1. Home
  2. JCCR
  3. JCCR 08 00285
Submit manuscript...
Journal of
eISSN: 2373-4396

Cardiology & Current Research

Editorial Volume 8 Issue 3

P Wave Duration and Dispersion as a Useful Conventional Electrocardiographic Marker for Atrial Fibrillation Prediction

Osmar Antonio Centurion,1,2 Nelson Aquino,1 Judith Torales,1 Karina Scavenius,1 Luis Mino,1 Orlando Sequeira1

1Department of Health Sciences?s Investigation, Sanatorio Metropolitano, Fernando de la Mora, Paraguay
2Cardiology Division, First Department of Internal Medicine, Asunci

Correspondence: Osmar Antonio Centurión, Professor of Medicine. Asunción National University, Department of Health Sciences’s Investigation, Sanatorio Metropolitano, Teniente Ettiene 215 c/ Ruta Mariscal Estigarribia Fernando de la Mora, Paraguay

Received: February 24, 2017 | Published: March 8, 2017

Citation: Centurión OA, Aquino N, Torales J, Scavenius K, Miño L, et al. (2017) P Wave Duration and Dispersion as a Useful Conventional Electrocardiographic Marker for Atrial Fibrillation Prediction. J Cardiol Curr Res 8(3): 00285. DOI: 10.15406/jccr.2017.08.00285

Download PDF

Editorial

The increase in prevalence of atrial fibrillation (AF) is related with aging, and it has been reported to be associated with degeneration of the atrial muscle in pathological studies in elderly people [1-3]. It has been 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 histologically related to the proliferation of extensive collagenous tissue septa in intracellular spaces [4-6]. 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 [1-6].

Patients with diseased atrial tissue with progressive fibro-degenerative changes may develop abnormal electrophysiological alterations [7-11]. Connective tissue surrounding atrial myocardial cells represents sites where electrical coupling between adjacent cells is altered [1-3]. 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 [3]. The P wave of the electrocardiogram may show alterations that can be associated with atrial arrhythmias and AF. P-wave dispersion (PWD) is considered a noninvasive electrocardiographic (ECG) marker for atrial remodeling and predictor for AF [12-15]. 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. The correct measurement of PWD is derived by subtracting the minimum P-wave duration from the maximum in any of the 12 standard surface ECG leads in supine position following 15 min of rest and room temperature and lighting kept constant [13]. The onset of the P-wave is defined as the point of first detectable upward or downward slope from the isoelectric line for positive or negative waveforms, respectively. Return to the isoelectric line is considered as the end of the P-wave. PWD can be calculated by manual measurements with hand-held calipers or computerized methods. Manual measurement with hand-held calipers is performed by increasing the ECG rate to 50 mm/s and the voltage to 1 mV/cm, accompanied by the use of magnification. The normal value of PWD was found to be 29 ± 9 ms, and values greater than 40 ms indicate the presence of heterogeneous electrical activity in different regions of the atrium that might cause AF to develop [13]. 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 [12-14].

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 [13-16]. It has been demonstrated that a P wave maximum duration value of 106 ms separated patients with paroxysmal AF from control subjects with a sensitivity of 83%, a specificity of 72%, and a positive predictive accuracy of 79%. In addition, a PWD value greater than 36 ms separated AF patients from control subjects with a sensitivity of 77%, a specificity of 82%, and a positive predictive accuracy of 85% [13]. PWD has shown to have a significant correlation with maximum P-wave duration (r=0.702, p<0.001) and a weak, although significant association with age (r=0.270, p<0.001) [13]. In addition, PWD was shown to be a significant predictor of frequent symptomatic AF paroxysms [14]. It was also found to have a significantly positive correlation with maximum P-wave duration (p<0.001) and negatively with minimum P-wave duration (p=0.06). 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 [17-28]. Consequently, PWD can be helpful in discriminating patients with different kinds of diseases whom are prone to develop paroxysmal AF in the course of their lives [29-37].

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 [7-11]. 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 [9-11]. Indeed, we demonstrated that the greater the extent of the compromised atrial muscle, the greater the likelihood that paroxysmal AF would develop [9]. 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.

Conclusion

PWD reflects prolonged, inhomogeneous and anisotropic distribution of connections between myocardial fibers resulting in discontinuous anisotropic propagation of sinus impulses, as well as, inhomogeneous and discontinuous atrial conduction. PWD is considered as a sensitive and specific ECG predictor of paroxysmal AF.

