Author(s):
Osmar Antonio Centurión1,2, Fabiola Rodríguez2, Karina Scavenius2,Luis Miño2 and Orlando Sequeira2
Affiliation(s):
1Department of Health Sciences’s Investigation, Sanatorio Metropolitano, Fernando de la Mora, Paraguay
2Cardiology Department, Clinic Hospital, Asunción National University, San Lorenzo, Paraguay
Dates:
Received: 25 May, 2017; Accepted: 22 June, 2017; Published: 23 June, 2017
*Corresponding author:
Osmar Antonio Centurión, Professor of Medicine, Asuncion National University, Department of Health Sciences’s Investigation, Sanatorio Metropolitano, Teniente Ettiene 215 c/ Ruta Mariscal Estigarribia Fernando de la Mora, Paraguay, E-mail: @
Citation:
Centurión OA, Rodríguez F, Scavenius K, Miño L, Sequeira O (2017) Postoperative Atrial Fibrillation and its association with the Atrial Substrate and the electrophysiological properties of the Atrial Myocardium. J Cardiovasc Med Cardiol 4(2): 029-032. 10.17352/2455-2976.000046
Copyright:
© 2017 Centurión OA, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
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Main article text

Editorial

Postoperative atrial fibrillation (AF) has a high prevalence, affecting up to 45% of coronary artery bypass graft surgery patients within the first week of the operation [1-4]. Interestingly, asymptomatic AF was reported more likely to occur after the first 4 days following the cardiac surgery. Postoperative AF is associated with increased morbidity and several types of complications. It was associated with increased duration of hospitalization, with high healthcare costs, and has been associated with an increased incidence of stroke, the need for permanent pacemaker placement, and early and late mortality. Several factors were found to be associated with new-onset AF following multivariate analysis, including advanced age, higher Killip class or heart failure, hypotension, higher heart rate, history of hypertension, history of stroke, female gender, increased peak creatinine, and increased Creactive protein levels [5-9]. In addition, AF may adversely affect quality of life and is associated with a higher risk of acute heart failure, and with thromboembolic events. It has recently been demonstrated that early and late postoperative AF have different predictors [9]. Early postoperative AF is the one occurring within the first 5 days after cardiac surgery, and late postoperative AF is the one occurring between the 6 and 30 days after cardiac surgery. Late postoperative AF was associated with conventional risk factors of AF in the general population. However, early AF was associated with low body mass index, high CRP levels, and previous myocardial infarction, higher EuroScore, and higher age [10-13]. Moreover, patients who develop postoperative AF are more likely to have left atrial dilation. This finding may suggest that left atrial size should be considered as a good predictor of postoperative AF [12,13]. As an interesting intraoperative related matter, Bidar et al., have observed that aortic cross-clamp time was a strong predictor of 30-day postoperative AF [9]. They carefully recorded any AF episode within the 30 days after cardiac surgery using an external 1-lead trans-telephonic loop recorder with an auto-trigger for AF. Late postoperative AF was associated with longer aortic cross-clamp times. In addition, this observation suggests that postoperative AF occurs not only during the first postoperative days but also in the weeks thereafter [9]. This fact has implications against the early discontinuation of oral anticoagulation [14].

On the other hand, clinical studies aiming to investigate the pathogenesis of postoperative AF have demonstrated that inflammatory reactions and oxidative stress are the most important factors for its development. Inflammation and active infection promote the release of cytokines and up-regulation of Toll-like receptor-2 expression on monocytes, which may act as a trigger for postoperative AF. The inflammation process induces atrial electrophysiological changes, activates reentry mechanisms and precipitates the development of postoperative AF [15-18].There is a high inflammation state during the intraoperative period due to the extracorporeal circulation, the cardiac ischemia-reperfusion injury, and oxidative stress. In addition, pulmonary infections and cardiac dysfunction during the postoperative period may worsen the inflammatory process. Hence, the inflammatory activity and CRP levels reach its highest value in the first postoperative week [18]. After the first week, surgery induced inflammatory activity decreases, and postoperative risk factors gradually diminish. Therefore, surgery-related metabolic changes and oxidative stress after heart operation induce inflammatory reactions and increase inflammatory capacity which is associated to a higher risk of developing postoperative AF.

