TO PERFORM SERIAL ELECTROCARDIOGRAM (ECG) ANALYSES IN PATIENTS WITH SUBTLE ECG CHANGES AND EVALUATE THE PERFORMANCE OF THE FOUR-VARIABLE FORMULA IN DETECTING LEFT ANTERIOR DESCENDING (LAD) CORONARY ARTERY OCCLUSION ON CORONARY ANGIOGRAM

Authors

  • S AHMAD Armed Forces Institute of Cardiology/National Institute of Heart Disease, AFIC/NIHD, Rawalpindi, Pakistan
  • MB SIDDIQUE Department of Medicine, Army Medical College, Rawalpindi, Pakistan
  • RU KHAN Department of Cardiology, MTI/Mardan Medical Complex, Mardan, Pakistan
  • MOR RANA Armed Forces Institute of Cardiology/National Institute of Heart Disease, AFIC/NIHD, Rawalpindi, Pakistan
  • H SIDDIQUE Department of Biochemistry, Foundation University, Islamabad, Pakistan
  • M MASOOM Armed Forces Institute of Cardiology/National Institute of Heart Disease, AFIC/NIHD, Rawalpindi, Pakistan

DOI:

https://doi.org/10.54112/bcsrj.v2024i1.886

Keywords:

ECG, Coronary Angiogram, Left Anterior Descending Artery

Abstract

Acute coronary syndrome (ACS) is a critical condition that often presents with symptoms such as ‘chest pain,’ ‘shortness of breath,’ and diaphoresis, signaling a potential underlying coronary artery disease. Among the various coronary arteries, the Left Anterior Descending (LAD) artery is particularly interesting due to its significant role in supplying blood to a large portion of the heart muscle. Objectives: To assess the efficacy of the ‘four-variable formula’ in identifying left anterior descending (LAD) coronary artery occlusion, ‘serial electrocardiogram (ECG) analyses’ should be performed on individuals exhibiting minor alterations in the ‘anterior leads.’ Methodology: ‘This study was a cross-sectional study conducted at the Armed Forces Institute of Cardiology’ (AFIC) from Jan 2023 to June 2023. The primary aim was to ‘evaluate the predictive performance of the Four-Variable Formula in detecting Left Anterior Descending (LAD) coronary artery occlusion’ using serial electrocardiogram (ECG) analyses. Upon presentation, a standard 12-lead ECG was performed on each patient. Serial ECGs were conducted at 30-minute intervals for the first two hours or until a definitive diagnosis was made. Following the ECG analyses, ‘all patients were taken to the catheterization lab for coronary angiography within 24 hours of presentation’. The angiographic results served as the gold standard for diagnosing LAD occlusion. An experienced interventional cardiologist, blinded to the ECG findings, performed and interpreted the angiograms. Results: The study included 360 patients, with a mean age of 62 ±11 years (range 32-80 years). The cohort comprised 219 males (62%) and 141 females (38%). Common risk factors included hypertension (69%), diabetes mellitus (46%), smoking (51%), and a family history of coronary artery disease (29%). Coronary angiography identified LAD occlusion in 139 patients (38%) and no significant LAD occlusion in 221 patients (62%). The results suggested that the Four-Variable Formula could be integrated into routine clinical practice to enhance early detection of significant coronary artery disease, particularly in settings where immediate access to coronary angiography is limited. Future studies with more extensive, multicenter cohorts could further validate these findings and potentially lead to widespread adoption of this predictive tool. Conclusion: Our findings suggest that the Four-Variable Formula holds promise as a non-invasive diagnostic tool in emergency settings, aiding ‘in the early identification of patients at risk’ of significant coronary artery disease. By incorporating the formula into clinical practice algorithms, healthcare providers may expedite triage decisions and facilitate timely interventions, ultimately improving patient outcomes.

Downloads

Download data is not yet available.

References

Shao C, Wang J, Tian J, Tang Y-d. Coronary artery disease: from mechanism to clinical practice. Coronary Artery Disease: Therapeutics and Drug Discovery. 2020:1-36.

Thiene G, Frescura C, Padalino M, Basso C, Rizzo S. Coronary arteries: Normal anatomy with historical notes and embryology of Main stems. Frontiers in cardiovascular medicine. 2021;8:649855.

Damluji AA, Van Diepen S, Katz JN, Menon V, Tamis-Holland JE, Bakitas M, et al. Mechanical complications of acute myocardial infarction: a scientific statement from the American Heart Association. Circulation. 2021;144(2):e16-e35.

Miró Ò, Martínez-Nadal G, Jiménez S, Gómez-Angelats E, Alonso JR, Antolín A, et al. Nontraumatic chest pain and suspicion of acute coronary syndrome: associated clinical and electrocardiographic findings on initial evaluation. Emergencias. 2020;32:9-18.

Goldberger AL. Clinical Electrocardiography E-Book: A Simplified Approach: Elsevier Health Sciences; 2012.

Pinto JR, Cardoso JS, Lourenço A. Evolution, current challenges, and future possibilities in ECG biometrics. IEEE Access. 2018;6:34746-76.

Driver BE, Khalil A, Henry T, Kazmi F, Adil A, Smith SW. A new 4-variable formula to differentiate normal variant ST segment elevation in V2-V4 (early repolarization) from subtle left anterior descending coronary occlusion-Adding QRS amplitude of V2 improves the model. Journal of electrocardiology. 2017;50(5):561-9.

