1. Intensive Care�Cardiovascular Pharmacology Toni Petrillo-Albarano, MD
Director, Pediatric Transport
Division of Critical Care Medicine
2. The “nervous system” is divided into the peripheral and central systems.
Our discussion begins by directing our attention to the peripheral nervous system which is divided into the:
autonomic system which controls cardiac and smooth muscle contraction and glandular secretion
and
somatic system supplying skeletal muscle and conducting sensory information such as pain and touch.
The autonomic system is then further divided into the sympathetic system which is generally catabolic expending energy and the parasympathetic which is anabolic which conserves energy.The “nervous system” is divided into the peripheral and central systems.
Our discussion begins by directing our attention to the peripheral nervous system which is divided into the:
autonomic system which controls cardiac and smooth muscle contraction and glandular secretion
and
somatic system supplying skeletal muscle and conducting sensory information such as pain and touch.
The autonomic system is then further divided into the sympathetic system which is generally catabolic expending energy and the parasympathetic which is anabolic which conserves energy.
3. Cardiovascular Pharmacology�Terminology Review Catecholamines
Naturally occurring, biologically active amines
Sympathomimetic
Mimics stimulation of the sympathetic nervous system Catecholamines transmit most impulses to the sympathetic system
Examples are norepinephrine and epinephrine which diffuse across the synaptic cleft and bind to post synaptic adrenergic receptorsCatecholamines transmit most impulses to the sympathetic system
Examples are norepinephrine and epinephrine which diffuse across the synaptic cleft and bind to post synaptic adrenergic receptors
4. Cardiovascular Pharmacology�Terminology Review Adrenergic
Refers to the sympathetic nervous system
Cholinergic
Refers to the parasympathetic nervous system
Dopaminergic
Dopamine receptors in renal, visceral, coronary, and cerebral areas Acetylcholine, hence cholinergic, transmits all parasympathetic signals to end organs (heart lungs etc)
Adrenergic or adrenoreceptors are broken down into 2 subtypes
alpha receptors and beta receptorsAcetylcholine, hence cholinergic, transmits all parasympathetic signals to end organs (heart lungs etc)
Adrenergic or adrenoreceptors are broken down into 2 subtypes
alpha receptors and beta receptors
5. Cardiovascular Pharmacology�Terminology Review Inotropic
Influencing the force of contraction
Chronotropic
Influencing the rate of contraction
6. Cardiovascular Pharmacology�Adrenoreceptors Six receptor subtypes:
alpha 1 (post-synaptic)
alpha 2 (pre-synaptic)
beta 1 (cardiac)
beta 2 (vascular/bronchial smooth muscle)
DA 1 (post-synaptic)
DA 2 (pre-synaptic) Alpha receptors are located on
vascular smooth muscle
presynaptic nerve terminals
blood platelets
fat cells
brain cells
two major types alpha 1 and alpha 2
Beta receptors are located on
smooth muscle
cardiac muscle
some presynaptic nerve terminals
lipocytes
brain
Dopaminergic receptors especially important in
- renal
- splanchnic
- brainAlpha receptors are located on
vascular smooth muscle
presynaptic nerve terminals
blood platelets
fat cells
brain cells
two major types alpha 1 and alpha 2
Beta receptors are located on
smooth muscle
cardiac muscle
some presynaptic nerve terminals
lipocytes
brain
Dopaminergic receptors especially important in
- renal
- splanchnic
- brain
7. Cardiovascular Pharmacology�Adrenoreceptors ALPHA 1:
Vasoconstriction
Mydriasis
Uterine contraction
Bladder contraction
Insulin inhibition
Glucagon inhibition ALPHA 2:
Inhibition of norepinephrine release
8. Cardiovascular Pharmacology�Adrenoreceptors BETA 1:
Inotropy
Chronotropy
Lipolysis BETA 2:
Vasodilation
Bronchodilation
Uterine relaxation
Bladder relaxation
Insulin release
Glucagon release
9. Cardiovascular Pharmacology�Adrenoreceptors Desensitization:
2o to Chronic exposure
Mechanisms
Uncoupling
Down-regulation
Sequestration Uncoupling of the receptor from the G protein prevents signal transduction
Downregulation: reduction in total number or density of beta receptors by increased receptor destruction or decreased receptor synthesis or both
Sequestration involves the internalization of the receptor from the cell surface. Takes place over minutes to hours. in contrast to downregulation this permits recycling of the receptor back to the surface once beta exposure ceases. Steroid affect this by upregulation.Uncoupling of the receptor from the G protein prevents signal transduction
Downregulation: reduction in total number or density of beta receptors by increased receptor destruction or decreased receptor synthesis or both
Sequestration involves the internalization of the receptor from the cell surface. Takes place over minutes to hours. in contrast to downregulation this permits recycling of the receptor back to the surface once beta exposure ceases. Steroid affect this by upregulation.
