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ORIGINAL ARTICLE

Myocardium stress diskinesia disease

Otoni Moreira Gomes; Eros Silva Gomes; Marcílio Faraj

DOI: 10.1590/S0102-76382004000400009

INTRODUCTION

Since the studies of PARDEE in 1920 [1], alterations in electrocardiograms (ECG) of myocardial ischemia patients have been well defined, characterizing the relationship between the anomalous Q waves with inactive zones due to necrosis and consequent fibrosis, the ST segment deviated by the pre-necrotic ischemic lesion and T wave alterations by the establishment of ischemia in its earliest phases.

The advent and evolution of the diagnosis of coronary insufficiency by induced stress increased even more the importance of the analysis of ST segment deviations, not only because of the diagnostic specificity in itself, but also because of evidence of its almost immediate reversibility with the cessation of ischemia-inducing stress. Individual differences in the electrocardiographic responses to stress, with varying patterns of the ST deviation in individuals with normal coronary arteries, motivated the need of improvement in the criteria and the introduction of analysis of the J and Y points, which among other things facilitated the interpretation of descending and ascending ST designs (concave or convex). Even so there are still cases of induced ST variations diagnosed as false positive or false negative, that is, imprecise sensitivity and specificity.

It is also well known that individuals presenting with partial obstructive coronary disease, ventricular hypertrophy or significant overloads during stress, preserve the normal ST pattern, whilst others, without diagnosed heart disease, evolve with significant changes of the ST segment, specifically at point J, with maximum responses at higher heart rates. These patients, even with normal coronary arteries or with non-occlusive parietal alterations evidenced by scintigraphic or angiographic studies, generally present with a syndromic profile defined by atypical precordial or retrosternal pain reducing their physical capability and a horizontal depression of the ST segment, marked by a 2-millimeter depression or greater at point J and a normal point Y or one with less than one-millimeter of depression.

The horizontal depression of the ST segment has been interpreted (not rarely as a physiological response of tachycardia) as dependent on the heart beat [2], with DETRANO et al. [3] in 1986 and LACHTERMAN et al. [4] in 1990 studying the ST/FC stress induced index, as a diagnostic element in exercise stress testing. Even so, this interpretation has been contested, demonstrating that it does not have a greater diagnostic significance than the simple ST variations [5-8].

In 1984, PIC & BROUSTED [9] observed that the ST depression in isolation presents a sensitivity rate of 72.5% and a specificity rate of 62.5% in patients without previous infarction, an increase in the R-wave sensitivity 58.5% and specificity 67.5% (or of the QRS with 78% and 57.5%, respectively) and the pain 63% and 75%. The three together positively diagnosed in 100% of cases. The positivity of only one signal corresponds to normal coronary arteries in most cases. This difficulty in guaranteeing the electrocardiographic diagnosis to guide patients is continuously being highlighted in recent studies [10-12].

KURL et al. [13] in 2003 demonstrated a significant increase in cardiovascular death rate (3.5 times greater) and death due to brain strokes (2.2 times greater) in asymptomatic patients with a horizontal depression of the ST segment during exercise stress testing.

These results prove to be risk free only for patients where the basal ECG is normal and the TE normal. In all other circumstances, they seem to indicate the need of complementary angiographic, angiokinetic or scintigraphic studies with cineangiography being the most reliable for a definitive diagnosis.

Definitive studies that diagnose patients without coronary artery obstructions and alterations of the ST segment seen during exercise stress tests with sufficient precision over the long-term are still rare and relatively incomplete. However, there is already sufficient evidence to justify preventative treatment in these cases, so that the risks to which patients are exposed are not ignored [13].

The challenge includes a search for other etiopathogenic factors, as well as arriving at a consensus that silent myocardial ischemia depends only on coronary vascular disease.

Taking the classic pattern of ST segment with deviations of less than 1 mm as normal and considering additional deviations of the ST segment as ischemic, the possibility of an asymmetric response between the myocardial oxygen demand and the dynamics of the coronary reserve in these patients is acceptable, (a) by the intensity in the contraction produced being greater than that necessary for systolic outflow and for the existent peripheral demand, (b) by the inferior reflex vasodilation necessary for the existent contractile demand or (c) due to the atypical and heterogeneous pattern of the myocardial sectorial myofibrillar contraction. Under these conditions, the areas of less spastic contraction may act with a steal effect from the areas of more intense contraction.

