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In conditions affecting the [[pericardium]] or diseases that primarily affect the heart muscle ([[restrictive cardiomyopathy|restrictive cardiomyopathies]]) a similar sound can be heard, but is usually more high-pitched and is called a 'pericardial knock'.
In conditions affecting the [[pericardium]] or diseases that primarily affect the heart muscle ([[restrictive cardiomyopathy|restrictive cardiomyopathies]]) a similar sound can be heard, but is usually more high-pitched and is called a 'pericardial knock'.


The S3 can also be confused with a widely split S2, or a mitral opening snap, but these sounds are typically of much higher pitch and occur closer to the onset of S2.
The S<sub>3</sub> can also be confused with a widely split S<sub>2</sub>, or a mitral opening snap, but these sounds are typically of much higher pitch and occur closer to the onset of S2.


=====Fourth heart sound S<sub>4</sub>=====
=====Fourth heart sound S<sub>4</sub>=====
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Grading the loudness of a murmur from 1 to 6 is a well described and widely used method <ref> Freeman AR, Levine SA. Clinical significance of systolic murmurs: study of 1000 consecutive "noncardiac" cases. Ann Intern Med. 1933, 6: 1371–85. </ref> Systolic thrills usually are associated with murmurs of grade 4 or louder.  
Grading the loudness of a murmur from 1 to 6 is a well described and widely used method <ref> Freeman AR, Levine SA. Clinical significance of systolic murmurs: study of 1000 consecutive "noncardiac" cases. Ann Intern Med. 1933, 6: 1371–85. </ref> Systolic thrills usually are associated with murmurs of grade 4 or louder.  


====[[Mitral regurgitation]]====
=====[[Mitral regurgitation]]=====


[[Mitral regurgitation]] can develop as a result of either [[papillary muscle dysfunction]] or as a result a dilation of the mitral apparatus secondary to left ventricular dilation. <ref>Birnbaum Y, Chamoun AJ, Conti VR, Uretsky BF. Mitral regurgitation following acute myocardial infarction. Coronary Artery Disease: Volume 13 (6) September 2002 337-344 </ref> <ref>Bursi F, Enriquez-Sarano M, Jacobsen SJ, Roger VL. Mitral regurgitation after myocardial infarction: a review. Am J Med. 2006 Feb;119(2):103-12. PMID 16443408 [[Mitral regurgitation]] generally results in a blowing holosystolic murmur best heard at the apex. If there has been rupture of the head of the [[papillary muscle]], a thrill may be palpated ([[ST elevation myocardial infarction complications|see complications]]).</ref> <ref>Maisel AS, Gilpin EA, Klein L, Le Winter M, Henning H, Collins D. The murmur of papillary muscle dysfunction in acute myocardial infarction: clinical features and prognostic implications. Am Heart J. 1986 Oct;112(4):705-11</ref>
[[Mitral regurgitation]] can develop as a result of either [[papillary muscle dysfunction]] or as a result a dilation of the mitral apparatus secondary to left ventricular dilation. <ref>Birnbaum Y, Chamoun AJ, Conti VR, Uretsky BF. Mitral regurgitation following acute myocardial infarction. Coronary Artery Disease: Volume 13 (6) September 2002 337-344 </ref> <ref>Bursi F, Enriquez-Sarano M, Jacobsen SJ, Roger VL. Mitral regurgitation after myocardial infarction: a review. Am J Med. 2006 Feb;119(2):103-12. PMID 16443408 [[Mitral regurgitation]] generally results in a blowing holosystolic murmur best heard at the apex. If there has been rupture of the head of the [[papillary muscle]], a thrill may be palpated ([[ST elevation myocardial infarction complications|see complications]]).</ref> <ref>Maisel AS, Gilpin EA, Klein L, Le Winter M, Henning H, Collins D. The murmur of papillary muscle dysfunction in acute myocardial infarction: clinical features and prognostic implications. Am Heart J. 1986 Oct;112(4):705-11</ref>


====[[Ventricular septal defect]]====
=====[[Ventricular septal defect]]=====


The development of a ventricular septal defect is associated with a holosystolic murmur and thrill which are most prominent along the left and right sternal border ([[ST elevation myocardial infarction complications|see complications]]).
The development of a ventricular septal defect is associated with a holosystolic murmur and thrill which are most prominent along the left and right sternal border ([[ST elevation myocardial infarction complications|see complications]]).


