[Coronary disease: early intervention saves lives. Treatment of acute myocardial infarction in Mantova: results of thirty months of work after the implementation of a province network]. / Malattia coronarica: l'intervento precoce salva la vita. Terapia dell'infarto miocardico acuto a Mantova, risultati di trenta mesi di attivita' dopo l'attivazione di una rete provinciale.

BACKGROUND: Since June 2001, in the province of Mantova, we have undertaken a program for the management of acute myocardial infarction based on the early assessment of patient risk profiles, concerning telematic connections among care centers and on the optimization of in-hospital and out of hospital critical pathways for access to care. MATERIALS AND METHODS: Our network provides connections among the following centers: advanced life support ambulances, seven hospitals, three coronary care units, one cath lab on call 24 h a day for primary angioplasty, and one thoracic surgery division. This program, through its strong telematic platform, allows the early assessment of myocardial infarction and provides primary angioplasty to all high-risk patients, as fibrinolytic treatment is reserved only for low-risk patients admitted in peripheral hospitals. RESULTS: Two hundred and eighty patients with acute myocardial infarction were treated with angioplasty; 224 patients (80%) underwent primary angioplasty, 36 patients (13%) facilitated angioplasty and 20 patients (7%) rescue angioplasty. One hundred and thirty-two patients (47%) were first admitted to Mantova Hospital; 78 patients (28%) were referred to Mantova from peripheral hospitals and 70 patients (25%) were directly transported to the cath lab by advanced life support ambulances. Procedural success was obtained in 98% of patients, with 0.4% intraprocedural mortality. In-hospital mortality was 5.7%, while mortality in cardiogenic shock patients was 36%. The recurrence of acute myocardial infarction occurred in 1% of patients and major bleeding occurred in 2.2% of patients. One patient with cardiogenic shock died during transport. Mean door to balloon time was 67 min with a 42% reduction in the 3rd recruitment period. CONCLUSIONS: This program, developed in the setting of a provincial network for the management of acute myocardial infarction, provided primary angioplasty to all high-risk patients, with a high procedural success rate. Within a few months, time to treatment was minimized by the use of telematic facilities.

Coronary artery bypass grafts in a patient with isolated cardiac dextroversion.

Despite several controversies, the term "dextrocardia" usually defines a rare type of intrinsic cardiac abnormality due to a rotation disorder and resulting in a right-sided direction of the cardiac axis. According to the majority of experts, the extent of a dextrocardia associated with a situs solitus is termed "dextroversion". In such a rare condition, therefore, the relationships between the cardiac chambers and the other structures (that is superior and inferior venae cavae, liver, stomach) are modified whereas in case of dextrocardia with situs inversus, the relationships between the cardiac chambers and neighboring structures are preserved and the classical "mirror image" is shown. In 95% of cases with dextroversion, an associated cardiac abnormality has been described and, therefore, acquired heart diseases in patients with isolated dextroversion are extremely rare. To our knowledge, the present is the first case report describing a coronary artery bypass graft performed in a patient with isolated dextroversion. The technical aspects of the surgical procedure are also discussed.

New insights on myocardial pyridine nucleotides and thiol redox state in ischemia and reperfusion damage.

OBJECTIVE: to investigate the changes of pyridine nucleotides and thiol redox state in cardiac tissue following ischemia and reperfusion. NADH/NAD and NADPH/NADP redox couples were specifically studied and the influence of NADPH availability on cellular thiol redox was also investigated. METHODS: isolated rabbit hearts were Langendorff perfused and subjected to a protocol of ischemia and reperfusion. An improved technique for extraction and selective quantitation of pyridine nucleotides was applied. RESULTS: ischemia and reperfusion induced an increase in diastolic pressure, limited recovery in developed pressure and loss of creatine phosphokinase. Creatine phosphate and ATP were decreased by ischemia and only partially recovered during reperfusion. NADH was increased (from 0. 36+/-0.04 to 1.96+/-0.15 micromol/g dry wt. in ischemia, P<0.001), whereas NADPH decreased during ischemia (from 0.78+/-0.04 to 0. 50+/-0.06 micromol/g dry wt., P<0.01) and reperfusion (0.45+/-0.03 micromol/g dry wt.). Furthermore, we observed: (a) release of reduced (GSH) and oxidised glutathione (GSSG) during reperfusion; (b) decreased content of reduced sulfhydryl groups during ischemia and reperfusion (GSH: from 10.02+/-0.76 to 7.11+/-0.81 nmol/mg protein, P<0.05, and to 5.48+/-0.57 nmol/mg protein; protein-SH: from 280.42+/-12.16 to 135.11+/-17.00 nmol/mg protein, P<0.001, and to 190.21+/-11.98 nmol/mg protein); (c) increased content in GSSG during reperfusion (from 0.17+/-0.02 to 0.36+/-0.02 nmol/mg protein, P<0.001); (d) increased content in mixed disulphides during ischemia (from 6.14+/-0.13 to 8.31+/-0.44 nmol/mg protein, P<0.01) and reperfusion (to 9.87+/-0.82 nmol/mg protein, P<0.01). CONCLUSIONS: under severe low-flow ischemia, myocardial NADPH levels can decrease despite the accumulation of NADH. The reduced myocardial capacity to maintain NADPH/NADP redox potential can result in thiol redox state changes. These abnormalities may have important consequences on cellular function and viability.