An interpretation of the asymmetric intramural contractions corroborates with the results published by Lins [14], demonstrating the appearance of an intraventricular pressure gradient in the echocardiographic study using induced stress in a group of patients with positive exercise stress tests.

Accepting abnormal myocardial contractions as the main generator of the ischemic condition, highlights the role of adrenergic inotropic stimulants and Calcium++ dependents. Evidence that patients being treated for hypertension using beta-blockers also presented silent depression of the ST segment, suggests that mechanisms dependent on transmembrane calcium flow are involved in the genesis of the disorder.

It is been demonstrated that in the first phases of myocardial ischemia contraction bands can occur together with the reduction of cytoplasmatic glycogen, impeding normal myofibrillar relaxation and making ventricular diastole difficult, a fundamental factor in the increased calcium++ flow into the myocell. These cases support the use of calcium antagonists as the first therapeutic option, not only because of the specific physiopathologic and pharmacokinetic implications, but also due to experience based on their use, biocompatibility and multiple cardiovascular benefits.

The aim of this present investigation is to analyze the results of a study of patients with atypical precordial pain, without obstructive coronary disease, submitted to exercise stress testing with or without treatment using diltiazem myocytic calcium-inhibitor.

METHOD

With the approval of the Bio-ethics Commission of the Institution, ten consecutive patients were studied in the Laboratory of stress exercise tests (FCSFAServcor). The exercise stress test was defined as positive when a horizontal depression of the ST segment occurred without precordial pain or arrhythmia during the examinations. Six (60%) patients were men and the ages of the patients ranged from 42 to 71 years (mean age 58.2 years). All the patients of the present series were restudied five days after being treatment with three daily doses of 90 mg of diltiazem.

The examinations were performed on a computerized treadmill (model Digistress/ MG), following the Bruce protocol. The J (STj) and Y (Sty) point variations of the ST segment, the maximum VO2 reached (mL/kg/min), heart rate (bpm), the double product (DP), the METs reached and the functional class (AHA) were analyzed, using the following criteria: 1- excellent, 2- good, 3-regular (medium), 4- weak and 5- very weak.

The Student t-test was employed to evaluate the statistical significance of differences between two parallel samples, with the level of significance was fixed with a p-value < 0.05. The EPIINFO version 6.04 computer program of the World Health Organization was used.

RESULTS

Table 1 presents the obtained results. It was confirmed that the administration of calcium-inhibitors impedes depression of the ST segment, both at point J (mean horizontal depression 2.1 ± 0.3 mm for controls, and 0.0 depression with treatment - p<0.001) and at point Y (horizontal depression of 1.65 ± 0.7 mm for controls, and 0.0 depression with treatment - p< 0.001). The heart rate did not present with statistically significant variations (average 156.1 ± 12.3 bpm in the controls and 151.6 ± 23.4 bpm with treatment - p-value > 0.05). There was a statistically significant improvement in the functioning (p-value < 0.05) with the treatment (mean 2.6 ± 0.7 in controls and 1.9 ± 0.7 after treatment), without significante differences in the VO2 or in the double product (p>0.05).



In two patients, the horizontal depression of the ST segment did not appear homogeneous in all complexes in each of the derivations analyzed, but the alterations were manifested progressively, with an appearance of claudication and pathologic complexes in with alternate anachronic and normal complexes on the same derivation (Figure 1).



COMMENTS

The consensus that deviations of the ST segment are more reliable to confirm myocardial ischemia during exercise stress testing compared to other hemodynamic or electrocardiographic variables (arrhythmia, Q wave or R wave alterations) is well known [15].

The current universal consensus of a relationship between induced stress ischemia, evidenced by silent depression of the ST segment, with coronary artery perviousness does not adequately explain cases of normal coronary arteries, nor does it offer perspectives of therapeutic options for the patients involved.

When considering another possible cardiovascular nosologic entity responsible for the ST segment depression in patients without organic coronary lesions and without defined heart disease, the following physiopathologic factors are especially interesting: the physiologic mechanism of supply-demand in the myocardial metabolism and interactive physiopathology of the ischemic degenerative alterations (with electrocardiographic and pharmacokinetic signs) of the transmembrane activation/inhibition of myocardial contraction and angiokinesis.