References

  1. Spach MS, Dober PC, Anderson PA (1989) Multiple regional differences in cellular properties that regulate repolarization and contraction in the right atrium of adult and newborn dogs. Circ Res 65(6): 1594-1611.
  2. Spach MS, Miller WT, Dolber PC, Kootsey JM, Sommer JR, et al. (1982) The functional role of structural complexities in the propagation of depolarization in the atrium of the dog: cardiac conduction disturbances due to discontinuities of effective axial resistivity. Circ Res 50(2): 175-191.
  3. Spach MS, Dober PC (1986) Relating extracellular potentials and their derivatives to anisotropic propagation at microscopic level in human cardiac muscle. Evidence for electrical uncoupling of side-to-side fiber connections with increasing age. Circ Res 58(3): 356-371.
  4. Lev M (1954) Aging changes in the human sinoatrial node. J Geront 9(1): 1-9.
  5. Davies MJ, Pomerance A (1972) Quantitative study of aging changes in the human sinoatrial node and internodal tracts. Br Heart J 34(2): 150-152.
  6. Hudson RE (1960) The human pacemarker and its pathology. Br Heart J 22: 153-167.
  7. Centurión OA, Isomoto S, Shimizu A, Konoe A, Kaibara M, et al. (2003) The effects of aging on atrial endocardial electrograms in patients with paroxysmal atrial fibrillation. Clin Cardiol 26(9): 435-438.
  8. Centurión OA, Shimizu A, Isomoto S, Konoe, Kaibara M, et al. (2005) Influence of advancing age on fractionated right atrial endocardial electrograms. Am J Cardiol 96(2): 239-242.
  9. Centurión OA, Fukatani M, Konoe A, Tanigawa M, Shimizu A, et al. (1992) Different distribution of abnormal endocardial electrograms within the right atrium in patients with sick sinus syndrome. Br Heart J 68(12): 596-600.
  10. Centurión OA, Isomoto S, Fukatani M, Shimizu A, Konoe A, et al. (1993) Relationship between atrial conduction defects and fractionated atrial endocardial electrograms in patients with sick sinus syndrome. Pacing Clin Electrophysiol 16(10): 2022-2033.
  11. Centurión OA, Shimizu A, Isomoto S, Konoe A, Hirata T, et al. (1994) Repetitive atrial firing and fragmented atrial activity elicited by extrastimuli in the sick sinus syndrome with and without abnormal atrial electrograms. Am J Med Sci 307(4): 247-254.
  12. Centurión OA (2009) Clinical implications of the P wave duration and dispersion: Relationship between atrial conduction defects and abnormally prolonged atrial endocardial electrograms. Int J Cardiol 134(1): 6-8.
  13. Aytemir K, Ozer N, Atalar E, Sade E, Aksoyek S, et al. (2000) P wave dispersion on 12-lead electrocardiography in patients with paroxysmal atrial fibrillation. Pacing Clin Electrophysiol 23(7): 1109-1112.
  14. Dilaveris PE, Gialafos JE (2001) P-wave dispersion: a novel predictor of paroxysmal atrial fibrillation. Ann Noninvasive Electrocardiol 6(2): 159-165.
  15. Lazzeroni D, Parati G, Bini M, Piazza P, Ugolotti, et al. (2016) P-wave dispersion predicts atrial fibrillation following cardiac surgery. Int J Cardiol 203: 131-133.
  16. Yoshizawa T, Niwano S, Niwano H, Igarashi T, fujiishi, et al. (2014) Prediction of new onset atrial fibrillation through P wave analysis in 12 lead ECG. Int Heart J 55(5): 422-427.
  17. Puerta RC, Aliz EL, Lopez CM, Ramirez RR, Pena GP (2011) Increased p wave dispersion in elite athletes. Indian Pacing Electrophysiol J 11(3): 73-80.
  18. Ertem AG, Erdogan M, Keles T, Durmaz T, Bozkurt E (2015) P-wave dispersion and left ventricular diastolic dysfunction in hypertension. Anatol J Cardiol 15(1): 78-79.
  19. Suner A, Cetin M (2016) The effect of trimetazidine on ventricular repolarization indexes and left ventricular diastolic function in patients with coronary slow flow. Coron Artery Dis 27(5): 398-404.
  20. Kim DH, Kim GC, Kim SH, Yu HK, Choi WG, et al. (2007) The relationship between the left atrial volume and the maximum P-wave and P-wave dispersion in patients with congestive heart failure. Yonsei Med J 48(5): 810-817.