11. Cardiac Output C.O.=Heart Rate x Stroke Volume
Heart rate
Stroke volume:
Preload- volume of blood in ventricle
Afterload- resistance to contraction
Contractility- force applied
12. In order to understand the indications and effects of CV drugs that moderate volume, flow and pressure to ultimately improve O2 delivery we must understand the interactions that occur in the cardiovascular system.
When one can identify the physiologic derangement treatment can be tailored to address the specific problem.
Before reviewing individual drugs we will review the normal physiology and interactions of the CV system to maintain systemic O2 deliveryIn order to understand the indications and effects of CV drugs that moderate volume, flow and pressure to ultimately improve O2 delivery we must understand the interactions that occur in the cardiovascular system.
When one can identify the physiologic derangement treatment can be tailored to address the specific problem.
Before reviewing individual drugs we will review the normal physiology and interactions of the CV system to maintain systemic O2 delivery
13. Inadequate tissue perfusion to meet the tissue demands
a result of inadequate blood flow and/or inadequate oxygen delivery. Shock is defined as a state of circulation characterized by inadequate tissue perfusion and oxygen delivery. Although inadequate BP is used as a criteria for shock, inadequate regional perfusion may occur in the absence of a normal arterial BP
- insert PALS graphShock is defined as a state of circulation characterized by inadequate tissue perfusion and oxygen delivery. Although inadequate BP is used as a criteria for shock, inadequate regional perfusion may occur in the absence of a normal arterial BP
- insert PALS graph
14. Mechanical Requirements for Adequate Tissue Perfusion Fluid
Pump
Vessels
Flow
15. Physiology of Shock Shock may be classified based on hemodynamic mechanismsShock may be classified based on hemodynamic mechanisms
16. Hypovolemic Shock: Inadequate Fluid Volume (decreased preload)
Fluid depletion
internal
external
Hemorrhage
internal
external
17. Cardiogenic Shock: Pump Malfunction (decreased contractility)
Electrical Failure
Mechanical Failure
cardiomyopathy
metabolic
anatomic
hypoxia/ischemia
18. Distributive Shock Abnormal Vessel Tone (decreased afterload)
Sepsis
Anaphylaxis
Neurogenesis (spinal)
Drug intoxication (TCA, calcium channel blocker)
19. OBSTRUCTIVE SHOCK OBSTRUCTED FLOW
Pericardial tamponade
Pulmonary embolism
Pulmonary hypertension
20. Hemodynamic Assessment of Shock
21. Alpha-Beta Meter
22. Cardiovascular Pharmacology�Dopamine Usage:
activates multiple receptors
DA1, DA2, beta, alpha
receptors activated in dose related manner
shown to increase at low doses:
glomerular filtration rate
renal plasma flow
urinary Na+ excretion Dopamine is an intermediary product in the enzymatic pathway leading to the production of norepinephrine and ultimately epinephrineDopamine is an intermediary product in the enzymatic pathway leading to the production of norepinephrine and ultimately epinephrine
23. Cardiovascular Pharmacology�Dopamine Pharmacodynamics:
0.5 - 2.0 mcg/kg/min - dopaminergic
2.0 - 5.0 mcg/kg/min - beta 1
5.0 - 20 mcg/kg/min - alpha Little of any CV improvement with lower doses of dopamine but CI rises once dopamine infusion rates exceed 5 ?g/kg/min
Tachycardia contributes to increased CI at infusion rates of 7.5 ?g/kg/min
High dose dopamine elevates systemic arterial pressure in preterm infants with shock
- achieved by increase SVR and increase HR
LV contractility falls with the cause of this reduced inotropic response related to decreased norepinephrine storesLittle of any CV improvement with lower doses of dopamine but CI rises once dopamine infusion rates exceed 5 ?g/kg/min
