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1600JohnF.KennedyBlvd. Ste1800 Philadelphia,PA19103-2899 CHOU’SELECTROCARDIOGRAPHYINCLINICALPRACTICE ISBN:978-1-4160-3774-3 SIXTHEDITION Copyright#2008,2001,1996,1991,1986,1979bySaunders,animprintofElsevierInc. Allrightsreserved.Nopartofthispublicationmaybereproducedortransmittedinanyformorby anymeans,electronicormechanical,includingphotocopying,recording,oranyinformationstorage andretrievalsystem,withoutpermissioninwritingfromthepublisher.Permissionsmaybesought directlyfromElsevier’sRightsDepartment:phone:(þ1)2152393804(US)or(þ44)1865843830(UK); fax:(þ44)1865853333;e-mail:healthpermissions@elsevier.com.Youmayalsocompleteyourrequeston-line viatheElsevierwebsiteathttp://www.elsevier.com/permissions. Notice Knowledgeandbestpracticeinthisfieldareconstantlychanging. Asnewresearchandexperience broadenourknowledge,changesinpractice,treatment,anddrugtherapymaybecomenecessaryor appropriate.Readersareadvisedtocheckthemostcurrentinformationprovided(i)onprocedures featuredor(ii)bythemanufacturerofeachproducttobeadministered,toverifytherecommendeddose orformula,themethodanddurationofadministration,andcontraindications.Itistheresponsibilityof thepractitioner,relyingontheirownexperienceandknowledgeofthepatient,tomakediagnoses,to determinedosagesandthebesttreatmentforeachindividualpatient,andtotakeallappropriatesafety precautions.Tothefullestextentofthelaw,neitherthePublishernortheEditorsassumeanyliabilityfor anyinjuryand/ordamagetopersonsorpropertyarisingoutoforrelatedtoanyuseofthematerial containedinthisbook. ThePublisher LibraryofCongressCataloging-in-PublicationData Surawicz,Borys,1917- Chou’selectrocardiographyinclinicalpractice/BorysSurawicz,TimothyK.Knilans.—6thed. p.;cm. Includesbibliographicalreferencesandindex. ISBN978-1-4160-3774-3 1.Electrocardiography—Interpretation.2.Heart—Diseases—Diagnosis.I.Knilans,TimothyK.II.Chou, Te—Chuan,1922-Electrocardiographyinclinicalpractice.III.Title.IV.Title:Electrocardiographyin clinicalpractice. [DNLM:1.Electrocardiography—methods.2.HeartDiseases—diagnosis.WG140S961c2008] RC683.5.E5C4542008 616.10207547—dc22 2007048392 ExecutivePublisher:NatashaAndjelkovic EditorialAssistant:IsabelTrudeau ProjectManager:MaryStermel DesignDirection:KarenO’KeefeOwens MarketingManager:ToddLiebel PrintedintheUnitedStates Lastdigitistheprintnumber: 9 8 7 6 5 4 3 2 1 ThiseditionisdedicatedtoDr.Te-ChuanChou,theauthorofthefirstfoureditions,asamarkofrespectfor his scholarship and understanding of this subject. PREFACE After the publication of his textbook Clinical myocardial infarction (STEMI) and non-STEMI, Electrocardiograpy in 1956, Dr. Louis Katz was stresstest,QTinterval,andpacemakers.Dr.Tim- saidtodeclarethatelectrocardiographywasfully othy Knilans updated the section on pediatric explored,implyingnoneedforfurtherinvestiga- electrocardiography,mostextensivelythechapter tionsinthisfield.Similarverdictshavebeenpro- on cardiac arrhythmias. Given that the backbone nouncedinsubsequentyears,provingthemtobe of an ECG textbook are the illustrations, many consistently wrong in the face of the continuing figures in this edition were added and replaced. flow of new information about the electrocardio- I am indebted to Drs. HJJ Wellens, APM gram (ECG) in synchrony with the continuing Gorgels, and PA Doevedans, authors of the progress in other areas of cardiology. monograph The ECG in Acute Myocardial Infarc- As envisioned by the author of the first four tion and Unstable Angina, for their permission editions, Dr. Chou, this text is primarily clinical, to reproduce several figures, and to Dr. Serge with sufficient basic science foundation and S.Baroldforallowingustoincludenewinforma- bibliographytounderstandthegenesisofdiverse tion and figures in the chapter on cardiac pace- ECG patterns. In the 7 years since the publica- makers. I am grateful to Mrs. Terri Scott for her tion of the fifth edition, valuable new infor- invaluable secretarial assistance. mation emerged that necessitated complete revisionofthesections