Hibernating myocardium: its pathophysiology and clinical role.

Myocardial hibernation, as first defined by Rahimtoola, is a state of chronic contractile dysfunction in patients with coronary artery disease which is fully reversible upon reperfusion. Clinical conditions consistent with the existence of myocardial hibernation include unstable and stable angina, myocardial infarction heart failure, and anomalous origin of coronary arteries. The mechanisms of hibernation are not known. Morphological alterations have been described in the hibernating area of patients, but these information are strongly affected by the diagnostic criteria utilized to screen patients. It has been postulated that hibernation is an adaptive phenomenon occurring during ischemia. In this context, downregulation of contraction is not regarded as a consequence of energetic deficit, but as a regulatory event aimed at reducing energy expenditure, thereby maintaining integrity and viability. Thus, hibernation might bear a relationship to the phenomenon of low-flow perfusion-contraction matching, or repetitive stunning or preconditioning. Clear-cut evidence for the mechanism of hibernation in the clinical setting seems likely to remain elusive, because of the nature of the studies needed to document it. Current experimental evidence supports the view that hibernation, stunning, preconditioning, or their coexistence can be responsible for regional myocardial contractile dysfunction which is reversible upon reperfusion. These are all adaptive and protective phenomena independent of their terminology and strict definitions and do not always apply to the extremely complex situation of myocardial ischemia in man.

Metabolic derangement in ischemic heart disease and its therapeutic control.

The term myocardial ischemia describes a condition that exists when fractional uptake of oxygen in the heart is not sufficient to maintain the rate of cellular oxidation. This leads to extremely complex situations that have been extensively studied in recent years. Experimental research has been directed toward establishing the precise sequence of biochemical events leading to myocyte necrosis, as such knowledge could lead to rational treatments designed to delay myocardial cell death. At the present time, there is no simple answer to the question of what determines cell death and the failure to recover cell function after reperfusion. Problems arise because: (1) ischemic damage is not homogeneous and many factors may combine to cause cell death; (2) severity of biochemical changes and development of necrosis are usually linked (both the processes being dependent on the duration of ischemia) and it is impossible to establish a causal relation; and (3) the inevitability of necrosis can only be assessed by reperfusion of the ischemic myocardium. Restoration of flow, however, might result in numerous other negative consequences, thus directly influencing the degree of recovery. From the clinical point of view, we have recently learned that there are several potential manifestations and outcomes associated with myocardial ischemia and reperfusion. Without a doubt, ventricular dysfunction (either systolic or diastolic) of the ischemic zone is the most reliable clinical sign of ischemia, since electrocardiographic changes and symptoms are often absent. The ischemia-induced ventricular dysfunction, at least initially, is reversible, as early reperfusion of the myocardium results in restoration of normal metabolism and contraction. In the ischemic zone, recovery of contraction may occur instantaneously or, more frequently, with a considerable delay, thus yielding the condition recently recognized as the "stunned" myocardium. On the other hand, when ischemia is severe and prolonged, cell death may occur. Reperfusion at this stage is associated with the release of intracellular enzymes, damage of cell membranes, influx of calcium, persistent reduction of contractility, and eventual necrosis of at least a portion of the tissue. This entity has been called "reperfusion damage" by those who believe that much of the injury is the consequence of events occurring at the moment of reperfusion rather than a result of changes occurring during the period of ischemia. The existence of reperfusion damage, however, has been questioned, and it has been argued that, with the exception of induction of arrhythmias, it is difficult to be certain that reperfusion causes further injury. The existence of such an entity has clinical relevance, as it would imply the possibility of improving recovery with specific interventions applied at the time of reperfusion. In 1985, Rahimtoola described another possible outcome of myocardial ischemia. He demonstrated that late reperfusion (after months or even years) of an ischemic area showing ventricular wall-motion abnormalities might restore normal metabolism and function. He was the first to introduce the term "hibernating myocardium," referring to ischemic myocardium wherein the myocytes remain viable but in which contraction is chronically depressed. In this article we review our data on metabolic changes occurring during ischemia followed by reperfusion, obtained either in the isolated and perfused rabbit hearts or in ischemic heart disease patients undergoing intracoronary thrombolysis or aortocoronary bypass grafting.