Mechanism of supply-demand in the myocardial metabolism

The preservation of the myocardial integrity depends basically on the relation between the supply and demand of essential metabolic substrates, with the coronary arterial blood flow as the factor responsible for cellular supply. In adverse circumstances, the cellular mechanisms of the coronary reserve and ischemic adaptation are determinants which respond to the myocardial survival capacity.

The phenomenon of coronary reserve can be demonstrated in flowmetry by the reactive hyperemia that follows occlusion of a coronary artery at an interval of ten seconds. Even occlusions of only one second cause reperfusion at an increased flow rate, estimated as normal hyperflow when levels are five times the basal rate, that is, from 250 mL to 1250 mL/min, or from 0.9 mL/g of myocardium to 4.5 mL/g [16]. Coronary artery diseases, including endothelial dysfunction and alterations in the extra-vascular resistance factor, can significantly alter the coronary reserve.

Ischemic adaptation is the resource by which the myocardium is able to present sensitive changes in its oxygen needs to protect itself from ischemia, whether reducing its inotropism and myofilamentar tension, or changing enzymatic channels to reduce energy use. The phenomenon of ischemic adaptation is well characterized in ischemic preconditioning, where it has been consistently demonstrated that a brief period of ischemia, succeeded by another period of reperfusion, increases the tolerance of the myocardium to anoxia and prolongs the time necessary for degeneration to necrosis [17], with the following beneficial effects demonstrated: reduction of the intensity and frequency of anginal events - warm up phenomenon, horizontal depression of the ST segment, depletion of PTA, enzyme release (CK-MB, troponin), production of lactic acid and free radicals, apoptosis, ultra-structural injury, infarction area, the incidence of arrhythmia, noxious remodeling, activation of leukocytes, hospitalization, with reduction of mortality and protection of the endothelium during reperfusion.

Although a simple episode of transitory ischemia can produce heart protection, repetitive episodes of brief periods of occlusion, if they are frequent, can cause trachyphilaxy resulting in myocardial injury.

Any expression of the proprieties of adaptation/ischemic resistance will depend on the evolution of the myocardial ischemia for the conditions of integral recovery, necrosis, stunning or hibernation. Stunning, which is the maximum reversible ultrastructural lesion and hibernation representing the condition of tissue survival with optimized minimum flow, by the maximum ischemic adaptation capacity or minimum sustainable metabolic reserve?

Electrocardiographic signal of myocardial ischemia

The correlation between the evolution of acute myocardial ischemia and the pattern of electrocardiographic register is sufficiently defined, with the T wave altered at the start of ischemia, the ST segment showing the progression of cellular degeneration and the Q wave diagnosing the definitive establishment of necrosis. All these signs are intimately linked to variations in the ionic flow of the cellular membrane and modifications resulting from the transmembrane potential. It is notable that the ECG can remain unaltered even in situations of complete inactivation of the myocardial contraction, even in mechanical uncoupling, which is reproducible in the laboratory using drugs. With this limitation always in view, is it possible to make a correlation between the biochemical and histopathologic phases of ischemia and alterations on the ECG.

Basically, the following phases can be considered for myocardial ischemia: 1 - cytoplasmatic hypoxia with a reduction in the pH, reduction of the ionic pumping activity and the start of the formation of oxygen free radicals; 2 - Edema and vacuolization of mitochondrias; 3 - Rupture of mitochondrias and of the myofibrils; 4 - karyolysis and 5 - Fibrosis of substitution. The first and the second phases are rapidly induced and reversible; the second generally appears after 5-10 minutes of ischemia and the third phase marks the start of necrosis, which generally occurs after 15-20 minutes of normothermic ischemia, with reversibility depending of the extension of the injured area and capacity of viable sustentation of the myocardium [18-22]. The myocardial ischemic stunning can be between phases 2 and 3 with most lesions reversible.

Basically, it is known that the variations of the T wave happen in the first phase and those of the ST segment correspond to lesions in the second and third phases and the Q wave marks the necrotic areas of Phases 4 and 5.