dealingwithST-elevation BORYSSURAWICZ,M.D.,M.A.C.C. vii CONTRIBUTING AUTHORS Lawrence E. Gering, M.D., F.A.C.C. Borys Surawicz, M.D., M.A.C.C. Owensboro Mercy Health System Professor Emeritus Owensboro, Kentucky; and Indiana University School of Medicine Riverview Hospital Indianapolis, Indiana Noblesville, Indiana Morton E. Tavel, M.D., F.C.C.P. Timothy K. Knilans, M.D. The Indiana Heart Institute Associate Professor, Pediatrics Care Group, Inc. University of Cincinnati School of Medicine Indianapolis, Indiana Director, Clinical Cardiac Electrophysiology and Pacing The Children’s Hospital Medical Center Cincinnati, Ohio ix (cid:1) ADULT SECTION I ELECTROCARDIOGRAPHY 1 Normal Electrocardiogram: Origin and Description OriginoftheElectrocardiogram NormalECG DepolarizationandRepolarization PWave Dipoles PRInterval PotentialDeclinewithIncreasing VentricularActivation(QRSComplex) Distancefromthe Heart CommonNormalVariants SolidAngleTheorem VolumeConductor S1S2S3Pattern RSR1PatterninLeadV 1 MethodsofRecording “EarlyRepolarization”Variant ECGLeads PoorRWaveProgression inPrecordial Vectorcardiography Leads Magnetocardiography Athlete’sHeart BodySurfaceMapping ObesityandEdema Signal-AveragedECG theory is based on an elementary model of a Origin of the Electrocardiogram single fiber surrounded by a homogeneous medium. In such fibers, during resting the pos- The waveform of the electrocardiogram (ECG) itive and negative boundaries are equal and recorded from the body surface depends on the opposite in sign for the extent of the conductor. properties of the generator (i.e., cardiac action This means that the polarized surface is closed, potential),thespreadofexcitation,andthechar- and no potential is recorded (Figure 1–2, top acteristicsofthevolumeconductor.Theelectro- tracing). When the excitation wave invades cardiographic theory attempts to integrate these the fiber and reverses the charges across the three elements.1 membrane, currents flow outside the fiber, Figure 1–1 shows the temporal relation inside the fiber, and across the membrane, as between the atrial and ventricular action poten- indicated by the arrows in Figure 1–1 (second tials and the surface ECG. The P wave is derived tracing from top). This creates potential differ- fromatrialdepolarization,theQRScomplexfrom ences of depolarization, which disappear when ventricular depolarization, the ST segment from the double layer again becomes homogeneous phase 2 (plateau), and the Twave from phase 3 in the fully activated state, as shown in the of the ventricular action potential. The activity middle tracing of Figure 1–2. Subsequently a of the conducting system is not represented on transition from an activated to a resting state the surface ECG. Intracardiac electrodes can be occurs, a process of repolarization shown in used to record His bundle potential and signals Figure 1–2 (fourth and fifth tracings from top). from other parts of the conducting system. DEPOLARIZATION AND DIPOLES REPOLARIZATION The he art conta ins about 10 10 cells. Each insta nt Potential differences generated during cardiac of depolarization or repolarization represents activitysetupcurrentsintheconductorssurround- different stages of activity for a large number of ing the heart. A simplified electrocardiographic cells,andanelectromotiveforcegeneratedateach 1 2 SECTIONI (cid:1) AdultElectrocardiography Figure1–1 Timingofcardiacactionpotentialsrecorded during inscription of an ECG complex. The action poten- tials responsible for the atrial and ventricular activation are designated manifest and those responsiblefor impulse initiationandpropagationasconcealed.Seetext. Figure1–2 Restingstate,depolarization,andrepolariza- instant represents a sum of uncanceled potential tioninasinglecell,thetwoendsofwhichareconnectedto differences. A potential difference between two agalvanometer.OntherightareECGdeflectionsresulting surfaces or between two poles carrying opposite from the polarization changes in the diagram on the left. chargesformsadipole,themagnitude(moment), (From Surawicz B: Electrocardiogram. In: Chatterjee K, ParmleyWW[eds]:Cardiology.Philadelphia,JBLippincott, polarity,anddirectionofwhichcanberepresented 1991,bypermission.) by a vector.