DOCSLIB.ORG

Ekg Graph Paper

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Ekg Graph Paper ECG Study Guide Table of Contents ECG STUDY GUIDE ..................................................................................................................................................................... 3 2015 AMERICAN HEART ASSOCIATION (AHA) GUIDELINES HIGHLIGHTS UPDATE FOR CARDIOPULMONARY RESUSCITATION (CPR) AND EMERGENCY CARDIOVASCULAR CARE (ECC). ....................................................................................................... 3 ECG INTERPRETATION BASICS ............................................................................................................................................. 4 EKG GRAPH PAPER ................................................................................................................................................................... 4 Components of the Normal EKG Waveform ......................................................................................................................... 6 RATE MEASUREMENT ................................................................................................................................................................ 9 The Six Second Method ......................................................................................................................................................... 9 Large Box Method ................................................................................................................................................................ 9 Small Box Method ............................................................................................................................................................... 10 BASIC EKG RHYTHM ANALYSIS GUIDE ................................................................................................................................... 11 Rhythm Interpretation ......................................................................................................................................................... 13 Six Basic Steps for Rhythm Interpretation Summary .......................................................................................................... 13 NURSING PRIORITIES AND POTENTIAL TREATMENTS ............................................................................................................... 14 Bradycardia ........................................................................................................................................................................ 14 BASIC CHARACTERISTICS OF CARDIAC RHYTHMS ................................................................................................................... 16 TYPES OF RHYTHM .................................................................................................................................................................. 18 NORMAL SINUS RHYTHM ......................................................................................................................................................... 18 SINUS BRADYCARDIA............................................................................................................................................................... 19 SINUS TACHYCARDIA ............................................................................................................................................................... 20 PREMATURE ATRIAL CONTRACTIONS (PACS) ......................................................................................................................... 22 ATRIAL FIBRILLATION ............................................................................................................................................................. 23 ATRIAL FLUTTER ..................................................................................................................................................................... 24 JUNCTIONAL RHYTHM .............................................................................................................................................................. 25 ACCELERATED JUNCTIONAL RHYTHM/JUNCTIONAL TACHYCARDIA ........................................................................................ 26 ATRIOVENTRICULAR BLOCKS .................................................................................................................................................. 27 1ST DEGREE AV BLOCK ........................................................................................................................................................... 27 2ND DEGREE AV BLOCK (MOBITZ TYPE I, WENCKEBACH) ..................................................................................................... 29 3RD DEGREE AB BLOCK / COMPLETE HEART BLOCK .............................................................................................................. 31 VENTRICULAR RHYTHMS ......................................................................................................................................................... 33 PREMATURE VENTRICULAR CONTRACTION (PVCS) ................................................................................................................ 34 VENTRICULAR TACHYCARDIA ................................................................................................................................................. 36 VENTRICULAR FIBRILLATION ................................................................................................................................................... 37 ASYSTOLE ................................................................................................................................................................................ 38 POLYMORPHIC VENTRICULAR TACHYCARDIA (TORSADE DE POINTES).................................................................................... 39 IDIOVENTRICULAR (IVR) ......................................................................................................................................................... 40 ACCELERATED IDIOVENTRICULAR (AIVR) .............................................................................................................................. 