This interpretation valorizes the appearance of the horizontal depression of the ST segment as representative of regional myocardial involvement always accompanied by histologic myocardial aggression, however little, whose intensity will define the velocity of the tissue recovery and the normalization of the ECG, which is also influenced by the velocity and efficiency of reperfusion.

Physiopathology of ischemia with silent depression of the ST segment

The etiopathological correlation of the transmembrane disorder of calcium flow, as a marker of silent stress ischemia without coronary arterial disease, has clinical proof of cause and effect in electrocardiographic alterations present in the surgical post-cardioplegia myocardial reperfusion, in patients presenting with hyperpotassemia (K+ > 7 mEq/L) and hypocalcaemia (Ca++ < 7 mg/dL): the electrocardiogram presents ST horizontal depression with the T wave negative, similar to the "Pardee Complex" of acute infarction, progressively corrected until complete normalization is achieved by the endovenous use of calcium gluconate and renal depuration of the potassium [23, 24].

Such solid physiopathologic evidence justified the hypothesis of treatment of the disorder using a calcium inhibitor.

The initial results so far (shown in Table 1), confirmed this physiopathologic and pharmacokinetic evidence. Note that treatment with diltiazem normalized the response to exercise stress test.

It is notable, in respect to the data, that maintenance of heart frequency was possible without the ischemic signs seen in the control group and without therapeutic stabilization.

On the other hand, myocardial disease with diskinetic contraction-perfusion, as it is related to the progressive functional response of the heart muscle, presupposes the possibility of installation and progressive regional extension of the contraction-perfusion asymmetry. This is a fact not infrequently observed in these patients, with the initial appearance of alternate or claudicant horizontal depression of the ST segment, to the establishment of a uniform definition of the regional involvement with the continuation of effort. Figure 1 demonstrates an example of this phenomenon.

The ischemic stress marker does not have a fixed pattern in the ventricular anatomy and can occur only in the inferior, lateral or anterior walls or be generalized and is diagnosed as a diskinetic condition of the myocardial contraction with regions showing different patterns of contraction/relaxation. The ischemic claudication phenomenon, with complexes of normal ST segments with intermittent ischemic patterns, similar to focal zones of tetany/spasms that do not affect the basic hemodynamic performance is not rare. This is similar to what happens in the skeletal musculature, with the manifestation of myalgia and local contractures (only precursory of cramps and contractures) which do not impede the performance but induce fatigue quicker. Figuratively, myocardial dyskinesia can function as an opening and closing of manual pumping, as if one or more fingers contract at different levels of tension, without prejudicing the total compression force, enabling the ventricles to maintain the systolic outflow and the hemodynamic stability.

Etymologically speaking, disease is "the lack or any disorder of the health [25]" and, thus, depression of the ST segment identifies existent heart diseases, such as obstructive coronary disease and myocardial hypertrophies. Innumerous lethal organic diseases also present silent evolution with totally asymptomatic phases and of extremely difficult diagnosis, with lethal results as one of their first clinical manifestations for examples the rupture of brain aneurysms and thromboembolic states and the always feared tumoral metastases.

Thus, the myocardial condition responsible for the appearance of effort-induced depression of the ST segment, even without organic obstructive coronary lesions is an important disease, which over the long-term causes higher morbid-mortality rates compared to other diseases, even congenital or acquired heart diseases.

The social aspect of the problem, in some studies, is similar to incidence of hypertension, with possible significant regional variations [26-28], as the positive exercise stress test in asymptomatic patients includes from 0.6 to 15% of the studied population (eight studies). In a maximum of 0.06 to l.6% cases this is associated with significant arterial disease (narrowing of 50% or more of the epicardial coronary artery), suggesting that stress myocardial dyskinesia is a disease occurring in 0.54 to l3.4% of the asymptomatic population [29]. KURL et al.[13], in 2003, demonstrated a significant increase in cardiovascular death (3.5 times greater) and of strokes (2.2 times greater) in asymptomatic individuals with horizontal depression of the ST segment evidenced during exercise stress testing.