====[[Tricuspid regurgitation]]====
=====[[Tricuspid regurgitation]]=====


Either right ventricular infarction or rupture of a right ventricular papillary muscle may result in tricuspid regurgitation.  This is a systolic murmur that is best heard along the left sternal border. In general, it is intensified by inspiration.  Tricuspid regurgitation may be associated with a prominent c-v wave in the jugular venous pulse.
Either right ventricular infarction or rupture of a right ventricular papillary muscle may result in tricuspid regurgitation.  This is a systolic murmur that is best heard along the left sternal border. In general, it is intensified by inspiration.  Tricuspid regurgitation may be associated with a prominent c-v wave in the jugular venous pulse.
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</div>
</div>


====[[Pericardial friction rub|Pericardial friction rubs]]====
=====[[Pericardial friction rub|Pericardial friction rubs]]=====


A pericardial friction rub is often best heard over the left sternal border, but many also be prominent at the apex of the heart.  In general, a rub is heard in both systole and  diastole. If it is heard only in systole, it may be mistaken for a systolic murmur. In general a rub is more scratchy and squeaky in nature compared with a murmur, which is more blowing or rumbling in character.
A pericardial friction rub is often best heard over the left sternal border, but many also be prominent at the apex of the heart.  In general, a rub is heard in both systole and  diastole. If it is heard only in systole, it may be mistaken for a systolic murmur. In general a rub is more scratchy and squeaky in nature compared with a murmur, which is more blowing or rumbling in character.

Revision as of 16:52, 5 February 2009

Myocardial infarction
ICD-10 I21-I22
ICD-9 410
DiseasesDB 8664
MedlinePlus 000195
eMedicine med/1567  emerg/327 ped/2520

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Physical examination

Role of the Physical Examination in ST Elevation MI

The physical examination in patients who have suspected acute myocardial infarction may reveal arrhythmia, evidence of heart failure, a new murmur, or cardiovascular compromise and shock. A systems focused examination is probably most appropriate at the time of presentation so as to not delay decisions regarding and implementation of reperfusion therapy. Following these initial stages of management, a more through examination is then warranted. Throughout the patient's course, detailed serial examinations should be performed in an effort to remain vigilant for the development of mechanical complications of acute MI.

Initial Physical Examination at the time of Presentation

Assess the Appropriateness of the Patient for Reperfusion Therapy

The focus of the initial physical examination should be directed towards evaluating the appropriateness of the patient for reperfusion therapy. In particular, contraindications fibrinolytic therapy should be thoroughly evaluated. The presence of aortic dissection should be excluded as should the presence of pericarditis. Thus if the patient has complaints such as back pain or interscapular pain that would suggest aortic dissection, the blood pressure should be evaluated in both arms and any discrepancy should be noted. Likewise, the presence of aortic insufficiency should be noted during cardiac auscultation. Careful auscultation of the heart to be performed to also assure that there is no pericardial friction rub to suggest the presence of pericarditis.

Likewise, the presence of the focal neurologic defect should be noted. A careful assessment of the patient's risk of bleeding should be assessed, including the assessment for occult bleeding from the G.I. tract if there is a suspicion.

If the patient is to undergo primary percutaneous coronary intervention (PCI) then careful assessment of the femoral pulses should be made. The strength of the pulses and the presence of bruits should be assessed. In particular, it should be anticipated that an intra-aortic balloon pump may need to be placed. If the choice is to proceed from the right femoral artery, then the ability to place an intra-aortic balloon pump in the left femoral artery should be noted.