41 PACED RHYTHMS ..................................................................................................................................................................... 42 Pacemaker Summary .......................................................................................................................................................... 45 CONCLUSION .............................................................................................................................................................................. 46 REFERENCES .............................................................................................................................................................................. 47 2 ECG Study Guide The ECG Assessment Testing is an assessment of your basic knowledge and should be completed as part of your new hire process. Although we are sure that you know the information, you need to study this information to be prepared to pass the test. Please remember the following guidelines: . The study guide is a good overall review of the components of the ECG waveform and more common dysrhythmia. You will need to be able to recognize the four lethal rhythms. Asystole, Ventricle Tachycardia (VT), Ventricle Fibrillation (VF), and Polymorphic Ventricle Tachycardia (Torsade de pointes). Use this study guide and other resource books to review ECG interpretation. You will be expected to calculate rates properly interpret each strip. Practice measuring your strips in the study guide. The rhythm strips on the exam are NOT always 6-second strips. Use calipers or review pages 9 & 10 for rate calculation. Memorize your blocks…there are several rhythm strips on blocks. Rules for passing the exam . Minimal passing score = 85% . If you do not correctly identify any of the following rhythms, you will be required to retake the exam, even if your test score is above the passing score. o Ventricular tachycardia o Ventricular fibrillation o Asystole o Torsade de pointes . If you correctly identify the four lethal rhythms and achieve an overall score of at least 85%, you have passed the exam. 2015 American Heart Association (AHA) Guidelines Highlights Update for Cardiopulmonary Resuscitation (CPR) and Emergency Cardiovascular Care (ECC). For Information Purpose Only http://eccguidelines.heart.org/wp-content/uploads/2015/10/2015-AHA-Guidelines-Highlights-English.pdf This “Guidelines Highlights” publication summarizes the key issues and changes in the 2015 American Heart Association (AHA) Guidelines Update for Cardiopulmonary Resuscitation (CPR) and Emergency Cardiovascular Care (ECC). Because this publication is designed as a summary, it does not reference the supporting published studies and does not list Classes of Recommendation or Levels of Evidence. For more detailed information and references, readers are encouraged to read the 2015 AHA Guidelines Update for CPR and ECC, including the Executive Summary, published in Circulation in October 2015, and to consult the detailed summary of resuscitation science in the 2015 International Consensus on CPR and ECC Science with Treatment 3 ECG Interpretation Basics EKG Graph Paper The paper used to record EKG tracings is grid like in nature and has specific markings utilized
Load more

Recommended publications
  • Chapter 20 *Lecture Powerpoint the Circulatory System: Blood Vessels and Circulation
    Chapter 20 *Lecture PowerPoint The Circulatory System: Blood Vessels and Circulation *See separate FlexArt PowerPoint slides for all figures and tables preinserted into PowerPoint without notes. Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Introduction • The route taken by the blood after it leaves the heart was a point of much confusion for many centuries – Chinese emperor Huang Ti (2697–2597 BC) believed that blood flowed in a complete circuit around the body and back to the heart – Roman physician Galen (129–c. 199) thought blood flowed back and forth like air; the liver created blood out of nutrients and organs consumed it – English physician William Harvey (1578–1657) did experimentation on circulation in snakes; birth of experimental physiology – After microscope was invented, blood and capillaries were discovered by van Leeuwenhoek and Malpighi 20-2 General Anatomy of the Blood Vessels • Expected Learning Outcomes – Describe the structure of a blood vessel. – Describe the different types of arteries, capillaries, and veins. – Trace the general route usually taken by the blood from the heart and back again. – Describe some variations on this route. 20-3 General Anatomy of the Blood Vessels Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Capillaries Artery: Tunica interna Tunica media Tunica externa Nerve Vein Figure 20.1a (a) 1 mm © The McGraw-Hill Companies, Inc./Dennis Strete, photographer • Arteries carry blood away from heart • Veins
    [Show full text]
  • The ECG Made Very Easy Indeed: a Beginner’S Guide
    Part 1 The ECG made very easy indeed: a beginner’s guide The ECG made very easy indeed 1 What is an ECG? 1 The heart is a pump driven by intrinsic electrical When do you need an ECG? 1 impulses which make the heart beat. An ECG is a paper recording of that electrical activity. The ECG records where How to record an ECG 2 electrical impulses start and how they flow through the How to interpret an ECG: the basics 2 heart. It does not measure how well the heart is pumping. The electrical activity of the heart starts in the ‘inter- The ECG waves and what they mean 2 nal pacemaker’, which is called the sinoatrial node. This Interpretation starts here! 4 is in the right atrium. The normal rhythm is called ‘sinus rhythm’ (properly it should be called sinoatrial rhythm, Rhythms you must be able to recognize 8 but it isn’t). The way electrical impulses flow through the Patterns you must be able to recognize 10 heart is called conduction. Abnormalities in the electrical activity of the heart can The normal ECG and its variants 13 result in abnormal conduction or rhythms where the heart ECG red flags 14 may go too quickly, too slowly, or beat irregularly. Changes to the normal flow of electricity through the heart can be shown on an ECG and may indicate damaged This guide has been written for those who are just starting heart muscle. Heart muscle can be damaged by many to use ECGs in their clinical practice.