Evidence that silent depression of the ST segment can be cured with drugs highlights the importance of adhesion of the patient to treatment. The classification of the problem as a reversible disease offers highly favorable psychological support, in contrast with the anxiety caused by the insecurity and lack of definition of its pleomorphic symptomatology, with a reduction of the physical aptness and pseudo-anginal algic sensations. The constructive emotion of the safety and satisfaction of patients is clearly seen when they are informed that the ECG has normalized after treatment.

The ideal situation is that all patients with stress myocardial dyskinesia without coronary arterial disease, a condition which defines the nosology, are completely studied in respect to the normality of the coronary arteries. However, the condition of public health system is complex, because the number of positive cases is relatively small and the negative cases high. On the other hand the evidence shows that the disease increases considerably the morbid-mortality of individuals, thus it requires special preventive treatment.

The initial experience of our institution, supporting the use of 90-120 mg diltiazem three times daily, highlights another significant aspect of the study. Re-synchronization of the myocardial contraction/perfusion by the drug appears to be a diagnostic test option to improve the criterion of the indication of complementary studies of coronary perviousness. As Antônio Felipe Simão and Maurício Nunes assure us there are no drugs, in acceptable clinical doses, able to normalize exercise stress testing in patients with significant coronary obstructions. Moreover, the use of diltiazem increases the safety in the initial period of rehabilitation, until effective myocardial conditioning, allowing a faster improvement of the functional performance, as occurred in previously treated patients, providing psychological and functional benefits of motivation and adherence.

Recent research suggests, without sufficient proof of cause, the occurrence of myocardial perfusion disorders of the microcirculation in the postoperative period of coronary revascularization [30]. From this it can be inferred that dyskinesia of myocardial contraction may also influence the direction of intramyocardial flow patterns, determining postoperative ventricular functional alterations. There are no studies yet comparing the evolution of these patients.

In a general analysis, the results obtained in the current investigation, without similar results reported in the literature, indicate a disorder of the myocardial contraction synchronism is another factor of silent ischemia induced by exercise stress, efficiently treated using diltiazem calcium inhibitor.

As frequently in preliminary clinical research, the small sample size, notwithstanding its absolute statistical significance and the restricted number of parameters analyzed, suggest the necessity of further investigations to provide an uncontestable scientific definition of the phenomenon observed.

BIBLIOGRAPHIC REFERENCES

1. Pardee HEB. An electrocardiographic sign of coronary artery obstruction. Arch Intern Med 1920;26:244-57.

2. Okin PM, Kligfield P. Computer-based implementation of the ST-segment/heart rate slope. Am J Cardiol 1989;64:926-30.
[ Medline ]

3. Detrano R, Salcedo E, Passalacqua M, Friis R. Exercise electrocardiographic variables: a critical appraisal. J Am Coll Cardiol 1986;8:836-47.
[ Medline ]

4. Lachterman B, Lehmann KG, Detrano R, Neutel J, Froelicher VF. Comparison of ST segment/heart rate index to standard ST criteria for analysis of exercise electrocardiogram. Circulation 1990;82:44-50.
[ Medline ]

5. Froelicher VF, Lehmann KG, Thomas R, Goldman R, Morrison D, Edson R et al. The electrocardiographic exercise test in a population with reduced workup bias: diagnostic performance, computerized interpretation, and multivariable prediction. Ann Intern Med 1998;128:965-74.
[ Medline ]

6. Okin PM, Grandits G, Rautaharju PM, Prineas RP, Cohen JD, Crow RS et al. Prognostic Value of heart rate adjustment of exercise-induced ST segment depression in the multiple risk factor intervention trial. J Am Coll Cardiol 1996;27:1437-43.
[ Medline ]

7. Okin PM, Anderson KM, Levy D, Kligfield P. Heart rate adjustment of exercise-induced ST segment depression: improved risk stratification in the Framingham Offspring Study. Circulation 1991;83: 866-74.
[ Medline ]

8. ACC/AHA 2002 Guideline Update for Exercise Testing: Summary Article. Circulation 2002;106:1883-903.

9. Pic A, Broustet JP. Diagnostic value of amplitude variations of the QRS complex during in computerized exercise testing. Arch Mal Coeur Vaiss 1984;77:54-63.
[ Medline ]

10. Severi S, Orsini E, Marracini P, Michelassi C, L'Abbate A. The basal electrocardiogram and the exercise stress test in assessing prognosis in patients with unstable angina. Eur Heart J 1988;9:441-6.
[ Medline ]

11. Fruegaard P, Launbjerg J, Jacobsen HL, Madsen JK. Seven-year prognostic value of the electrocardiogram at rest and an exercise test in patients admitted for, but without, confirmed myocardial infarction. Eur Heart J 1993;14:499-504.

