Cardiogenic shock medical therapy: Difference between revisions

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: João André Alves Silva, M.D. [2]

Overview

Cardiogenic shock is considered an emergency and irrespectively to the therapeutic approach, the target goal of any therapy is prompt revascularization of ischemic myocardium. This should be achieved in the shortest timespan possible. There are two major categories of treatment for cardiogenic shock, the medical/conservative approach and the interventional approach. The ideal treatment combines both techniques, in which medical therapy, after restored filling pressures, allows hemodynamical stabilization of the patient, until interventional methods, that contribute to the reversal of the process leading to the shock state, may performed. The interventional approach may include PCI or coronary artery bypass graft surgery (CABG) and in both techniques the goal is not only to reestablish perfusion of the occluded coronary artery, but also to prevent vessel reoclusion. If there is no access to a cardiac catheterization facility, nor the possibility of transferring the patient to one within 90 minutes, then immediately thrombolytic therapy should be considered.^[1] Other important factors to increase the chances of a better outcome are: mechanical ventilation, in order to improve tissue oxygenation, and close monitoring of the therapeutic dosages, particularly of vasoactive drugs, since these have been associated with excess mortality due to toxicity effects.^[2][3] Also, it is recommended invasive hemodynamic monitoring, in order to monitor and guide the effects of the therapy as well as the overall status of the patient. The success of reperfusion is usually suggested by the relief of symptoms, restoration of hemodynamic parameters and electrical stability, as well as the reduction of at least 50% in the ST-segment on the EKG, in the case of a STEMI.^[1][4]

Medical Therapy

Cardiogenic shock is a medical emergency, rescusitive measures should be initiated immediately while the underlying etiology of the cardiogenic shock is promptly investigated. Myocardial infarction is the most common cause of cardiogenic shock, and when present, prompt revascularization should be performed. Other causes, such as free wall rupture, acute valvular abnormality, or left ventricular septum rupture, may require more invasive interventions.

Goals of Therapy

Cardiogenic shock is characterized by low cardiac output, high left ventricular filling pressure, and decreased blood pressure with organ hypoperfusion. Goals of therapy:

• Increase coronary blood flow
• Decrease myocardial energy consumption
• Increase systemic blood flow

Management Plan

• Resuscitation and general measures
• Optimization of the blood pressure
  • Pharmacological therapy
  • Mechanical therapy
• Reperfusion or revascularization
• Hemodynamic monitoring and stabilization

Resuscitation and General Measures

Resuscitation measures should be IMMEDIATELY initiated:

• Monitor heart rate
• Monitor blood pressure (sphygmomanometer or arterial line)
• Correct hypoxia and ensure optimal oxygenation and ventilation support (mechanical ventilation is often required in patients with cardiogenic shock to assure adequate oxygenation.)
• Correct electrolytes and acid base abnormalities
• Manage the intravenous volume status
• Pain relief
• Anti-thrombotic therapy among patients with MI: aspirin, heparin, possibly GPIIbIIIa inhibitor
• Check the glucose and administer insulin in case of severe hyperglycemia
• Monitor ECG and restore sinus rhythm

Optimization of the Blood Pressure

The goal of blood pressure optimization are to:

• Improve coronary blood flow
• Improve systemic reperfusion

The first line treatment to increase blood pressure in cardiogenic shock is the administration of pharmacological therapy with either ionotropes or vasopressors,^[5] the main choices being dopamine, dobutamine, and norepinephrine. If pharmacological therapy fails to stabilize the patient's blood pressure, mechanical support must be provided.

Pharmacological Therapy

The appropriate choice of an inotrope or vasopressor requires the assessment of the balance between its desired and undesired effects:

• Desired effects: ↑ cardiac output and ↓ left ventricular pressure
• Undesired effects: ↑ myocardial energy consumption

All inotropes and vasopressors increase myocardial oxygen consumption to a certain extent. However, the benefit of their administration in the setting of a cardiogenic shock is achieved through counteracting the deleterious effects of hypotension. In cardiogenic shock, hypotension decreases myocardial perfusion and leads to compensatory elevation in LV filling pressure which in turn increases myocardial energy consumption. Therefore, the balance between desired and undesired effects of these agents necessitate their administration at the minimum efficacious dose.^[6] There is no robust data that compares the efficacy of inotropes and vasopressors in improvement of cardiovascular outcomes and reduction in mortality.^[7]

The two main agents used to optimize the blood pressure are:

• Dopamine
• Norepinephrine: Norepinephrine is mainly used among patients with severe hypotension.

Alternative agents include dobutamine (mainly in non-sick patients) and phosphodiesterase inhibitors (amrinone or milrinone).

Selection of a Vasopressor or an Inotrope

The choices of pharmacological agents is guided by the blood pressure and clinical status of the patient. There is no clear cut regarding the choice of the agents, combinations of moderate doses of different medications are commonly used instead of the administration of the maximal dose of any individual drug.^[8]

Low Output without Shock

Dobutamine is the treatment of choice among patients with low output and preserved systolic blood pressure.

