The coronary vasculature and the myocardium

The effect of bradykinin (BK) on myocardial inotropic state was tested on 5 isolated rat heart preparations, in which a proper ballon was placed to record left ventricular pressure, whose developed systolic value was taken as an index of contractility. A reduction of developed left ventricular pressure was observed when BK was added to the perfusion oxygenated Tyrode solution. However, when BK was given after 1-amino-benzotriazole, an inhibitor of Cytochrome P-450 (Cyt P-450), developed pressure did not change. Since Cyt P-450 is known to act on arachidonic acid inducing the production of epoxiecocistrienoic acids (EETs) which hyperpolarizes myocardial fibres, it was argued that the reduction in contractility by bradykinin was the result of the hyperpolarizing effect of EETs. The fact that the concentration of Cyt P-450 is higher in the vascular endothelial cells than in the sarcolemma of the myocytes and the observation that the coronary resistance decreases together with the contractility suggest that the endothelium plays a pivotal role in mediating the negative inotropic effect of BK.     

Bifurcation asymmetry of the porcine coronary vasculature and its implications on coronary flow heterogeneity

The branching pattern of the coronary arteries and veins is asymmetric, i.e., many small vessels branch off of a large trunk such that the two daughter vessels at a bifurcation are of unequal diameters and lengths. One important implication of the geometric vascular asymmetry is the dispersion of blood flow at a bifurcation, which leads to large spatial heterogeneity of myocardial blood flow. To document the asymmetric branching pattern of the coronary vessels, we computed an asymmetry ratio for the diameters and lengths of all vessels, defined as the ratio of the daughter diameters and lengths, respectively. Previous data from silicone elastomer cast of the entire coronary vasculature including arteries, arterioles, venules, and veins were analyzed. Data on smaller vessels were obtained from histological specimens by optical sectioning, whereas data on larger vessels were obtained from vascular casts. Asymmetry ratios for vascular areas, volumes, resistances, and flows of the various daughter vessels were computed from the asymmetry ratios of diameters and lengths for every order of mother vessel. The results show that the largest orders of arterial and venous vessels are most asymmetric and the degree of asymmetry decreases toward the smaller vessels. Furthermore, the diameter asymmetry at a bifurcation is significantly larger for the coronary veins (1.7-6.8 for sinus veins) than the corresponding arteries (1.5-5.8 for left anterior descending coronary artery) for orders 2-10, respectively. The reported diameter asymmetry at a bifurcation leads to significant heterogeneity of blood flow at a bifurcation. Hence, the present data quantify the dispersion of blood flow at a bifurcation and are essential for understanding flow heterogeneity in the coronary circulation.     

Characteristics of coronary vasodilation reserve in partial restriction and subsequent recovery of the coronary blood flow

The studies were performed on anesthetized dogs using the model of partial controlled blood flow restriction in the left circumflex coronary artery with intact thorax. 70% of blood flow restriction were compensated by coronary vasodilation reserve, evaluated in hyperemia reaction. No rapid reperfusion hyperemia reaction was observed in reperfusion period, while moderate reduction in heart contractility was maintained. Alterations in coronary vessel reactivity could have a certain depressing effect on reperfusion hyperemia reaction. The observed changes were reversible, as coronary vessels retained their dilatation ability in response to an additional ischemic stimulus.     

Simulation of coronary circulation with special regard to the venous bed and coronary sinus occlusion

The vascular beds of the left circumflex and the left anterior descending coronary arteries are modelled by means of coupled differential equations that consider an arterial, a capillary and a venous section. In a stepwise procedure, experimental data from normal coronary perfusion and coronary sinus occlusion are used to assess the model parameters. For venous distensibility, a non-linear form of pressure-volume relationship proved vital to reproduce the characteristics of the rise in venous pressure after the onset of coronary sinus occlusion. Numerical integration was carried out for normal perfusion and for coronary sinus occlusion, yielding time courses of flows, volumes and pressures within large coronary arteries, capillaries and coronary veins. Coronary sinus occlusion reduces total mean flow by 18% and divides intramyocardial flow between the capillaries and the veins into a forward component of 3.03 mls⁻¹ and a backward component of − 1.54 mls⁻¹. This result represents a prediction for a haemodynamic quantity which is therapeutically important but inacessible to measurement. Varying degrees of systolic myocardial squeezing are studied to display the impact of myocardial contractility and vessel collapse on the mean values and phasic components of intra-myocardial flows.     

Roots and calibers of the human coronary arteries

The anatomical structure of the coronary-aortic junctions in humans is studied by using corrosion casts of the coronary network. A model is proposed for the specification of these junctions in terms of vessel diameters and branching angles, and the model is used to produce morphological data on these junctions which hitherto have not been available. This anatomical model correlates poorly with the accepted theoretical model of arterial bifurcations in the cardiovascular system. The results suggest that the structure of the coronary-aortic junctions is very different from the structure of typical arterial bifurcations and, by implication, that the flow conditions under which they function are very different. A good understanding of these junctions is important in coronary bypass surgery, where the coronary-aortic junctions are emulated by creating a new anastomosis for the graft at the base of the ascending aorta, and in coronary artery disease, where atherosclerotic lesions occur not far from the coronary-aortic junctions.     

