = 20) and 38 +/- 1 mm Hg (severe stenosis, n = 16). In the left circumflex coronary artery area, myocardial blood flow measured with radioactive microspheres to subepicardium, midmyocardium, and subendocardium did not change with the mild and severe stenosis from control. In the left anterior descending coronary artery area, myocardial blood flow to each layer remained at nearly control level with the mild stenosis but was reduced in midmyocardium and subendocardium with the severe stenosis. With the mild stenosis, diameters of coronary arterial microvessels less than 100 microns in diameter dilated, and those larger than 100 microns in diameter did not change. The magnitude of vasodilation in small arterial microvessels was inversely related to control diameter. With the severe stenosis, small arterial microvessels dilated, and simultaneously, large arterial microvessels constricted. Again, the magnitude of vasodilation in small arterial microvessels was inversely related to control diameter.(ABSTRACT TRUNCATED AT 250 WORDS)

Diameter change and pressure-red blood cell velocity relations in coronary microvessels during long diastoles in the canine left ventricle.

The objective of this study was to determine whether coronary vascular resistance remains constant during long diastoles and whether critical closure of arterial microvessels occurs at zero-flow pressure. For this purpose, we directly measured internal diameters and red blood cell velocities in arterial and venous coronary microvessels during long diastoles under maximal vasodilation. The epicardial coronary microcirculation was viewed in anesthetized, open-chest mongrel dogs through an intravital microscope equipped with a newly developed floating objective. Coronary microvascular diameters and red blood cell velocities were measured with high-speed cinematography. During maximal vasodilation (150 micrograms/kg body wt i.v. dilazep), long diastoles were induced by vagal nerve stimulation. Internal diameters of all small arteries and arterioles (n = 12) gradually declined with decreasing aortic pressure during long diastoles, and the reduction of the diameter was greatest when aortic pressure was less than 35 mm Hg. The mean internal diameter (88.8 +/- 52.2 microns) at minimal aortic pressure (19.2 +/- 6.4 mm Hg) was significantly less than that at an aortic pressure of 100 mm Hg (116.2 +/- 68.5 microns, p less than 0.01). The internal diameters of small veins and venules remained nearly constant during long diastoles. When red blood cell progression in coronary microvessels stopped at the nadir of aortic pressure, all arterial coronary microvessels remained open; that is, there was no evidence of "critical closure."(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of the effects of increased myocardial oxygen consumption and adenosine on the coronary microvascular resistance.

The purposes of this study were to determine if coronary dilation secondary to an increase in myocardial oxygen consumption (MVO2) affects the microcirculation in a homogeneous or heterogeneous manner and to determine if comparable degrees of coronary dilation produced by increasing MVO2 or exogenous (intravenous adenosine) or endogenous (intravenous dipyridamole) adenosine have similar effects in the coronary microcirculation. The epimyocardial coronary microcirculation was observed through an intravital microscope by stroboscopic epi-illumination in anesthetized open-chest dogs. Aortic pressure and heart rate were controlled by an aortic snare and atrioventricular sequential pacing, respectively, during experimental procedures. In group 1 (n = 15), coronary arterial microvessel diameters were measured under control condition and during rapid pacing at 300 beats/min, which doubled MVO2. Increases in MVO2 caused heterogeneous vasodilation in coronary arterial microvessels (40-380 microns). There was an inverse relation between control diameter and percent increase in diameter. In group 2 (n = 15) or group 3 (n = 10), adenosine or dipyridamole was infused intravenously to increase myocardial perfusion to the same level as that obtained with rapid pacing. Adenosine and dipyridamole did not change MVO2. Adenosine and dipyridamole also caused heterogeneous vasodilation, but the effects of adenosine and dipyridamole were restricted to arterial microvessels smaller than 150 microns. From these results, we conclude that increases in MVO2 produce widespread but heterogeneous vasodilation, that is, greater dilation in smaller arterial microvessels. Comparable increases in coronary flow produced by increasing MVO2 or endogenous and exogenous adenosine do not produce identical changes in the distribution of coronary microvascular resistance.