    [Show full text]
  • Young Adults. Look for ST Elevation, Tall QRS Voltage, "Fishhook" Deformity at the J Point, and Prominent T Waves
    EKG Abnormalities I. Early repolarization abnormality: A. A normal variant. Early repolarization is most often seen in healthy young adults. Look for ST elevation, tall QRS voltage, "fishhook" deformity at the J point, and prominent T waves. ST segment elevation is maximal in leads with tallest R waves. Note high take off of the ST segment in leads V4-6; the ST elevation in V2-3 is generally seen in most normal ECG's; the ST elevation in V2- 6 is concave upwards, another characteristic of this normal variant. Characteristics’ of early repolarization • notching or slurring of the terminal portion of the QRS wave • symmetric concordant T waves of large amplitude • relative temporal stability • most commonly presents in the precordial leads but often associated with it is less pronounced ST segment elevation in the limb leads To differentiate from anterior MI • the initial part of the ST segment is usually flat or convex upward in AMI • reciprocal ST depression may be present in AMI but not in early repolarization • ST segments in early repolarization are usually <2 mm (but have been reported up to 4 mm) To differentiate from pericarditis • the ST changes are more widespread in pericarditis • the T wave is normal in pericarditis • the ratio of the degree of ST elevation (measured using the PR segment as the baseline) to the height of the T wave is greater than 0.25 in V6 in pericarditis. 1 II. Acute Pericarditis: Stage 1 Pericarditis Changes A. Timing 1. Onset: Day 2-3 2. Duration: Up to 2 weeks B. Findings 1.
    [Show full text]
  • Basic Rhythm Recognition
    Electrocardiographic Interpretation Basic Rhythm Recognition William Brady, MD Department of Emergency Medicine Cardiac Rhythms Anatomy of a Rhythm Strip A Review of the Electrical System Intrinsic Pacemakers Cells These cells have property known as “Automaticity”— means they can spontaneously depolarize. Sinus Node Primary pacemaker Fires at a rate of 60-100 bpm AV Junction Fires at a rate of 40-60 bpm Ventricular (Purkinje Fibers) Less than 40 bpm What’s Normal P Wave Atrial Depolarization PR Interval (Normal 0.12-0.20) Beginning of the P to onset of QRS QRS Ventricular Depolarization QRS Interval (Normal <0.10) Period (or length of time) it takes for the ventricles to depolarize The Key to Success… …A systematic approach! Rate Rhythm P Waves PR Interval P and QRS Correlation QRS Rate Pacemaker A rather ill patient……… Very apparent inferolateral STEMI……with less apparent complete heart block RATE . Fast vs Slow . QRS Width Narrow QRS Wide QRS Narrow QRS Wide QRS Tachycardia Tachycardia Bradycardia Bradycardia Regular Irregular Regular Irregular Sinus Brady Idioventricular A-Fib / Flutter Bradycardia w/ BBB Sinus Tach A-Fib VT PVT Junctional 2 AVB / II PSVT A-Flutter SVT aberrant A-Fib 1 AVB 3 AVB A-Flutter MAT 2 AVB / I or II PAT PAT 3 AVB ST PAC / PVC Stability Hypotension / hypoperfusion Altered mental status Chest pain – Coronary ischemic Dyspnea – Pulmonary edema Sinus Rhythm Sinus Rhythm P Wave PR Interval QRS Rate Rhythm Pacemaker Comment . Before . Constant, . Rate 60-100 . Regular . SA Node Upright in each QRS regular . Interval =/< leads I, II, . Look . Interval .12- .10 & III alike .20 Conduction Image reference: Cardionetics/ http://www.cardionetics.com/docs/healthcr/ecg/arrhy/0100_bd.htm Sinus Pause A delay of activation within the atria for a period between 1.7 and 3 seconds A palpitation is likely to be felt by the patient as the sinus beat following the pause may be a heavy beat.