Low Output with Shock

Systolic blood pressure (SBP) > 70 or 80 mm Hg

Dobutamine is preferred over dopamine when the patient does not have symptoms:

• Usual dose: 2.0–20 μg/kg/min
• Maximum dose: 40 μg/kg/min
• Avoid ↑ HR by >10% of baseline

Dopamine should be administered among symptomatic patients:

• Cardiac dose: 5.0–10 μg/kg/min
• Pressor dose: 10–20 μg/kg/min
• Maximum dose: 20–50 μg/kg/min

Phosphodiesterase inhibitors (PDIs) such as milrinone and inamrinone (formerly known as amrinone) are not dependent upon the adrenoreceptor activity and patients may not develop tolerance, and they may be less likely to increase myocardial oxygen demands and risks of arrhythmia. However, the addition of a vasopressor is often required as these agents reduce preload and afterload. PDIs are more likely to be associated with tachyarrhythmias than dobutamine, significant vasodilation and hypotension.

Systolic blood pressure (SBP) < 70 or 80 mm Hg

Norepinephrine is indicated among patients with severe hypotension:

• Initial dose: 0.5–1.0 μg/min
• Maximum dose: 30–40 μg/min
• Titrate to SBP >90 mm Hg

If norepinephrine does not generate a MAP of 60 mm Hg, then epinephrine can be added. Epinephrine increases both the stroke volume and heart rate, but is associated with lactic acidosis

Mechanism of Action of Ionotropes and Vasopressors

Shown below is a table summarizing the different inotrope or vasopressor agents used in the setting of cardiogenic shock.^[9][6]

Phosphodiesterase inhibitors (milrinone, amrinone)

• Potent ionotrope
• Potent chronotrope
• Vasodilation
• Increase myocardial contractility

Vasopressin:

• Act on V1 (vascular smooth muscle cells) and V2 (renal collecting duct system) receptors
• May cause cardiac ischemia
• Severe peripheral and splanchnic vasoconstriction

Levosimendan:

• Ussed in decompensated heart failure

Mechanical Therapy

Mechanical therapy for cardiac shock involves the use of circulatory assist systems, which are different by:

• Mode of placement: percutaneous vs. surgical
• Mode of circulatory support: LV, RV, or biventricular and/or volume unloading
• Presence or absence of combined extracorporal membrane oxygenation (ECMO)

Intra-aortic Balloon Placement

As per the recommendation of the 2013 AHA/ACC guidelines, in the setting of acute MI complicated by cardiogenic shock refractory to pharmacological therapy, the placement of an intra-aortic balloon pump (IABP) (which reduces workload for the heart, and improves perfusion of the coronary arteries) should be considered.^[10]

The hemodynamic effects of IABP are:

• ↑ stroke volume and cardiac output
• ↑ systemic blood pressure
• ↑ coronary blood flow
• ↓ myocardial oxygen consumption
• ↓ pulmonary capillary wedge pressure

Despite IABP's favorable hemodymaic benefits, the survival benefit associated with the use of IABP is controversial.^[11]/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=41291 }} </ref>

In a meta-analysis of seven randomized trials among 1009 patient, IABP placement in STEMI was not associated with an improvement in mortality or in left ventricular function but was associated with a higher rate of stroke and bleeding. When data from non-randomized cohort studies were evaluated in a meta-analysis (n=10,529 STEMI patients with cardiogenic shock), IABP placement was associated with an 18% relative risk reduction in 30 day mortality among patients treated with a fibrinolytic agent. This particular analysis is confounded by the fact that those patients in whom an IABP was placed underwent adjunctive percutaneous intervention (PCI) more frequently. In this non-randomized cohort analysis, IABP placement in patients undergoing primary angioplasty was associated with a 6% relative increase in mortality (p<0.0008). Thus, neither randomized nor observational data support IABP placement in the setting of primary PCI for cardiogenic shock, and careful consideration should be given to the risk of stroke and bleeding prior to IABP placement in this population.^[12]

Left Ventricular Assist Device Placement

As per the recommendation of the 2013 AHA/ACC guidelines, in the setting of pronounced hypotension despite medical therapy and IABP placement, placement of a left ventricular assist device (which augments the pump-function of the heart) should be considered.^[10] A ventricular assist device should only be placed in those patients in whom the cardiogenic shock is deemed to be reversible or if it is being used as a bridge option. ^[13]

ECMO

Urgent Revascularization

If the patient has an ST elevation myocardial infarction, then primary angioplasty should be considered to restore flow to the culprit artery. Consideration should also be given to restoration of flow in the non-culprit territories in the setting of cardiogenic shock.