Women and the management of acute coronary syndrome

Coronary heart disease (CHD) is the leading cause of morbidity and mortality in both men and women in the developed countries. Despite this fact, females are still under-represented in the majority of clinical trials. At the present time, only limited evidence is available with respect to the female-specific aspects of pathogenesis, management, and outcomes in acute coronary syndrome (ACS). Women less frequently undergo coronary intervention, and a lower proportion of women receive evidence-based pharmacotherapy, compared with men. It has been shown that women benefit from an invasive approach and coronary intervention in ACS as much as men, despite their advanced age and higher rate of bleeding complications. Also, administration of beta-blockers, ACE-inhibitors, and intensive statin therapy is associated with a comparable reduction of cardiovascular event rates in women and men. On the other hand, women may profit less than men from fibrinolytic or glycoprotein IIb/IIIa inhibitor therapy. Both sexes benefit equally from aspirin therapy, whereas contradictory data are available on the efficacy of clopidogrel in women. There is an urgent need for intensive research in the development of female-specific therapeutic strategy in ACS, even though the detailed mechanisms of sex differences are still unknown.     

Embryonic development of the proepicardium and coronary vessels

In the last few years, an increasing interest in progenitor cells has been noted. These cells are a source of undifferentiated elements from which cellular components of tissues and organs develop. Such progenitor tissue delivering stem cells for cardiac development is the proepicardium. The proepicardium is a transient organ which occurs near the venous pole of the embryonic heart and protrudes to the pericardial cavity. The proepicardium is a source of the epicardial epithelium delivering cellular components of vascular wall and interstitial tissue fibroblasts. It contributes partially to a fibrous tissue skeleton of the heart. Epicardial derived cells play also an inductive role in differentiation of cardiac myocytes into conductive tissue of the heart. Coronary vessel formation proceeds by vasculogenesis and angiogenesis. The first tubules are formed from blood islands which subsequently coalesce forming the primitive vascular plexus. Coronary arteries are formed by directional growth of vascular protrusions towards the aorta and establishing contact with the aortic wall. The coronary vascular wall matures by attaching smooth muscle cell precursors and fibroblast precursors to the endothelial cell wall. The cells of tunica media differentiate subsequently into vascular smooth muscle by acquiring specific contractile and cytoskeletal markers of smooth muscle cells in a proximal - distal direction. The coronary artery wall matures first before cardiac veins. Maturity of the vessel wall is demonstrated by the specific shape of the internal surface of the vascular wall.     

Myocardial blood volume and coronary resistance during and after coronary angioplasty

Animal experiments have shown that the coronary circulation is pressure distensible, i.e., myocardial blood volume (MBV) increases with perfusion pressure. In humans, however, corresponding measurements are lacking so far. We sought to quantify parameters reflecting coronary distensibility such as MBV and coronary resistance (CR) during and after coronary angioplasty. Thirty patients with stable coronary artery disease underwent simultaneous coronary perfusion pressure assessment and myocardial contrast echocardiography (MCE) of 37 coronary arteries and their territories during and after angioplasty. MCE yielded MBV and myocardial blood flow (MBF; in ml · min(-1) · g(-1)). Complete data sets were obtained in 32 coronary arteries and their territories from 26 patients. During angioplasty, perfusion pressure, i.e., coronary occlusive pressure, and MBV varied between 9 and 57 mmHg (26.9 ± 11.9 mmHg) and between 1.2 and 14.5 ml/100 g (6.7 ± 3.7 ml/100 g), respectively. After successful angioplasty, perfusion pressure and MBV increased significantly (P < 0.001 for both) and varied between 64 and 118 mmHg (93.5 ± 12.8 mmHg) and between 3.7 and 17.3 ml/100 g (9.8 ± 3.4 ml/100 g), respectively. Mean MBF increased from 31 ± 20 ml · min(-1) · g(-1) during coronary occlusion, reflecting collateral flow, to 121 ± 33 ml · min(-1) · g(-1) (P < 0.01), whereas mean CR, i.e., the ratio of perfusion pressure and MBF, decreased by 20% (P < 0.001). In conclusion, the human coronary circulation is pressure distensible. MCE allows for the quantification of CR and MBV in humans.     

Percutaneous closure of a coronary fistula between the right coronary artery to the left atrium

We describe a case of a congenital coronary artery fistula of the right coronary artery draining into the left atrium in an eight-year-old boy. The initial diagnosis was made after the detection of a continuous cardiac murmur at the age of six years. Transthoracic echocardiography showed the right coronaric ostium dilatation, the site of drainage in the left atrium and left ventricle volume overload. Catheterization confirmed the diagnosis. The patient underwent percutaneous closure by PDA occluder device. Immediate post-closure angiograms showed complete occlusion of the fistula. The patient showed transient ischemic changes on ECG associated to an increase of plasmatic levels of the cardiac enzyme. ECG and cardiac enzyme were normal one week after the procedure.