    [Show full text]
  • Basic ECG Interpretation
    12/2/2016 Basic Cardiac Anatomy Blood Flow Through the Heart 1. Blood enters right atrium via inferior & superior vena cava 2. Right atrium contracts, sending blood through the tricuspid valve and into the right ventricle 3. Right ventricle contracts, sending blood through the pulmonic valve and to the lungs via the pulmonary artery 4. Re-oxygenated blood is returned to the left atrium via the right and left pulmonary veins 5. Left atrium contracts, sending blood through the mitral valve and into the left ventricle 6. Left ventricle contracts, sending blood through the aortic Septum valve and to the body via the aorta 1 http://commons.wikimedia.org/wiki/File:Diagram_of_the_human_heart 2 _(cropped).svg Fun Fact….. Layers of the Heart Pulmonary Artery – The ONLY artery in the body that carries de-oxygenated blood Pulmonary Vein – The ONLY vein in the body that carries oxygenated blood 3 4 Layers of the Heart Endocardium Lines inner cavities of the heart & covers heart valves (Supplies left ventricle) Continuous with the inner lining of blood vessels Purkinje fibers located here; (electrical conduction system) Myocardium Muscular layer – the pump or workhorse of the heart “Time is Muscle” Epicardium Protective outer layer of heart (Supplies SA node Pericardium in most people) Fluid filled sac surrounding heart 5 6 http://stanfordhospital.org/images/greystone/heartCenter/images/ei_0028.gif 1 12/2/2016 What Makes the Heart Pump? Electrical impulses originating in the right atrium stimulate cardiac muscle contraction Your heart's
    [Show full text]
  • What Is Single Ventricle?
    LifeLife withwith aa SingleSingle VentricleVentricle StephenStephen Crumb,Crumb, APNAPN CoordinatorCoordinator CColumbusolumbus OOhiohio AAdultdult CCongenitalongenital HHearteart DiseaseDisease ProgramProgram Biology 101 Q. Your heart has ______ chambers? A. ___3____ Wrong! You need to study!! But you asked how many chambers MY heart has! My heart has only 3 chambers because I have a single ventricle !! ObjectivesObjectives DescribeDescribe thethe congenitalcongenital heartheart defectsdefects thatthat leadlead toto singlesingle ventricleventricle DiscussDiscuss longlong--termterm issuesissues thatthat maymay arisearise inin peoplepeople withwith singlesingle ventricleventricle andand howhow toto treattreat themthem DiscussDiscuss waysways toto staystay healthyhealthy LearnLearn fromfrom eacheach otherother TheThe NormalNormal HeartHeart WhatWhat isis SingleSingle Ventricle?Ventricle? AbnormalAbnormal heartheart structurestructure presentpresent atat birthbirth OnlyOnly oneone functionalfunctional pumpingpumping chamberchamber (ventricle)(ventricle) SeveralSeveral congenitalcongenital heartheart defectsdefects leadlead toto singlesingle ventricle,ventricle, aa featurefeature ofof allall isis cyanosiscyanosis CyanosisCyanosis BlueBlue colorcolor duedue toto lowlow bloodblood oxygenoxygen CausedCaused byby mixingmixing ofof oxygenoxygen--poorpoor (blue)(blue) bloodblood andand oxygenoxygen--richrich (red)(red) bloodblood MixingMixing isis necessarynecessary forfor initialinitial survivalsurvival HypoplasticHypoplastic LeftLeft
    [Show full text]
  • Visualizing Real Tim E Vasomotion in Vivo Using Optical Coherence
    A Visualizing real time vasomotion in vivo using Optical Coherence Tom ography Suhir Abuhajar 2012 Lancaster University-Physics Department-Nonlinear Biomedical Physics Submitted in fulfilment of the requirements for the degree of Doctor of Philosophy in Physics ProQuest Number: 11003436 All rights reserved INFORMATION TO ALL USERS The quality of this reproduction is dependent upon the quality of the copy submitted. In the unlikely event that the author did not send a com plete manuscript and there are missing pages, these will be noted. Also, if material had to be removed, a note will indicate the deletion. uest ProQuest 11003436 Published by ProQuest LLC(2018). Copyright of the Dissertation is held by the Author. All rights reserved. This work is protected against unauthorized copying under Title 17, United States C ode Microform Edition © ProQuest LLC. ProQuest LLC. 789 East Eisenhower Parkway P.O. Box 1346 Ann Arbor, Ml 4 8 1 0 6 - 1346 C ontents Declaration v Abstract vi Acknowledgment vii 1 Introduction 1 1.1 Motivation .................................................................................................... 1 1.2 Structure of the th esis ............................................................................. 2 1.3 Physiology of the skin ............................................................................. 5 1.3.1 Functions of the s k i n ................................................................... 7 1.3.2 Structure of human s k i n ............................................................ 9 1.3.3
    [Show full text]
  • ECG P Wave Abnormalities