* The ECG records the sequence of suchinstantaneousvectorsattributedtoanimagi- narydipolethatchangesitsmagnitudeanddirec- tion during impulse propagation. During activity therecordingelectrodeisinfluencedbythepoten- tial difference across the boundary; the record of activity, represented by an instantaneous vector, depends on the position of the electrode within theelectricalfieldcreatedbythedipole. Figure 1–3 represents an electrical field with acentrallocationofadipoleinanidealhomoge- neousmedium.Thesolidlinesrepresentpositive and negative isopotential lines. The maximum potentialsaregivenvaluesofþ20and–20.They are in close proximity to the poles of the dipole (i.e., the source and the sink). The potentials decrease with increasing distance from the dipole. The vertical interrupted line that trans- ects the dipole isa zeropotential line. The leads totherightofthislinerecordpositivepotentials, Figure 1–3 Electrical field generated by a dipole (-/þ). (From Surawicz B: Electrocardiogram. In: Chatterjee K, *A dipole is a source-sink pair separated by a short ParmleyWW[eds]:Cardiology.Philadelphia,JBLippincott, distance. 1991,bypermission.) 1 (cid:1) NormalElectrocardiogram:OriginandDescription 3 and those to the left of the line record negative same time it can be understood that the anterior potentials. An electrode connecting two points precordial leads, owing to their proximity to the on the isopotential line records no potential heart,areinfluencedbythelocalpotentialsgener- differences. ated in the structures lying directly underneath In the prototype model of Einthoven et al.,2 the corresponding electrodes. the postulated generator of cardiac activity was a single dipole at the center of the triangle, and SOLID ANGLE THEOREM the postulated volume conductor was both homogeneous and unbounded. This oversimpli- The basic concept applicable to the analysis of fied model remains useful for teaching electro- the body surface potentials states that at any cardiography at the elementary level. It does givenpoint,therecordedpotentialisdetermined not explain, however, the three-dimensional by the productof a solid angle subtended at this (3D) distribution of cardiac electrical activity in point by the boundary between the opposing theheartateachpointintimeduringthecardiac charges and the charge density per unit area cycle. It has been suggested that the electromo- across the boundary (Figure 1–4). This means tive forces generated by ventricular excitation that for any given charge density, the deflection canbe expressedmore properlyby theelectrical recorded by the electrode facing the boundary field of several dipoles rather than by that of a increases with increasing surface of the bound- single dipole.3 aryand,conversely,thatforanygivendimension of the boundary surface, the magnitude of the POTENTIAL DECLINE WITH recorded deflection increases with increasing INCREASING DISTANCE charge density across the boundary. The solid FROM THE HEART angletheoremhasbeenfoundusefulforanalysis of potential differences caused by injury cur- It has been established that in the volume con- rents4 (see Chapter 7). ductor with the properties of the human thorax, the potential declines approximately in propor- VOLUME CONDUCTOR tion to the square of the distance. This means that,forpracticalpurposes,allpointsonthetorso The conductivity of tissues surrounding the situatedatadistanceofmorethantwodiameters heartinfluencestheamplitudeoftheECGdeflec- oftheheartareapproximately“electrically”equi- tions. Tissues with low conductivity decrease the distant from the generator. Thus the remoteness amplitude of the ECG deflections. Low voltage ofthe electrodesplacedonthe extremities issuf- is present when the lungs are hyperinflated or ficienttominimizethenondipolarcomponentsof when the heart is insulated by a large amount of the ECG caused by the proximity effect. At the fat.Lowvoltagecanalsobecausedbypericardial Figure1–4 Potentialsgeneratedbyanexcitationwaveofsourcesandsinksarerelatedtothesolidangleoftheexcitation waveasseenfromthefieldpoint.Thesolidangleisthefractionofaunitspheresubtendedbyathree-dimensionalobject. Thesymbolis thepotentialgeneratedby theillustratedsource-sinkboundary.Thispotentialisdeterminedby thecharge densityacrosstheboundary,thesolidangle,andthereciprocalofthesquareofthedistancefromtheboundarytothefield point.