Pulse - PowerPoint PPT Presentation

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Pulse

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Pulse The pulse has been studied for centuries. Information gained: Frequency, regularity Patency of peripheral arteries Characteristics of the arterial pressure ... – PowerPoint PPT presentation

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Title: Pulse


1
Pulse
2
The pulse has been studied for centuries.
  • Information gained
  • Frequency, regularity
  • Patency of peripheral arteries
  • Characteristics of the arterial pressure pulse
    wave
  • The arterial pulse contour changes to the
    periphery
  • Resistance viscosity, vessel geometry opposes
    flow HR independent
  • Inertia mass opposes rate of change of flow, HR
    dependent
  • Compliance distensibility opposes changes of
    blood volume, HR-dependent

3
Location of Pulses
  • Carotid similar to central aortic pulse (delay
    of 20msec)
  • Radial used to assess the volume and
    consistency of the peripheral vessels.
  • Brachial
  • Femoral
  • Posterior tibial
  • Dorsalis pedis
  • Look for any differences in the pulse amplitude,
    contour, or upstroke.

4
Factors Influencing the Pulse
  • Stroke volume
  • Rate of ejection
  • Distensibility of peripheral arteries
  • Peripheral resistance
  • Pulse rate
  • Pulse pressure
  • Size of the vessel
  • Distance from the heart

5
Normal Pulse (1/2)
  • The normal central aortic pulse wave is
    characterized by a fairly rapid rise to a
    somewhat rounded peak.
  • The anacrotic shoulder, present on the ascending
    limb, occurs at the time of peak rate of aortic
    flow just before maximum pressure is reached.
  • The less steep descending limb is interrupted by
    a sharp downward deflection, coincident with AV
    closure, called incisura.
  • The pulse pressure is about 30-40 mmHg.

6
Normal Pulse (2/2)
  • As the pulse wave is transmitted peripherally,
    the initial upstrokes becomes steeper, the
    anacrotic shoulder becomes less apparent, and the
    incisura is replaced by the smoother dicrotic
    notch.

7
Abnormal Pulses
  • Inequality in the amplitude of the peripheral
    pulses
  • Obstructive arterial diseases , most commonly
    artherosclerosis
  • Aortic dissection
  • Aortic aneurysm
  • Takayasu arteritis (pulseless disease)
  • Supravalvular aortic stenosis (fixed form of LVOT
    caused by narrowing of ascending aorta)

8
Pulsus Parvus
  • The pressure is diminished, and the pulse feels
    weak and small, reflecting decreased stroke
    volume (e.g. heart failure), restrictive
    pericardial disease, hypovolemia, mitral
    stenosis, and increased peripheral resistance
    (e.g. exposure to cold, severe CHF).
  • Pulsus Parvus et Tardus (weak and delayed)
    ?Aortic Stenosis

9
Aortic Stenosis (1/2)
  • LVOT obstruction
  • Reduces SV, prolongs LV total ejection time, and
    retards the rate of initial stroke output into
    the aorta and distal arterial system.
  • Anacrotic character (anacrotic pulse)
  • Interruption of the upstroke of the carotid
    pulse. AS is likely to be hemodynamically
    significant when the anacrotic notch is felt
    immediately after the onset of the upstroke.

10
Aortic Stenosis (2/2)
  • Delayed upstroke of the ascending limb (pulsus
    tardus)
  • Prolonged LV ejection time.
  • Appreciated by simultaneous palpation of carotid
    pulse and auscultation fo the interval between S1
    and S2.
  • Normally the carotid pulse occurs closer to S1
    in severe AS closer to S2.
  • Thrill (carotid shudder)

11
Bisferiens Pulse
  • Increased arterial pulse with a double systolic
    peak.
  • Second peak, the tidal wave, presumed to
    represent a reflected wave from the periphery.
  • Causes hemodynamically significant AR
  • HCM rarely palpable rapid LV ejection during
    early systole, rapid decline due to LVOT
    obstruction, and tidal wave from periphery.