Assess the Patient for the Presence of Right Ventricular Myocardial Infarction

Administration of nitrates are an important part of the initial management of patients with ST elevation MI. Patients who are treated with nitrates may become hypotensive in the presence of a right ventricular infarction. Therefore a careful assessment for signs of right ventricular myocardial infarction should be performed. If right heart failure is present, elevated jugular venous pressure and hepatojugular reflux, or swelling of the legs due to peripheral edema may be found on physical examination. The presence of ST segment elevation on right sided leads (V4R) are critical in establishing the diagnosis of RV infarction. In the patient with ST segment elevation in inferior leads, right sided leads should be obtained to quickly aid in the diagnosis of RV infarction, particularly if signs of RV failure or hypotension are present.

Assess the Patient for the Presence of Hypoperfusion and Left Ventricular Failure

Administration of beta blockers, angiotensin converting enzyme inhibitors and other vasoactive medications are part of the initial management of acute MI. Therefore, at the time of the initial evaluation, a careful assessment of tissue perfusion should be made. Classically, patients with acute MI move around in the bed so that they can find a more comfortable position. This is in contrast to patients with angina who often lie still. However, in the presence of cardiogenic shock, the patient may lie still. As a result of intense vasoconstriction from heightened sympathetic tone, systemic blood pressure may not reveal the presence of a shock like state. In the presence of intense vasoconstriction, the skin is often cool, clammy, mottled and pale. The lips and the nail beds may be cyanotic. In cases of severe hypoperfusion the patient may be either confused and/or disoriented. Rales on the lung exam are are indicative of left heart failure. The presence of tachycardia may also suggest a low perfusion state.

Rarely, a cardiac bulge with a pace different from the pulse rhythm can be felt on precordial examination. Varioaus abnormalities can be found on auscultation, such as a third and fourth heart sound, systolic murmurs, paradoxical splitting of the second heart sound, a pericardial friction rub and rales over the lung.[1]

Complete Phsyical Examination of the Patient After the Initial Rapid Assessment

The purpose of the physical examination following initial presentation is to monitor the patient for the development of mechanical complications and to monitor the patient's response to therapeutic interventions. The presence of indwelling catheters is no replacement for a careful daily physical examination. In fact, careful physical examination should often suffice in replacing the need for hemodynamic monitoring and in patients. Careful attention to the pulse, blood pressure, the neck veins, the presence of rales, and the urine output should all be used to guide therapeutic interventions. [1]

Temperature

Some patients may have low-grade fever (38–39 °C) and an elevated white blood cell count in the setting of acute MI.

Pulse

The heart rate will vary depending upon infarct artery location and the presence of left ventricular dysfunction. Upon presentation many patients are anxious and in pain. This may result in a hyperadrenergic state which in turn may result in the sinus tachycardia. Patients with left ventricular failure will obviously develop sinus tachycardia. Inferior myocardial infarction is often associated with various degrees of heart block and bradycardia (see complications). The presence of pulsus alternans (an alternating strong and weak pulse) may reflect the presence of left ventricular dysfunction. Both mitral regurgitation and the development of a new ventricular septal defect may be associated with a more abrupt rise and fall in the pulse (see complications).

Blood Pressure

It is critical to obtain a complete prior history to place the patient's blood pressure in the appropriate context. Normotension in a patient who was previously hypertensive can be reflective of poor LV function. Again as noted in the above section on the pulse, upon presentation many patients are anxious and in pain and this hyperadrenergic state may result in a hypertensive response in a patient who was previously normotensive.

It should be noted that the blood pressure during the initial course of myocardial infarction generally does not reflect what a patient's blood pressure will ultimately be at the time of discharge. In general, it is not uncommon for patients with an inferior MI to be hypotensive at some point early in their admission due to autonomic dysfunction. Likewise, it is not uncommon for a patient with an anterior MI to be hypertensive in the early phase infarction due to an early surge in adrenergic tone.