McLaren JT, Kapoor M, Soojin LY, Chartier LB. Using ECG-to-activation time to assess emergency physicians’ diagnostic time for acute coronary occlusion. The Journal of Emergency Medicine. 2021;60(1):25-34.

Li Y-L, Leu H-B, Ting C-H, Lim S-S, Tsai T-Y, Wu C-H, et al. Predicting long-term time to cardiovascular incidents using myocardial perfusion imaging and deep convolutional neural networks. Scientific Reports. 2024;14(1):3802.

Smith SM, Gurka MJ, Calhoun DA, Gong Y, Pepine CJ, Cooper-DeHoff RM. Optimal systolic blood pressure target in resistant and non-resistant hypertension: a pooled analysis of patient-level data from SPRINT and ACCORD. The American journal of medicine. 2018;131(12):1463-72. e7.

Allen BR, Christenson RH, Cohen SA, Nowak R, Wilkerson RG, Mumma B, et al. Diagnostic performance of high-sensitivity cardiac troponin T strategies and clinical variables in a multisite US cohort. Circulation. 2021;143(17):1659-72.

Echarri G, Duque-Sosa P, Callejas R, Garcia-Fernandez N, Nunez-Cordoba JM, Iribarren MJ, et al. External validation of predictive models for acute kidney injury following cardiac surgery: a prospective multicentre cohort study. European Journal of Anaesthesiology| EJA. 2017;34(2):81-8.

Martí D, Mestre JL, Salido L, Esteban MJ, Casas E, Pey J, et al. Incidence, angiographic features and outcomes of patients presenting with subtle ST-elevation myocardial infarction. American heart journal. 2014;168(6):884-90.

Willerson JT, Armstrong PW. Acute myocardial infarction. Comprehensive Management of High Risk Cardiovascular Patients: CRC Press; 2016. p. 637-72.

Kosuge M, Kimura K, Ishikawa T, Endo T, Shigemasa T, Sugiyama M, et al. Electrocardiographic criteria for predicting total occlusion of the proximal left anterior descending coronary artery in anterior wall acute myocardial infarction. Clinical cardiology. 2001;24(1):33-8.

Smith SW. Upwardly concave ST segment morphology is common in acute left anterior descending coronary occlusion. The Journal of emergency medicine. 2006;31(1):69-77.

Larson DM, Menssen KM, Sharkey SW, Duval S, Schwartz RS, Harris J, et al. “False-positive” cardiac catheterization laboratory activation among patients with suspected ST-segment elevation myocardial infarction. Jama. 2007;298(23):2754-60.

Kontos MC, Kurz MC, Roberts CS, Joyner SE, Kreisa L, Ornato JP, et al. An evaluation of the accuracy of emergency physician activation of the cardiac catheterization laboratory for patients with suspected ST-segment elevation myocardial infarction. Annals of emergency medicine. 2010;55(5):423-30.

Garvey JL, Monk L, Granger CB, Studnek JR, Roettig ML, Corbett CC, et al. Rates of cardiac catheterization cancelation for ST-segment elevation myocardial infarction after activation by emergency medical services or emergency physicians: results from the North Carolina Catheterization Laboratory Activation Registry. Circulation. 2012;125(2):308-13.

Mixon TA, Suhr E, Caldwell G, Greenberg RD, Colato F, Blackwell J, et al. Retrospective description and analysis of consecutive catheterization laboratory ST-segment elevation myocardial infarction activations with proposal, rationale, and use of a new classification scheme. Circulation: Cardiovascular Quality and Outcomes. 2012;5(1):62-9.

Barge-Caballero E, Vázquez-Rodríguez JM, Estévez-Loureiro R, Barge-Caballero G, Rodríguez-Vilela A, Calviño-Santos R, et al. Prevalence, etiology, and outcome of catheterization laboratory false alarms in patients with suspected ST-elevation myocardial infarction. Revista Española de Cardiología (English Edition). 2010;63(5):518-27.

Smith SW. Updates on the electrocardiogram in acute coronary syndromes. Current Emergency and Hospital Medicine Reports. 2013;1:43-52.

Nfor T, Kostopoulos L, Hashim H, Jan MF, Gupta A, Bajwa T, et al. Identifying false-positive ST-elevation myocardial infarction in emergency department patients. The Journal of emergency medicine. 2012;43(4):561-7.

Downloads

Published

2024-06-05

How to Cite

AHMAD, S., SIDDIQUE, M., KHAN, R., RANA, M., SIDDIQUE, H., & MASOOM, M. (2024). TO PERFORM SERIAL ELECTROCARDIOGRAM (ECG) ANALYSES IN PATIENTS WITH SUBTLE ECG CHANGES AND EVALUATE THE PERFORMANCE OF THE FOUR-VARIABLE FORMULA IN DETECTING LEFT ANTERIOR DESCENDING (LAD) CORONARY ARTERY OCCLUSION ON CORONARY ANGIOGRAM. Biological and Clinical Sciences Research Journal, 2024(1), 886. https://doi.org/10.54112/bcsrj.v2024i1.886

Most read articles by the same author(s)

<< < 1 2 3 > >>