Urgent revascularization can be achieved through one of the following:

• Percutaneous coronary intervention (PCI)
• Coronary artery bypass graft (CABG)
• Fibrinolytic therapy

Urgent revascularization is a priority over hemodynamic monitoring in MI patients and should not be delayed. PCI or CABG are indicated among MI patients with cardiogenic shock. When PCI or CABG can not be perfomed, fibrinolytic therapy is indicated in the absence of any contraindications.^{[10][14] [15][16]} Administration of streptokinase therapy to patients with cardiogenic shock has not been associated with an improvement in survival.^[17] Yet, these studies are old and limited by the infrequent use of adjunctive PCI. If a patient is not deemed a candidate for primary angioplasty, then consideration should be given to fibrinolyitc administration. CABG in the setting of cardiogenic shock is associated with high rates of mortality and morbidity, therefore if primary angioplasty can be performed successfully, CABG is preferably avoided.

Hemodynamic Monitoring and Stabilization

Hemodynamic Monitoring

The aims of hemodynamic monitoring are:

• To make sure that a target mean arterial pressure (MAP) of 60 to 65 mmHg is achieved to maintain perfusion to vital organs (brain, kidney, heart)
• To monitor and guide the effects and doses of the ionotrope and vasopressors

The response to the treatment is determined through the assessment of whether the mean arterial pressure reached the target value, an increase in blood pressure, and bed-side clinical assessment by evaluating indices of organ perfusion, such as physical exam, urine output, and lactate levels,

Target endpoints: SaO2 >92% SvO2 >60% ScvO2 >70% Urine output >0.5 mL/kg/h Lactate <2.2 mM/L Hematocrit ≥30%

Preload

Goal: PCWP 15–18 mm Hg, CVP 8–12 cm H2O

• Fluid challenge protocol ("TROL")
• ± Correct pulmonary congestion
  • Furosemide
    • Usual dose: 40 mg slow IV injection
    • May increase dose to 80 mg after 1 hour as needed
  • Morphine
    • Usual dose: 2–4 mg slow IV injection
    • May repeat dose every 5–30 minutes as needed

Afterload

Goal: MAP >65 mm Hg, SVR 800–1200 dyn·s·cm−5

If ↑ MAP & ↑ SVR:

• Taper vasopressor
• ± Vasodilator
  • Nitroglycerin
    • Initial dose: 5.0 μg/min
    • Titrate by 10–20 μg/min q 3–5 min
  • Nitroprusside
    • Initial dose: 0.3 μg/kg/min
    • Usual dose: 3.0–5.0 μg/kg/min
    • Maximum dose: 10 μg/kg/min

If ↓ MAP & ↓ SVR:

• Vasopressor
  • Norepinephrine
    • Initial dose: 0.5–1.0 μg/min
    • Maximum dose: 30–40 μg/min
    • Titrate to SBP >90 mm Hg
  • Dopamine
    • Cardiac dose: 5.0–10 μg/kg/min
    • Pressor dose: 10–20 μg/kg/min
    • Maximum dose: 20–50 μg/kg/min
  • Phenylephrine
    • Initial dose: 100–180 μg/min
    • Maintenance dose: 40–60 μg/min
  • ± Vasopressin
    • Adjunctive therapy to norepinephrine or dopamine
    • Usual dose: 0.01–0.03 U/min
    • Maximum dose: 0.04 U/min

If ↓ MAP & ↑ SVR:

• Continue vasopressor
• Optimize cardiac output with inotropic agent

Cardiac index

Goal: CI >2.2 L/min/m2

• Dobutamine
  • Usual dose: 2.0–20 μg/kg/min
  • Maximum dose: 40 μg/kg/min
  • Avoid ↑ HR by >10% of baseline
• Milrinone
  • Loading dose: 50 μg/kg (slowly over 10 minutes)
  • Maintenance dose: 0.375–0.75 μg/kg/min

Volume Management

The goal of managing the patient with cardiogenic shock is to optimize the filling of the left ventricle so that the Starling relationship and mechanical performance and contractility of the heart is optimized. In the setting of acute MI, a pulmonary capillary wedge pressure of 18 to 20 mm Hg may optimize left ventricular filling. Filling pressures higher than this may lead to LV dilation, and poorer left ventricular function.

Even though, there is adequate intravascular volume in cardiogenic shock, fluid administration should be considered in patients with cardiogenic shock following acute MI because patients are often diaphoretic with subsequent relative hypovolemia.^[18][19]

Contraindicated Medications

Cardiogenic shock is considered an absolute contraindication to the use of the following medications:

• Acebutolol
• Amiodarone
• Atenolol
• Betaxolol
• Bisoprolol
• Brimonidine tartrate and Timolol maleate
• Carvedilol
• Disopyramide
• Esmolol
• Metoprolol
• Mexiletine
• Nadolol
• Nesiritide
• Penbutolol
• Pindolol
• Propafenone
• Propranolol
• Sotalol
• Timolol
• Verapamil
• Labetalol

2013 Revised ACCF/AHA Guidelines for the Management of ST-Elevation Myocardial Infarction (DO NOT EDIT)^[10]

General and Specific Considerations (DO NOT EDIT)^[10][20]

Treatment of Cardiogenic Shock in Patients with STEMI (DO NOT EDIT)^[10]

References

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