Hypotension in the early course of acute myocardial infarction has two broad causes. One is cardiogenic shock (see complications). These patients will have a systolic blood pressure below 90 mm Hg and will have evidence of end-organ hypoperfusion. In general, they will be tachycardic. Cardiogenic shock is more often seen in patients with infarction involving the left ventricle. In contrast, patients with activation of the Bezold-Jarisch reflex will in general not be tachycardic and may instead be bradycardic. This reflex activation is more common in patients with an inferior myocardial infarction. Whereas cardiogenic shock will persist for a protracted period of time, the Bezold-Jarisch reflex will generally resolve in a shorter period of time, and is responsive to fluids, atropine (0.5 to 1.0 mg IV) and elevation of the legs (Trendelenburg position).

Cardiac Exam

Heart Sounds

Third heart sound (S3)

This sound is called a protodiastolic gallop or ventricular gallop , a type of gallop rhythm occurs when the left ventricle is not very compliant, and at the beginning of diastole the rush of blood into the left ventricle suddenly is halted, resulting in a vibration of the ventricle and surrounding structures. It is caused by the sudden slowing of blood rushing in from the atrium into the ventricle as it is relaxing.

Differential Diagnosis of Causes of an S3

It is associated with heart failure, caused by conditions which have:

  • Rapid ventricular filling
  • Mitral regurgitation - this is when one of the heart valves that usually stops blood going from the left ventricle to the left atria fails, allowing blood into the atria during systole. This means they will be overfilled when they come to contract, leading to the rapid ventricular filling.
  • Elevated left atrial and left ventricular filling pressures, usually a result of a stiffened and dilated left ventricle
  • Ventricular septal defect - this is a hole in the wall between the two ventricles, which allows rapid filling from the other ventricle.
  • Elevated atrial pressure
  • High-output states
  • Poor Left Ventricular Function
  • Post-MI - the death of tissue in the ventricular wall due to loss of blood supply causes areas which do not move as well, if at all (hypokinetic and akinetic), meaning they do not relax quickly enough so the ventricular filling is relatively too quick.
  • Dilated cardiomyopathy - the ventricular walls are abnormal for a variety of reasons, and become thin and stiff so do not relax well.
  • Hypertrophic obstructive cardiomyopathy
  • Cardiomegaly of a variety of causes

In conditions affecting the pericardium or diseases that primarily affect the heart muscle (restrictive cardiomyopathies) a similar sound can be heard, but is usually more high-pitched and is called a 'pericardial knock'.

The S3 can also be confused with a widely split S2, or a mitral opening snap, but these sounds are typically of much higher pitch and occur closer to the onset of S2.

Fourth heart sound S4

S4 (or fourth heart sound) occurs just before S1 (thus right at the end of one whole cycle), giving a cadence like the word 'Tennessee'. It is never normal. If the problem lies with the left ventricle, the gallop rhythm will be heard best at the cardiac apex (the point of the two ventricles). It will become more apparent with exercise, with the patient lying on their left-hand side, or with the patient holding expiration. If the culprit is the right ventricle, the abnormal rhythm will be most evident on the lower left hand side of the sternum, and will get louder with exercise and quick, deep inspiration [2]. The fourth heart sound S4 is sometimes audible in healthy children, but when audible in an adult is called a presystolic gallop or atrial gallop. This gallop is a sign of a pathologic state, usually a failing left ventricle. This sound occurs just after atrial contraction ("atrial kick") and is the sound of blood being forced into a stiff/hypertrophic left ventricle. The combined presence of S3 and S4 is a quadruple gallop. At rapid heart rates, S3 and S4 may merge to produce a summation gallop.

It is caused by the atria contracting forcefully in an effort to overcome an abnormally-stiff ventricle.