  21. Dursun H, Tanriverdi Z, Colluoglu T, Kaya D (2015) Effect of transcatheter aortic valve replacement on P-wave duration, P-wave dispersion and left atrial size. J Geriatr Cardiol 12(6): 613-617.
  22. Beig JR, Tramboo NA, Rather HA, Hafeez I, Ananth V, et al. (2015) Immediate effect of percutaneous transvenous mitral commissurotomy on atrial electromechanical delay and P wave dispersion in patients with severe mitral stenosis. Indian Heart J 67(Suppl 2): S46-S54.
  23. Kizilirmak F, Demir GG, Gokdeniz T, Gunes, Cakal, et al. (2016) Changes in electrocardiographic P wave parameters after Cryoballoon ablation and their association with atrial fibrillation recurrence. Ann Noninvasive Electrocardiol 21(6): 580-587.
  24. Ding L, Hua W, Zhang S, Chu, Wang, et al. (2009) Improvement of P wave dispersion after cardiac resynchronization therapy for heart failure. J Electrocardiol 42(4): 334-338.
  25. Kawamura M, Scheinman MM, Lee RJ, Badhwar N (2015) Left atrial appendage ligation in patients with atrial fibrillation leads to a decrease in atrial dispersion. J Am Heart Assoc 4(5): e001581.
  26. Mugnai G, Chierchia GB, De Asmundis C, Julia, Conte G, et al. (2016) P-wave indices as predictors of atrial fibrillation recurrence after pulmonary vein isolation in normal left atrial size. J Cardiovasc Med Hagerst 17(3): 194-200.
  27. Badhwar N, Lakkireddy D, Kawamura M, Han FT, Iyer SK, et al. (2015) Sequential percutaneous LAA ligation and pulmonary vein isolation in patients with persistent AF: initial results of a feasibility study. J Cardiovasc Electrophysiol 26(6): 608-614.
  28. Kose MD, Bag O Güven B, Mese T, Oztürk A, (2014) P-wave dispersion: an indicator of cardiac autonomic dysfunction in children with neurocardiogenic syncope. Pediatr Cardiol 35(4): 596-600.
  29. Dilaveris PE, Gialafos EJ, Sideris SK, Artemis M, George, et al. (1998) Simple electrocardiographic markers for the prediction of paroxysmal idiopathic atrial fibrillation. Am Heart J 135(5): 733-738.
  30. Magnani JW, Mazzini MJ, Sullivan LM, Williamson, Ellinor PT, et al. (2010) P-wave indices, distribution and quality control assessment (from the Framingham Heart Study). Ann Noninvasive Electrocardiol 15(1): 77-84.
  31. Aytemir K, Amasyali B, Kose S, Kilic, Abali, et al. (2004) Maximum P-wave duration and P-wave dispersion predict recurrence of paroxysmal atrial fibrillation in patients with Wolff-Parkinson-White syndrome after successful radiofrequency catheter ablation. J Interv Card Electrophysiol 11(1): 21-27.
  32. Magnani JW, Williamson MA, Ellinor PT, Monahan KM, Benjamin EJ (2009) P wave indices: current status and future directions in epidemiology, clinical, and research applications. Circ Arrhythm Electrophysiol 2(1): 72-79.
  33. Dilaveris PE, Gialafos EJ, Andrikopoulos GK, Richter DJ, Papanikolaou V, et al. (2000) Clinical and electrocardiographic predictors of recurrent atrial fibrillation. Pacing Clin Electrophysiol 23(3): 352-358.
  34. Boriani G, Diemberger I, Biffi M, Camanini C, Valzania, et al. (2005) P wave dispersion and short-term vs. late atrial fibrillation recurrences after cardioversion. Int J Cardiol 101(3): 355-361.
  35. Perzanowski C, Ho AT, Jacobson AK (2005) Increased P wave dispersion predicts recurrent atrial fibrillation after cardioversion. J Electrocardiol 38(1): 43-46.
  36. Ozdemir O, Soylu M, Demir AD, Alyan, Topaloglu, et al. (2006) Does p-wave dispersion predict the atrial fibrillation occurrence after direct-current shock therapy? Angiology 57(1): 93-98.
  37. Amasyali B, Kose S, Aytemir K, Kilic A, Turhan, et al. (2006) P wave dispersion predicts recurrence of paroxysmal atrial fibrillation in patients with atrioventricular nodal reentrant tachycardia treated with radiofrequency catheter ablation. Ann Noninvasive Electrocardiol 11(3): 263-270.
Creative Commons Attribution License

©2017 Centurión, et al. This is an open access article distributed under the terms of the, which permits unrestricted use, distribution, and build upon your work non-commercially.

Citations

Journal Menu

Useful Links