Different outcomes of the reperfused myocardium: insights into the comments of stunning and hibernation.

There are several potential outcomes of myocardial ischaemia. When ischaemia is severe and prolonged, irreversible damage occurs and there is no recovery of contractile function. Interventions aimed at reducing mechanical activity and oxygen demand either before ischaemia or during reperfusion have been shown to delay the onset of ischaemic damage and to improve recovery during reperfusion. When myocardial ischaemia is less severe but still prolonged, myocytes may remain viable but exhibit depressed contractile function. Under these conditions, reperfusion restores complete contractile performance. This type of ischaemia leading to a reversible, chronic left ventricular dysfunction has been termed 'hibernating myocardium'. It is important clinically recognize hibernation as reperfusion of hibernating myocardium by angioplasty or heart surgery restores contraction and this correlates with long term survival. A third possible outcome after a short period of myocardial ischaemia is a transient post-ischaemic ventricular dysfunction, a situation termed 'stunned myocardium'.

Aorta and skeletal muscle NO synthase expression in experimental heart failure.

Nitric oxide (NO), the free radical that accounts for the biological activity of endothelium-derived relaxing factor, is synthesized from L-arginine by NO synthase (NOS). There is evidence that NO availability is reduced in the peripheral vasculature of patients with congestive heart failure (CHF). The aim of this study was to investigate the expression of NOS in the descending aorta and in the skeletal muscles of rats subjected to heart failure. The alkaloid, monocrotaline, was used to induce pulmonary hypertension and cardiac failure in rats. The expression of both the constitutive (ecNOS) and the inducible (iNOS) isoforms of the enzyme was assessed by Western blot analysis. In CHF animals, the ecNOS location in the aorta is altered: the endothelial protein expression is substantially reduced (from 0.083 +/- 0.012 to 0.003 +/- 0.004 OD/microgram total proteins, P < 0.001) whereas the expression of ecNOS in the smooth muscle is increased (from 0.024 +/- 0.004 to 0.059 +/- 0.009 OD/ microgram total proteins, P < 0.01). The total aortic ecNOS is diminished in CHF respect to control animals (0.062 +/- 0.009 v 0.107 +/- 0.013 OD/microgram total proteins, P < 0.01). On the contrary, no difference in ecNOS protein expression was observed in the extensor digitorum longus and soleus muscles. Furthermore, iNOS was not detected in any of the tissues considered. In conclusion, experimental CHF causes a re-setting of the ecNOS protein expression in the descending aorta but not in skeletal muscles. The reduced abundance of ecNOS in the aortic endothelium is consistent with the impairment of the vasodilating function reported in patients with CHF.

Activation of the neuroendocrine response in heart failure: adaptive or maladaptive process?

Congestive heart failure is a clinical syndrome in which the capacity of the heart to maintain cardiac output is impaired. As a consequence, blood pressure is threatened and endocrine and paracrine mechanisms are activated to preserve circulatory homeostasis and to maintain blood pressure. At terminal stages, a complex multiorgan syndrome develops with severe pump failure, intense systemic vasoconstriction, and avid water and sodium retention. Increasing evidence points to humoral circulating or locally synthesized substances as one of the causes of the terminal consequences of heart failure. Therefore, the hypothesis that the syndrome of heart failure is, at least in part, a humoral disease has developed and is obtaining scientific credibility. Consequently, the neuroendocrine response to heart failure is no longer viewed as a compensatory beneficial mechanism. Instead, we have learned through the years that pharmacological treatment aimed at reducing the effect of the neuroendocrine response is indeed clinically and prognostically advantageous for the patient.

Cardioprotective effect of angiotensin-converting enzyme inhibitors in patients with coronary artery disease.

Clinical and experiments study with angiotensin-converting enzyme (ACE) inhibitors suggest that these agents may improve coronary artery disease by acting at multiple sites in the series of events leading to end-stage heart disease. These agents reduce blood pressure, improve prognosis and symptoms in patients with severe heart failure and in patients after acute myocardial infarction with left ventricular dysfunction. They are useful in the early, acute phase of myocardial infarction. More recently, ACE inhibitors have been shown to reduce in vitro vascular hypertrophy, to attenuate arteriosclerosis, and to maintain endothelium function. Whether these effects occur at clinical levels is still uncertain. The exciting clinical data have led to the proposal that alteration of ACE activity, particularly in tissue, is an important factor in development and progression of CAD. The ACE system is complex, with endocrine, paracrine, and autocrine effects. ACE is present in cardiac and vascular tissue. Therefore, the beneficial effects of ACE inhibitors can be classified as "cardio" and "vasculo" protective. This article summarizes a number of independent and complementary mechanisms pointing to a role of ACE and ACE inhibition in coronary artery disease.