    E lectrocardiography S eries Singapore Med J 2013; 54(1) : 4 CMEARTICLE ECG P wave abnormalities Li Ling Tan1, MBBS, MRCP, Swee Guan Teo1,2, MBBS, MRCP, Kian Keong Poh1,2, FRCP, FACC Fig. 1 ECG shows bifid P waves in leads II, III and aVF. CASE 1 tomography (CT) of his brain showed an infarct involving the CLINICAL PRESENTATION right putamen and internal capsule. He was otherwise A 58-year-old man presented to the emergency department asymptomatic. What does the electrocardiogram (ECG) in Fig. 1 with a one-week history of left-sided weakness. Computed show? 1Cardiac Department, National University Heart Centre, National University Health System, 2Department of Medicine, Yong Loo Lin School of Medicine, National University of Singapore, Singapore Correspondence: A/Prof Poh Kian Keong, Senior Consultant and Associate Professor, Cardiac Department, National University Heart Centre, 1E Kent Ridge Road, NUHS Tower Block, Level 9, Singapore 119228. [email protected] E lectrocardiography S eries 2a 2b Fig. 2 (a) Echocardiogram in the parasternal long axis view shows a calcified mitral valve. There is restricted opening and closing of the posterior mitral valve leaflet (thick arrow), as well as doming of the anterior mitral valve leaflet (thin arrow); (b) At diastole, the mitral valve opening is markedly reduced (outlined and labeled with an asterisk). RV: right ventricle; LV: left ventricle; LA: left atrium ECG INTERPRETATION CLINICAL COURSE ECG shows the presence of ‘P mitrale’ in multiple leads – inferior Transthoracic echocardiogram showed moderately severe mitral leads II, III and aVF, and also leads V2, V3 and V4. The duration stenosis (Fig.
    [Show full text]
  • Ventricular Repolarization Components on the Electrocardiogram Cellular Basis and Clinical Significance Gan-Xin Yan, MD, PHD, Ramarao S
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE Journal of the American College of Cardiology providedVol. by Elsevier 42, No. - 3,Publisher 2003 Connector © 2003 by the American College of Cardiology Foundation ISSN 0735-1097/03/$30.00 Published by Elsevier Inc. doi:10.1016/S0735-1097(03)00713-7 STATE-OF-THE-ART PAPER Ventricular Repolarization Components on the Electrocardiogram Cellular Basis and Clinical Significance Gan-Xin Yan, MD, PHD, Ramarao S. Lankipalli, MD, James F. Burke, MD, FACC, Simone Musco, MD, Peter R. Kowey, MD, FACC Wynnewood, Pennsylvania Ventricular repolarization components on the surface electrocardiogram (ECG) include J (Osborn) waves, ST-segments, and T- and U-waves, which dynamically change in morphol- ogy under various pathophysiologic conditions and play an important role in the development of ventricular arrhythmias. Our primary objective in this review is to identify the ionic and cellular basis for ventricular repolarization components on the body surface ECG under normal and pathologic conditions, including a discussion of their clinical significance. A specific attempt to combine typical clinical ECG tracings with transmembrane electrical recordings is made to illustrate their logical linkage. A transmural voltage gradient during initial ventricular repolarization, which results from the presence of a prominent transient ϩ outward K current (Ito)-mediated action potential (AP) notch in the epicardium, but not endocardium, manifests as a J-wave on the ECG. The J-wave is associated with the early repolarization syndrome and Brugada syndrome. ST-segment elevation, as seen in Brugada syndrome and acute myocardial ischemia, cannot be fully explained by using the classic concept of an “injury current” that flows from injured to uninjured myocardium.
    [Show full text]
  • Time-Varying Elastance and Left Ventricular Aortic Coupling Keith R
    Walley Critical Care (2016) 20:270 DOI 10.1186/s13054-016-1439-6 REVIEW Open Access Left ventricular function: time-varying elastance and left ventricular aortic coupling Keith R. Walley Abstract heart must have special characteristics that allow it to respond appropriately and deliver necessary blood flow Many aspects of left ventricular function are explained and oxygen, even though flow is regulated from outside by considering ventricular pressure–volume characteristics. the heart. Contractility is best measured by the slope, Emax, of the To understand these special cardiac characteristics we end-systolic pressure–volume relationship. Ventricular start with ventricular function curves and show how systole is usefully characterized by a time-varying these curves are generated by underlying ventricular elastance (ΔP/ΔV). An extended area, the pressure– pressure–volume characteristics. Understanding ventricu- volume area, subtended by the ventricular pressure– lar function from a pressure–volume perspective leads to volume loop (useful mechanical work) and the ESPVR consideration of concepts such as time-varying ventricular (energy expended without mechanical work), is linearly elastance and the connection between the work of the related to myocardial oxygen consumption per beat. heart during a cardiac cycle and myocardial oxygen con- For energetically efficient systolic ejection ventricular sumption. Connection of the heart to the arterial circula- elastance should be, and is, matched to aortic elastance. tion is then considered. Diastole and the connection of Without matching, the fraction of energy expended the heart to the venous circulation is considered in an ab- without mechanical work increases and energy is lost breviated form as these relationships, which define how during ejection across the aortic valve.