Differential Diagnosis of Causes of an S4

The S4 rhythm is associated with disorders that increases the stiffness of the ventricle, including:

Murmurs

It is important to thoroughly evaluate and record the presence of any murmur at baseline so that the development of any new murmur (which may reflect a mechanical complication) can be promptly noted. The intensity of the murmur may vary depending upon the size and compliance of the cardiac chambers involved.[3] [4] [5] [6] [7]

Grading the loudness of a murmur from 1 to 6 is a well described and widely used method [8] Systolic thrills usually are associated with murmurs of grade 4 or louder.

Mitral regurgitation

Mitral regurgitation can develop as a result of either papillary muscle dysfunction or as a result a dilation of the mitral apparatus secondary to left ventricular dilation. [9] [10] [11]

Ventricular septal defect

The development of a ventricular septal defect is associated with a holosystolic murmur and thrill which are most prominent along the left and right sternal border (see complications).

Tricuspid regurgitation

Either right ventricular infarction or rupture of a right ventricular papillary muscle may result in tricuspid regurgitation. This is a systolic murmur that is best heard along the left sternal border. In general, it is intensified by inspiration. Tricuspid regurgitation may be associated with a prominent c-v wave in the jugular venous pulse.

Pericardial friction rubs

A pericardial friction rub is often best heard over the left sternal border, but many also be prominent at the apex of the heart. In general, a rub is heard in both systole and diastole. If it is heard only in systole, it may be mistaken for a systolic murmur. In general a rub is more scratchy and squeaky in nature compared with a murmur, which is more blowing or rumbling in character.

(Images courtesy of Charlie Goldberg, M.D.)

See also

References

  1. 1.0 1.1 S. Garas et al.. Myocardial Infarction. eMedicine. Retrieved November 22, 2006.
  2. Tavel ME. The appearance of gallop rhythm after exercise stress testing. 'Clin Cardiol'. 1996 Nov;19(11):887-91
  3. Cheng, TO. Some new observations on the syndrome of papillary muscle dysfunction. Am J Med 1969; 47:924.
  4. Craige, E. Phonocardiography in interventricular septal defects. Am Heart J 1960; 60:51.
  5. Dock, W, Zoneraich, S. A diastolic murmur arising in a stenosed coronary artery. Am J Med 1967; 42:617.
  6. Mineo, K, Cummings, J, Josephson, R, Nanda, NC. Acquired left ventricular outflow tract obstruction during acute myocardial infarction: diagnosis of a new cardiac murmur. Am J Geriatr Cardiol 2001; 10:283.
  7. Ronan, JA Jr, Steelman, RB, DeLeon, AC Jr, et al. The clinical diagnosis of acute severe mitral insufficiency. Am J Cardiol 1971; 27:284.
  8. Freeman AR, Levine SA. Clinical significance of systolic murmurs: study of 1000 consecutive "noncardiac" cases. Ann Intern Med. 1933, 6: 1371–85.
  9. Birnbaum Y, Chamoun AJ, Conti VR, Uretsky BF. Mitral regurgitation following acute myocardial infarction. Coronary Artery Disease: Volume 13 (6) September 2002 337-344
  10. Bursi F, Enriquez-Sarano M, Jacobsen SJ, Roger VL. Mitral regurgitation after myocardial infarction: a review. Am J Med. 2006 Feb;119(2):103-12. PMID 16443408 Mitral regurgitation generally results in a blowing holosystolic murmur best heard at the apex. If there has been rupture of the head of the papillary muscle, a thrill may be palpated (see complications).
  11. Maisel AS, Gilpin EA, Klein L, Le Winter M, Henning H, Collins D. The murmur of papillary muscle dysfunction in acute myocardial infarction: clinical features and prognostic implications. Am Heart J. 1986 Oct;112(4):705-11

Additional Resources

  • Chizner MA. Cardiac auscultation: Rediscovering the lost art. Curr Probl Cardiol. 2008 Jul; 33(7): 326-408. PMID 18513577

External links

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