12. Grundy D, Gibler WB, Bassan R. O eletrocardiograma e o monitor de tendência do segmento ST na avaliação diagnóstica e no prognóstico da dor torácica. In: Bassan R, editor. Síndrome coronariana aguda nas unidades de dor torácica. Rio de Janeiro:Atheneu;2000. p.71-95.

13. Kurl S, Laukkanen JA, Tuomainen TP, Rauramaa R, Lakka TA, Salonen R et al. Association of exercise-induced, silent ST-segment depression with the risk of stroke and cardiovascular disease in men. Stroke 2003;34:1760-5.

14. Lins RHC. Gradiente intraventricular de estresse. In: Simpósio do Departamento de Fisiologia Cardiovascular e Cardiologia Experimental. 59o Congresso da Sociedade Brasileira de Cardiologia. Rio de Janeiro:Sociedade Brasileira de Cardiologia;2004.

15. Uchida AH, Canabrava MVF. Teste ergométrico em assintomáticos: uma análise baseada em evidências. Revista DERC 2004;10:18-9.

16. Gould KL. Coronary artery stenosis. New York:Elsevier Science Publishers;1991.

17. Murry CE, Jennings RB, Reimer KA. Preconditioning with ischemia: a delay of lethal cell injury in ischemic myocardium. Circulation 1986;74:1124-36.
[ Medline ]

18. Gomes OM. Análise comparativa das alterações ultra-estruturais e bioquímicas determinadas no miocárdio, pelas paradas cardíacas anóxicas normotérmica e hipotérmica (20ºC): estudo experimental. [Tese de doutorado]. São Paulo:Faculdade de Medicina da Universidade de São Paulo,1975.

19. Gomes OM, Weigl DR, Pedroso FI, Gomes ES, Faraj M, Carvalho JI et al. Cardioplegia diastólica: o fator endotelial e o paradoxo do ATP na parada cardíaca hipotérmica. Coração 1995;5:9-18.

20. Gomes OM, Weigl DR, Pedroso FI, Pitchon M, Caetano MC, Oliveira NA et al. Classificação das lesões anóxicas ultramicroscópicas do miocárdio. Coração 1991;2:5-9.

21. Braile DM. Fisiopatologia da proteção miocárdica. In: Martins AS, editor. Proteção miocárdica e função ventricular. Botucatu:Editora Cultura Acadêmica;2004. p.13-44.

22. Martins AS, Matsubara BB, Braile DM, Gomes OM. Proteção miocárdica e função ventricular. Botucatu:Editora Cultura Acadêmica;2004.

23. Gomes OM. Síndromes da proteção miocárdica. Coração 1992;2:3-5.

24. Gomes OM. Myocardial protection distress. CN NetWork 2002;1:19.

25. Ferreira ABH. Novo dicionário da Língua Portuguesa. Rio de Janeiro:Editora Nova Fronteira;1975.

27. Gomes OM, Crizola R, Kazzaz NM, Anjos MLM, Caetano MC, Pitchon M et al. Censo pressórico: estudo Belo Horizonte. Coração 1989;1:20-5.

28. Gomes OM, Caetano MC, Pitchon M, Teixeira RMB, Barros MVL, Gomes ES et al. Censo pressórico: estudo Belo Horizonte II/Seguimento tardio. Coração 1990;2:13-6.

29. Fowler-Brown A, Pignone M, Pletcher M, Tice JA, Sutton SF, Lohr KN. Exercise tolerance testing to screen for coronary heart disease: a systematic review for the technical support for the US Preventive Services Task Force. Ann Inter Med 2004;140:W9-24.

30. Spyrou N, Khan MA, Rosen SD, Foale R, Davies DW, Sogliani F et al. Persistent but reversible coronary microvascular dysfunction after bypass grafting. Am J Physiol Heart Circ Physiol 2000;279:H2634-40.

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