(FromBarrRC:Genesisoftheelectrocardiogram.In:MacfarlanePW,LawrieTD[eds]:ComprehensiveElectrocardiol- ogy.NewYork,Pergamon,1989.Copyright1989ElsevierScience,bypermission.) 4 SECTIONI (cid:1) AdultElectrocardiography and pleural effusions or edema owing to the short-circuiting action of these well-conducting fluids. Methods of Recording ECG LEADS To study the electromotive forces generated dur- ing the propagation of cardiac impulses, it is necessary to attach the leading electrodes to the heart or to the body surface. When one or both electrodes are in contact with the heart, the ECGleadsarecalleddirect.When theelectrodes are placed at a distance of more than two car- diac diameters from the heart, the leads are called indirect. Semidirect leads designate an arrangement in which one or both electrodes Figure 1–5 are in close proximity but not in direct contact Einthoven’s triangle showing the projection ofavectorontheaxesofthreestandardlimbleads.(From with the heart. The leads are considered bipolar Surawicz B: Electrocardiogram. In: Chatterjee K, Parmley when both electrodes face sites with similar WW [eds]: Cardiology. Philadelphia, JB Lippincott, 1991, potentialvariationsandunipolarwhenpotential bypermission.) variations of one electrode are negligible in comparison with those of the other. Of the 12 standard ECG leads, I, II, and III are indirect and bipolar; aV , aV , and aV are indirect and R L F unipolar; and V through V are semidirect 1 6 and unipolar.* The three standard limb leads were designed byEinthoventorepresentthreesidesofanequi- lateral triangle in which the heart is positioned at the center (Figure 1–5). As stated previously, this concept arose from an assumption that the electromotive forces of the heart could be repre- sentedbyasinglevectorcenteredinthistriangle. According to Einthoven’s law, the magnitude of thedeflectioninleadIIequalsthesumofdeflec- tionsinleadsIandIII.Figure1–6illustratesthis point. Although a more accurate system of elec- trode placement at points equidistant from the heart has been proposed by other investigators, theuseofEinthoven’sleadshasbecomeuniver- sally entrenched. The unipolarchest leads were Figure 1–6 introducedbyWilsonforthepurposeofdimin- Einthoven’s law. Note an isoelectric QRS ishing the influence of the distant reference complexinleadIIasaresultofequalamplitudesofoppo- sitepolarityinleadsIandIII. electrode. He constructed a zero potential elec- trode (V) by connecting the three limb electro- desthroughequalresistancesof5000ohmstoa terminal to the individual limb electrodes central terminal. Wilson and coworkers5 devel- (V ,V ,V ).Subsequently,Goldberger6discon- oped the system of unipolar chest leads and R L F nected the resistors placed between the limb unipolar limb leads taken from the central and the central terminal and thus augmented (a) the voltage of these leads about 1.5 times (aV , aV , aV ). The relation between the stan- *TheuseofthetermunipolarinreferencetoECGleadsis R L F dard and unipolar augmented leads is as fol- controversial because the potential at the central terminal poleisnotnegligible. lows: 1 (cid:1) NormalElectrocardiogram:OriginandDescription 5 aV þaV þaV ¼0 R L F ThedirectionofleadIis0degrees;leadII,60 degrees; lead III, 120 degrees; lead aV , 90 F degrees; lead aV , –30 degrees; and lead aV , L R –150 degrees. Lead Display The traditional sequence of lead display in a standard 12-lead ECG is: I, II, III, aV , aV , R L aV ,andV –V .Thissequencedisplayslogically F 1 6 theprecordialleads,butnotnecessarilythelimb leads, where the displayed panoramic clockwise sequence would be: aVL, I, –aVR, II, aVF, and III. Figure 1–7 Directions of the lead axes of leads V1 The latter display was endorsed by a large num- throughV . 