    [Show full text]
  • Cardiology- the ABC's of the PQRST
    Cardiology- the ABC’s of the PQRST Heather Carter LVT, VTS (Anesthesia & Analgesia) Introduction Understanding cardiology can provide the anesthetist with the ability to trouble shoot and treat various problems. Knowing when and how to treat a bradycardia versus a tachycardia can ensure a smooth anesthetic event. Origin of the Heartbeat http://i.pinimg.com/736x/9b/70/59/9b7059c20a452fc655a26e9e3e4b40ad.jpg Understanding the origin of the heartbeat can help the anesthetist know when and how to identify a potential problem. An ECG complex consists of a PQRST complex. The sinoatrial node (SA) is the pacemaker of the heart and produces the P wave. The QRS wave is produced by the atrioventricular node (AV). The P wave in an ECG complex indicates atrial depolarization. The QRS is responsible for ventricular depolarization and the T wave is ventricular repolarization. If a P wave is absent there is a lack of atrial depolarization. This is also known as atrial standstill. P waves that are combined in the QRS complexes are indicative of ventricular tachycardia or a junctional tachycardia. Present P waves that are without a QRS are indicative of an atrial depolarization that has not been conducted through the AV node. A QRS complex without a P wave demonstrate premature or escape beats. Essentials Arrhythmias can be identified with ease if several essentials are in place. ECG leads should be placed correctly: White- Right forelimb Black- Left forelimb Green- Right hind limb Red- Left hind limb Determining the paper speed (25mm/sec vs 50mm/sec) will also help the anesthetist determine if a bradycardia or tachycardia is present.
    [Show full text]
  • Effect of Mental Stress on Myocardial Blood Flow and Vasomotion in Patients with Coronary Artery Disease
    Effect of Mental Stress on Myocardial Blood Flow and Vasomotion in Patients with Coronary Artery Disease Heiko Schoder, Daniel H. Silverman, Roxana Campisi, Harold Karpman, Michael E. Phelps, Heinrich R. Schelbert, and Johannes Czernin Department ofMolecular and Medical Pharmacology, Division ofNuclear Medicine, School ofMedicine, University of California, Los Angeles; and Laboratory ofStructural Biology and Molecular Medicine, University ofCalifornia, Los Angeles, California dial oxygen demand is physiologically accommodated by an In patients with coronary artery disease (CAD), mental stress increase in myocardial blood flow (MBF). Therefore, in may provoke ischemic electrocardiographchanges and abnor healthy individuals mental stress induces coronary artery malities in regionaland global left ventricularfunction. However, vasodilatation (3,4). In patients with coronary artery disease little is known about the underlyingmyocardialblood flow (CAD), however, mental stress modeled in a laboratory or response(MBF)inthesepatients.Methods: We investigatedthe experienced in daily life can induce myocardial ischemia as hemodynamic, neurohumoral, and myocardial blood flow re sponses to mental stress in 17 patients with CAD and 17 healthy evidenced by ischemic changes on electrocardiography volunteers of similar age. Mental stress was induced by asking (ECG) (5), left ventricular wall motion abnormalities, and a individualsto solve mathematicsubtractionsin a progressively decline in left ventricular ejection fraction (6, 7). Such challenging sequence; MBF was quantified at rest and during abnormal responses to mental stress may also predict mentalstressusing13NammoniaPET.Results:Mentalstress ischemic events, such as unstable angina pectoris or myocar induced significant (P < 0.01) and comparable increases in dial infarction, in daily life (8,9). rate—pressureproduct, measured in beats per minute x mm Hg, The mechanisms underlying these mental stress—induced in bothpatients(from7826 ±2006to 10586±2800)and healthy volunteers (from 8227 ±1272 to 10618 ±2468).
    [Show full text]