12
Bigeminal Pulse
  • Normal beat alternating with a premature
    contraction.
  • SV of the premature beat diminished, and pulse
    varies in amplitude accordingly.
  • May masquerade as pulsus alternans
  • Causes decreased BP (e.g. severe HF, hypovolemic
    shock, cardiac tamponade) and peripheral
    resistance (e.g. fever), s/p aortic valve
    replacement.
  • Present in normal individuals after exercise.

13
Pulsus Alternans (1/2)
  • Variation in pulse amplitude occurring with
    alternate beats due to changing systolic
    pressure.
  • When the cuff pressure is slowly released while
    taking BP, phase I Korotkoff sounds are initially
    heard only during the alternate strong beats
    with further release of cuff pressure, the softer
    sounds of the weak beat also appear.
  • Degree of pulsus alternans can be quantitated by
    measuring the pressure difference between the
    strong and the weak beat.

14
Pulsus Alternans (2/2)
  • Causes
  • Left ventricular failure usually accompanied by
    a left-sided S3.
  • May be seen in patients with severe AR
  • Frequently precipitated by ectopic beats
    (bigeminal pulse)
  • Mechanisms
  • Alternating preload and afterload, incomplete
    relaxation,
  • Change in ventricular contractility, causing
    changes in end-diastolic volume and pressure.

15
Pulsus Paradoxus (1/2)
  • Pressure drop gt 20 mmHg during inspiration.
  • Normally, systolic arterial pressure falls 8-12
    mmHg during inspiration.
  • Evaluated with sphygmomanometer
  • when the cuff is slowly released the systolic
    pressure at expiration is first noted. With
    further slow deflation of the cuff, the systolic
    pressure during inspiration can also be detected.

16
Pulsus Paradoxus (2/2)
  • Causes
  • Cardiac Tamponade
  • COPD, hypervolemic shock
  • infrequently in constrictive pericarditis and
    rescrictive cardiomyopathy.
  • Mechanism
  • Decreased LV-SV due to an increased RV-EDV and
    decreased LV-EDV during inspiration.
  • In cardiac tamponade, the interventricular septum
    shifts toward the LV cavity during inspiration
    (reverse Bernheims effect) b/c of increased
    venous return to RV, decreasing the LV preload.
  • Decrease in pulmonary venous return to the LV
    during inspiration also contributes to decreased
    LV preload.

17
Bounding Pulses (1/2)
  • A.K.A. water-hammer pulse or the Corrigan pulse.
  • Most commonly in chronic, hemodynamically
    significant AR.
  • Seen in many conditions associated with increased
    stroke volume PDA, large arteriovenous fistula,
    hyperkinetic states, thyrotoxicosis anemia, and
    extreme bradycardia.
  • Not seen in acute AR, since SV may not have
    increased appreciably.

18
Bounding Pulses (2/2)
  • Physical signs of aortic insufficiency are
    related to the high pulse pressure and the rapid
    decrease in blood pressure during diastole due to
    the AI
  • Lighthouse sign (blanching flushing of
    forehead)
  • de Musset's sign (head nodding in time with the
    heart beat)
  • Ladolfi's sign (alternating constriction
    dilatation of pupil)
  • Becker's sign (pulsations of retinal vessels)
  • Müller's sign (pulsations of uvula)
  • Corrigan's pulse (rapid upstroke and collapse of
    the carotid artery pulse)
  • (Watson's) Water-hammer pulse
  • Quincke's sign (pulsation of the capillary bed in
    the nail)
  • Mayen's sign (diastolic drop of BPgt15 mm Hg with
    arm raised)
  • Rosenbach's sign (pulsatile liver)
  • Gerhardt's sign (enlarged spleen)
  • Duroziez's sign (systolic and diastolic murmurs
    heard over the femoral artery when it is
    gradually compressed)
  • Hill's sign (A 20 mmHg difference in popliteal
    and brachial systolic cuff pressures, seen in
    chronic severe AI)
  • Traube's sign (a double sound heard over the
    femoral artery when it is compressed distally)
  • Lincoln sign (pulsatile popliteal)
  • Sherman sign (dorsalis pedis pulse is quickly
    located unexpectedly prominent in agegt75 yr)
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