Lec 23- inotropes

Question 1

Inotropes

Answer 1

• Increase cardiac force
• Inotropes are used to support failing heart
• The heart may fail in several circumstances and a variety of drugs may be used to support it
• HR is effected by chronotropes

Question 2

HF

Answer 2

• HF is condition that develops when the hears muscle becomes weakened after injury
• This can be from high BP, and loses its ability to pump sufficient blood to supply the bodies needs
• On a frank-starling curve a failing heart will see decreased CO and more EDV

Question 3

HF risk factors

Answer 3

• AMI
• High BP
• High ChE
• Damage to heart valves
• Diabetes
• Obesity

Question 4

Mechanism responsible for HF

Answer 4

• Decreased energy production
• Increased energy utilisation
• Abnormal Ca homeostasis
• Altered gene expression

Question 5

Compensatory mechanisms in HF

Answer 5

A) Frank-Starling
B) Neuroendocrine response: increase sympathetic output; increased RAAS activity; increased ADH (vasopressin)
C) Myocardial hypertrophy

Question 6

Inotropes can be divided into the following classes

Answer 6

• Cardiac glycosides: digoxin
• Catecholamines: NA and adrenaline
• Phosphodiesterase inhibitors- sildenafil
• Calcium entry promoters- : opposite of CCB. Act on nitrendipine receptors
• Ca
• Ca sensitisers- increase affinity of troponin for calcium (depressed by hypoxia and acidosis). Potential future development (potential advantage that they wouldn’t increase myoplasmic Ca, therefore pherhaps less problems with arrhythmias)

Question 7

Factors involved in cardiac contraction

Answer 7

• AP OR
• NA acts on B1-adrenoceptors (dobutamine act on these) resulting in phosphorylation (PKA pathway) of Ca2+ channels which increases opening times
• 1) Depolarisation allows Ca2+ influx through voltage gated Ca2+ channels
• 2) Ca2+ release from sarcoplasmic reticulum (SR) increases Ca2+ still further
  3) Ca2+ plus troponin= contraction

Question 8

Mechanism for decrease of Ca2+

Answer 8

1) Ca2+ is extruded in exchange for Na by Ca2+ exchanger (CE)
2) Na+ is exchanged with K+ by the Na/K/ATPase (Na pump;SP)
- Cardiac glycosides inhibit the Na pump leading to: slow removal of Ca2+ so increasing concentration –> increasing force of contraction

Question 9

Muscle cell: cardiac or vascular

Answer 9

• AP
• Open Ca channels
• Influx of Ca2+
• These act on SR channels
• This causes further release of Ca2+

Question 10

Inotrope action

Answer 10

• Inotrope action involves Ca2+ handling in the cardiac myocyte
• Rationale is to increase Ca2+ available of contractile proteins
• This is done by: increase Ca2+ influx; Decreasing Ca2+ efflux

Question 11

Increasing Ca2+ influx

Answer 11

• B-adrenergic activation- dobutamine

- Phosphodiesterase inhibition- sildenafil

Question 12

B-Aadrenergic activation

Answer 12

• Activation of B1 receptors, leads via adenylate cyclase which turns ATP to cAMP. cAMP activates Protein Kinase A (PKA)
• PKA phosphorylates L-type Ca2+ channels, which favours mode 2 gating (Opens them, also opens them for longer)
• Amount of Ca2+ entry during depolarisation is therefore increased
• Increased Ca2+ also means that more is stored in the sarcoplasmic reticulum for subsequent release
• Post synaptic B1-receptors are predominant adrenergic receptors in the heart
• Stimulation causes increased rate and force of cardiac contraction. mediated by cAMP

Question 13

3 modes of Ca2+ channel opening

Answer 13

-Mode 0
opening probability is 0 
Favoured by DHP antagonists 
% of time spent like this=<1%
-Mode 1
Opening probability is low 
%of time spent like this=70%
-Mode 2- This is the mode when opened by B-agonist 
Opening probability is high 
Favoured by DHP agonists 
%of time spent like this=30%
-Weather or not a channel is open affects the binding of the drug

Question 14

In addition to causing increased Ca2+ entry

Answer 14

• B1 adrenoceptors activation also leads to an increase of the sensitivity of the contractile machinery, probably via troponin C phosphorylation
• There is also more cytosolic Ca2+ for uptake into the SR, so that there is more Ca2+ for release during the AP
• Net result is to elevate and steepen the ventricular function curve