Tachycardia contributes to increased CI at infusion rates of 7.5 ?g/kg/min
High dose dopamine elevates systemic arterial pressure in preterm infants with shock
- achieved by increase SVR and increase HR
LV contractility falls with the cause of this reduced inotropic response related to decreased norepinephrine stores
24. Cardiovascular Pharmacology�Dopamine Indications:
Low cardiac output
Hypotension with SVR
Risk of renal ischemia
25. Renal Dose Dopamine (RDD)�Fact or Fiction?�Summary of the Data In healthy humans and animal models, RDD augments:
RBF, GFR, and natriuresis
In experimental models of ischemia and nephrotoxic ARF, RDD augments:
RBF, GFR, and natriuresis
26. Renal Dose Dopamine (RDD)�Fact or Fiction?�Summary of the Data Most human studies failed to demonstrate:
RDD prevents ARF in high risk patients
improves renal function or effects outcome in established ARF
The “dark side”
cardiovascular and metabolic complications Show side effect slide - as with everything we do there are positive and negative effectsShow side effect slide - as with everything we do there are positive and negative effects
27. Cardiovascular Pharmacology�Dopamine Complications:
activity with NE depletion
PA pressure
pulmonary vascular resistance
Dysrhythmias
Renal vasoconstriction
Tissue necrosis
Dopamine activity can be decrease by as much as 50% when Ne stores are lacking. Ie Chronic CHF, immaturity
Dark side complications
CV
- tachyarrythmias
- increase R&R ventricular afterload
- increased intrapulmonary shunting and worsening hypoxemia
metabolic
increase natriuresis at expense of tubular cell ischemia by blunting tubular glomerular filtration rate which protects tubular cells against ischemia.Dopamine activity can be decrease by as much as 50% when Ne stores are lacking. Ie Chronic CHF, immaturity
Dark side complications
CV
- tachyarrythmias
- increase R&R ventricular afterload
- increased intrapulmonary shunting and worsening hypoxemia
metabolic
increase natriuresis at expense of tubular cell ischemia by blunting tubular glomerular filtration rate which protects tubular cells against ischemia.
28. Is Dopamine the Devil? Dopamine administration can reduce the release of a number of hormones from the anterior pituitary gland, including prolactin which can have important immunoprotective effects
Dopamine administration was associated with ICU and hospital mortality rates 20% higher than in patients with shock who did not receive dopamine
29. Cardiovascular Pharmacology�Dobutamine Synthetic catecholamine
Direct beta1 weak alpha
Indications:
Low cardiac output in patients at risk for:
Myocardial ischemia
Pulmonary hypertension
LV dysfunction (cardiomyopathy) Modified from isoproterenol
More direct B1 agonist than isoproterenol which is non selective
Actually has weak alpha1 agonism which can be unmasked by B blockade and manifest as severe HTN
Strong inotropy weak vasodilator
Dilates coronariesModified from isoproterenol
More direct B1 agonist than isoproterenol which is non selective
Actually has weak alpha1 agonism which can be unmasked by B blockade and manifest as severe HTN
Strong inotropy weak vasodilator
Dilates coronaries
30. Dobutamine �Pharmacodynamics
31. Isoproterenol (Isuprel) Major indication
bradycardia
Pure beta
Potent pulmonary/ bronchial vasodilator
Increased cardiac output
Widened pulse pressure
Increased flow to non-critical tissue beds (skeletal muscle)
32. Isoproterenol (Isuprel) �Drawbacks Tachycardia
Dysrhythmias
Peripheral vasodilation
Increased myocardial consumption
CPK indicating myocardial necrosis
Decreased coronary O2 delivery
“Splanchnic steal” by skeletal muscle