6 ber of leading electrocardiographers7 but has not yet prevailed to alter the established tradition. Intrinsic and Intrinsicoid Deflections Vectors and Electrical Axis When the electrical activity on the cardiac sur- Theelectromotiveforcegeneratedbytheheartat face is recorded by means of a unipolar lead, any instant can be represented by the vector the activation front approaching the electrode forceofasingleequivalentdipolesituatedatthis registers an upright deflection, but as soon as point. This vector points from the negative to the activation front reaches the electrode, the thepositivepotential(coincidentwiththedirec- direction changes and the electrogram records tion of the impulse propagation), and its magni- a rapid negative deflection, which is referred to tude is proportional to the magnitude of the as intrinsic. The validity of this concept, pro- electromotive force. The voltage registered in a posed by Lewis et al. in 1914, was supported given lead corresponds to the projection of the by the experiments of Dower.8 cardiac vector on the axis of the lead (see Dower showed that an electrode placed on Figure 1–5). The maximum deflection is the surface of the guinea pig heart inscribes registered when the vector is parallel, and the a negative deflection that coincides with the minimum deflection is seen when the vector is upstroke of the ventricular action potential in perpendicular to the lead axis. theimmediatelysubjacentcell.InDower’sstudy, The maximum QRS vector is used to define theintrinsicdeflectionwasmarkedmoresharply the main axis. This vector usually corresponds ontheleftthanontherightsurfaceoftheheart.8 to the R axis. The mean QRS axis is the average Thetransitionfrompositivetonegativeisless ofallinstantaneousvectorsduringtheQRScom- abrupt in semidirect unipolar precordial leads plex.The general phrase “electrical heart axis in than in direct leads, which makes the intrinsic thefrontalplane”issometimesusedinreference deflection less rapid and less distinct. For this to the main axis and sometimes to the mean reason, this deflection was designated by axis. This designation is meaningful only when McLeod et al. in 1930 as intrinsicoid. The onset one dominant deflection is present in at least of an intrinsicoid deflection in the precordial one of the limb leads. When the QRS complex leads corresponds to the peak of the tall R wave is biphasic in all leads, the meaning of the aver- or the nadirof the deep S wave. The onset of an age QRS axis changes because the vectorcardio- intrinsicoiddeflectionmaybedelayedifthedura- graphic QRS loop (see later discussion) is tionof the excitationwave spreadingtowardthe nearly circular. Such a biphasic pattern with an recording electrode is prolonged owing to indeterminate axis is described preferably as a increased ventricular wall thickness. In the right sequence of two main axes corresponding to precordial leads the upper limit of normal is the initial and terminal deflections. 0.035 second, and in the left precordial leads it Thesemidirectprecordialleadsintroducedby is 0.045 second. This interval is used mostly to Wilson record the potential differences between diagnose ventricular hypertrophy and bundle the chest electrodes and the central terminal branch block when the onset of the intrinsicoid (V) electrode at locations shown in Figure 1–7. deflectionisdelayed.

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Widely considered the optimal electrocardiography reference for practicing physicians, and consistently rated as the best choice on the subject for board preparation, this is an ideal source for mastering the fundamental principles and clinical applications of ECG. The 6th edition captures all of th
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