Question 15

B-receptors

Answer 15

• Post synaptic B1 receptors are predominant adrenergic receptors in heart
• Stimulation causes increased rate and force of cardiac contraction
• Mediated by cAMP
• Post synaptic B2-receptors in vasculature mediate vasodilation

Question 16

a1-receptors

Answer 16

• Post synaptic cardiac a1 receptors:
• Stimulation cause ssignificant increase in contractility without an increase in rate
• Mediated by IP3- Ca2+ release
• Effect more pronounced at low HR
• Slower onset and longer duration than B1-receptors mediated response

Question 17

Dobutamine

Answer 17

• B1 agonist
• IV continuous infusion in acute severe HF; infarction; cardiac surgery; cardiomyopathy; septic shock; cariogenic shock and during positive expiratory pressure ventilation

Question 18

Adrenaline/Epinephrine

Answer 18

• Agonist at a and B receptors, net effect is Inotropic

- Iv continuous infusion I cardiopulmonary resuscitation; anaphylaxis; acute hypotension

Question 19

Phosphodiesterase inhibitors

Answer 19

• In cardiac muscle PDEIII catalyses breakdown of cAMP
• Inhibiting PDE III leads to increased levels of cAMP
• Increased activation of PKA
• Increased phosphorylation of L-type Ca2+ channels leads to more Ca2+ entry on depolarisation and so underlies the Inotropic effect

Question 20

Phosphodiesterase inhibitors 2

Answer 20

-increased Ca2+ influx increases rate and force of myocardial contraction
-cAMP also affects diastolic heart function through enhanced Ca re-sequestration rate and hence improves diastolic relaxation
-Synergistic with beta agonists
-Also relax vascular smooth muscle resulting in vasodilation
-Myocardial O2 consumption and HR are not significantly increased
-Tolerance is not a feature
NB different variants of PDE

Question 21

Enoximone and milrinoe

Answer 21

• USE: management of decompensated CHF
• Ademonstration: IV; (ITU or CCU)
• Monitoring: BP; ECG: platelets; K+; CVP
• Adverse effects: arrhythmias; hypersensitivity; hypotension

Question 22

Decreasing Ca2+ efflux

Answer 22

• Na/K/ATPase inhibition
• Ca2+ is extruded in exchange for Na by the Na/Ca2+ exchanger
• Depends on Na gradient; Na is maintained low internally by Na/K/ATPase pump
• By maintaining high conc of Na inside the cell this means that the Na/Ca exchanger can’t work as effectively which means that Ca2+ stays inside the cell for longer

Question 23

Cardiac glycosides

Answer 23

• Inhibit Na/K/ATPase
• Digoxin from digitalis purpurea (foxglove)
• Na gradient is maintained bt ATPase pump
• Na gradient drives Ca/Na
• Reduced Na gradient slows Ca removal (by inhibition of ATPase)
• NB due to the fact that we can’t pump out Ca2+ it is stored in sarcoplasmic reticulum

Question 24

Digoxin mechanism

Answer 24

-Inhibits Na/K/ATPase and produces subtle changes in resting electrolyte status
-Increase [Na]i
Increased [Na]I reduces driving force for Ca efflux and thereby increased Ca2+ loading in the SR (positive inotropic effect)
-Decreases [K]i
-Lowers resting membrane potential (i.e. more +ve), makes them more excitable and more likely to depolarise

Question 25

Digoxin

Answer 25

• Increases contractility: positive inotrope; used for HF treatment
• Decreased HR: Negative chronotrope; Used to control HR in AF
• Monitoring; ECG: pulse; renal function; K; symptoms of toxicity; TDM

Question 26

Parasympathetic effects of cardiac glycosides

Answer 26

• Reduces HR
• Acts on Vagus nerve; the lowering of the resting membrane potential means the nerve is more excitable
• Therefore release more ACh (inhibitory effect)
• This acts on the SAN causing heart rate to slow down

Question 27

Frank starling curve- failing heart

Answer 27

• A failing heart is unable to pump enough blood to meet the bodies demands
• Due to decrease in the contractility of the left ventricle heart mule
• Seen in the frank starling curve as a decrease in CO relative to ventricular filling