33. Epinephrine �Indications Pressor of choice post-arrest
Shock
with bradycardia
unresponsiveness to other vasopressors
anaphylaxis
Low cardiac output syndrome
34. Epinephrine �Pharmacokinetics Limited data available in children
Plasma concentration varies linearly with infusion rate
Clearance
15.6-79.2 m/kg/min
35. Epinephrine �Effects Most potent catecholamine
Direct acting
no catecholamine stores needed
Prominent alpha and beta effects
Increased diastolic pressures
36. Epinephrine �Pharmacodynamics
37. Epinephrine Complications
Renal ischemia
Dysrhythmias
Severe hypertension
Myocardial necrosis
Hyperglycemia
Hypokalemia
38. Norepinephrine��Levophed�
39. Norepinephrine (Levophed) �Indications Indications
Sepsis with vasodilation unresponsive to volume expansion
Hypotension unresponsive to therapy
Dose:
0.05 - 1 mcg/kg/min
t 1/2 = 2 - 2.5 min
40. Norepinephrine (Levophed)� Effects Potent peripheral alpha agonist
Little beta 1 effects
Minimal to no beta 2
Produces
vasoconstriction
SVR, PVR
increases systolic, MAP, diastolic BP Increased SVR may or may not alter CO depending on how much you increase the afterload. a little may improve CO too much may decrease COIncreased SVR may or may not alter CO depending on how much you increase the afterload. a little may improve CO too much may decrease CO
41. Norepinephrine (Levophed) �Complications Renal vasoconstriction
may be decreased with dopamine
Possible cardiac function due to increased afterload
Dysrhythmias
Tissue necrosis 2 studies show benefit
Martin et al CCM
24 patients with septic shock
NE and titrated to maintain Nl SBP
20/24 pt return urine flow, decreased serum creatinine, increased creatinine clearance
none got low dose dopa or lasix
4 patients remained oliguric
2/4 died 2/4 renal failure
Hoogenburg et al
low dose dopa + increasing doses norepi in healthy volunteers
norepi caused decreased renal plasma flow but not GFR
norepi + dopa prevented decreased renal plasma flow, increased sodium excretion attenuated HTN and renal vasoconstriction
results of study sufficiently strong to recommend low dose dopamine in all critically ill patients requiring norepi.2 studies show benefit
Martin et al CCM
24 patients with septic shock
NE and titrated to maintain Nl SBP
20/24 pt return urine flow, decreased serum creatinine, increased creatinine clearance
none got low dose dopa or lasix
4 patients remained oliguric
2/4 died 2/4 renal failure
Hoogenburg et al
low dose dopa + increasing doses norepi in healthy volunteers
norepi caused decreased renal plasma flow but not GFR
norepi + dopa prevented decreased renal plasma flow, increased sodium excretion attenuated HTN and renal vasoconstriction
results of study sufficiently strong to recommend low dose dopamine in all critically ill patients requiring norepi.
42. Milrinone (Primacor) Mechanism of action
Phosphodiesterase III inhibitor
Pharmacodynamics:
Almost pure inotrope
CI
Potent vasodilator
SVR
PVR
Bolus: 50 mcg/kg
Infusion: 0.375 - 0.75 mcg/kg/min
43. Milrinone (Primacor) Pharmacokinetics:
t 1/2 = 90 min
Side effects:
Hypotension
Thrombocytopenia
Advantages:
No precipitation
Short t 1/2
44. Vasopressin ADH Analog
Increases cyclic adenosine monophosphate (cAMP) which increases water permeability at the renal tubule resulting in decreased urine volume and increased osmolality
direct vasoconstrictor (primarily of capillaries and small arterioles) through the V1 vascular receptors
directly stimulates receptors in pituitary gland resulting in increased ACTH production; may restore catecholamine sensitivity
45. Vasopressin Vasodilatory shock with hypotension unresponsive to fluid resuscitation and exogenous catecholamines
0.0003-0.002 units/kg/minute (0.018-0.12 units/kg/hour); titrate to effect