Most of the cardiac surgeries in organic heart disease are performed in elder patients. There is a, well documented, rise in prevalence of atrial AF with advancing age [19-21]. Several electrophysiological and pathological studies have shown that there is clear evidence in the human atrial myocardium of age-related electrical uncoupling of the side-to-side connections between bundles. This is related to the proliferation of extensive collagenous tissue septa in intracellular spaces [22-24]. In pathological studies, it was demonstrated that these age-induced changes include a reduction in the number of myocardial cells within the sinus node, a generalized loss of atrial myocardial fibers, as well as an increase in fibrosis which leads to an apparent loss of myocardial fiber continuity [19-24]. It is so clear to observe that patients with diseased atrial tissue with progressive fibro-degenerative changes may develop abnormal electrophysiological alterations [25-29]. Connective tissue surrounding atrial myocardial cells represents sites where electrical coupling between adjacent cells is altered [19-21]. Therefore, the micro-architecture and anisotropic characteristics may play an important role in reentry by causing inhomogeneous and discontinuous propagation of the impulse in the atrium [21]. These findings suggest that progressive electro-pathological changes within the atria are associated with persistent AF. Previous studies have investigated the underlying cause responsible for perpetuation of AF. Atrial fibrosis has been suggested to be an important element in the pathophysiology of AF. There is a significant larger amount of atrial fibrosis seen in patients with AF. The degree of fibrotic tissue in AF patients demonstrated heterogeneity and does not always predict the severity of the AF burden. An excessive extracellular matrix leads to uncoupling of cells and may facilitate inhomogeneous conduction, re-entry, and multiple wavelets. During the preoperative evaluation of the patients, MRI can be a helpful diagnostic tool for the determination of degree of fibrosis in AF patients and identification of areas of fibrosis. It was demonstrated that the activation of cellular signaling pathways plays an important role in human atrial structural remodeling, and promotes the proliferation of atrial fibroblasts, leading to atrial fibrosis. In addition, it is involved in apoptosis, inflammation and epithelial mesenchymal transformation [30-35]. The exact mechanism and signal transduction pathway underlying atrial muscle fibrosis is unknown. However, it was reported that the following mechanisms are mainly involved in atrial fibrosis: 1) the renin angiotensin aldosterone system, 2) transforming growth factor-β1 and 3) inflammation and oxidative stress. Transforming growth factor-β1, a key growth factor in fibrosis, can regulate cell proliferation, apoptosis and migration, and extracellular matrix synthesis. It up-regulates the expression of fibronectin and collagen, and its over-expression can lead to the occurrence of atrial fibrosis and AF [32-35].

Considering the relatively high incidence of postoperative AF, it is important to try to identify patients at risk of developing AF after surgery. In this regard, Luo W et al. observed with logistic regression analyses performed in 304 patients that a history of hypertension, left atrium diameter, and EuroSCORE I were independent risk factors for postoperative AF in patients older than 60 years of age [36]. Other studies have identified the following independent predictors of postoperative AF: high CHA2DS2-VASc, Age ≥75 years, diabetes mellitus, prior stroke or transient ischemic attack or thromboembolism, vascular disease, severe obesity, preoperative β-blocker use, preoperative antiplatelet therapy, renal insufficiency, and preoperative systolic pulmonary arterial pressure [37-39]. Patients with these independent predictors of postoperative AF may constitute a target population to test preventive strategies.

Another helpful diagnostic tool is P-wave duration and dispersion (PWD) which is considered a noninvasive electrocardiographic (ECG) marker for atrial remodeling and predictor for AF [40-43]. PWD reflects disturbances of intra-atrial and inter-atrial conduction, and it is defined as the difference between the wider and the narrower P-wave duration recorded from the 12 ECG leads at a paper speed of 50 mm/s. It has been shown that increased P-wave duration and PWD reflect prolongation of intra-atrial and inter-atrial conduction time and the inhomogeneous atrial propagation of sinus impulses [40-42]. The analysis of the P-wave with the 12 standard surface ECG leads in the stratification of patient suffering from AF is a recognized universal approach. It is well accepted that not only the P-wave duration, but also the P-wave morphology and dispersion have the potential to give information about the anatomical substrate predisposing to AF [41-44]. Extensive clinical evaluation of P-wave dispersion has been performed in the assessment of the risk for atrial fibrillation in patients without organic heart disease, in patients with arterial hypertension, in patients with coronary artery disease, in patients undergoing coronary artery bypass surgery, in patients with congenital heart diseases, as well as in other groups of patients suffering from various cardiac or non-cardiac diseases [45,46]. Consequently, PWD can be helpful in discriminating patients with different kinds of diseases whom are prone to develop paroxysmal AF in the postoperative scenario [47,48].

We have previously found that patients with a predisposition to develop AF have significantly higher incidence of atrial conduction defects, and abnormally prolonged and fractionated atrial endocardial electrograms [25-29]. At the time of the atrial endocardial catheter mapping during sinus rhythm, we have found that an abnormally prolonged and fractionated right atrial electrogram may reflect inhomogeneous local electrical activity related to a delayed and non-uniform anisotropic conduction through diseased atrial muscle, and were closely related to the vulnerability of the atrial muscle in patients with paroxysmal AF [27-29]. Indeed, we demonstrated that the greater the extent of the compromised atrial muscle, the greater the likelihood that paroxysmal AF would develop [27]. Qualitative and quantitative analysis of atrial endocardial electrograms recorded during sinus rhythm should be an important analysis in evaluating local atrial electrophysiological abnormalities, and acquire particular relevance in the study of patients with paroxysmal AF.

In the evaluation of patients with altered P wave morphology and dispersion in the electrocardiogram, it is very important to keep in mind that patients who have a great susceptibility to develop AF possess abnormally prolonged and fractionated atrial endocardial electrograms, a significantly longer P wave duration, a significantly longer intra-atrial and inter-atrial conduction time of sinus impulses; and a significantly greater sinus node dysfunction and higher incidence of induction of sustained atrial fibrillation. In conclusion, the heterogeneous presentation, development and progression of AF implicate the existence of different pathophysiological processes. In order to improve surgical outcomes is necessary to individualized diagnostic and therapeutic management of the arrhythmogenic substrate underlying AF and minimize the metabolic, oxidative stress and inflammation process during surgery.

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