2. Coronary hyperaemia: The life thread
1. Coronary blood flow can increase up to 5 times the basal flow to
meet increased demand
2. Increase in blood flow is referred to as a hyperemia
3. Observed in response to ischemia and exercise
4. Quantifying the hyperemic response is a critical step in
understanding the coronary circulation and is applied in most
physiological assessments of myocardial blood flow
5. Stood the test of time
1. Coronary vasodilator for microcirculation hyperaemia FFR is really
only used for intermediate stenosis (40% to 70%)
2. Popular SVT Rx
8. 2 Ways to increase extracellular level
1. Inhibiting adenosine kinase during ischemia because ATP depletion
2. Inhibiting adenosine deaminase by dipyradamole
9. Within, across and out
1. In the intracellular space, adenosine can be synthesized de novo
during purine biosynthesis or accumulate as a result of ATP
breakdown. Intracellular adenosine concentrations increase when
there is a mismatch between ATP synthesis and use as in ischemia
or hypoxia
2. Not freely pass across the cell membrane and requires the use of
nucleoside transporters to facilitate the process.
3. Extracellular adenosine arises from active transport of intracellular
stores or from breakdown of adenine nucleotides outside the cell
10. Cell surface G-receptors
A1 A2 A3
A B
Gi protein–bound A1 receptors
reduces adenyl cyclase activity
and decreases intracellular
cAMP Adenosine
Highest affinity for the A1 and
A2a receptors
Mostly neural transmittor
regulation in heart and other
Gs protein–bound increases
adenyl cyclase activity and
cAMP levels
Vasodilation of most vascular
beds including the coronary
circulation
Produces vasoconstriction in
renal afferent arterioles and
hepatic veins
Activation of the Gi protein–bound
A3 receptors reduces adenyl
cyclase activity and decreases
intracellular cAMP
11. Difference
A1 Receptor A2-A and -B A3
1. Generally have an inhibitory
function
2. Negative inotropic
3. Negative Chronotropic
4. Negative Dromotropic
5. Inhibition of atrioventricular
(AV) node conduction and
prolongation of the refractory
period via inhibition of cAMP-
mediated calcium influx and
enhances potassium
conduction
A2A
1. Coronary artery
vasodilator
2. Anti-inflammatory effects
3. A major target of caffeine
A2B receptors
1. Mast cells and are thought
to produce mast cell
degranulation and
bronchial constriction
A3
1. Peripherally located but
are thought to play a role
in mediating pre-
conditioning
13. 3-compartment model
R1 R2 R3
The large epicardial vessels (0.5- to
5.0-mm diameter) make up the first
compartment
Small coronary arteries/pre-
arterioles (100- to 500-mm
diameter)
Arterioles (<100-mm diameter)
branch into intramyocardial
capillaries to create the third
compartment
14. Dynamic ceilling
1. 60% of resistance is provided at the arteriolar level,
2. 25% at the capillary level
3. 15% in the venular compartment
4. During hyperaemia, total resistance decreases across the coronary
circulation by 70%
5. In the arteriolar and venular compartments, resistance decreases
by 86% and 98%, respectively, resulting in minimal alteration of
capillary hydrostatic pressure such that the capillaries offer the
most resistance to coronary blood flow at hyperaemia
6. Capillaries provide the ceiling for the hyperaemic response
15. Different vasodilator
Adenosine Nitroglycerine
Adenosine exerts its predominant vasodilatory effect
on coronary microvessels <150 mm in diameter .
Whether this is an endothelium-dependent process is
unclear. An intact endothelium is not necessary for an
adenosine response in vitro . However, work
performed in humans in vivo has demonstrated that
the vasodilator effect of adenosine in the forearm can
be inhibited by a nitric oxide synthase inhibitor .
Endothelium dependent
16. 2 Methods of Administration
Intravenous Intra coronary
1. Femoral/brachial
2. Sustained
3. Dose is 140-mg/kg/min infusion
4. Greater efficacy for achieving maximal hyperemia
compared with the conventional IC dosing
5. Added advantage that FFRpullback and
more complex physiological assessments can be
made
1. Its peak effect occurs <10 s
2. Duration of effect is 20 sec
3. Current recommendations for IC
adenosine dosing are 40 mg in the right coronary
artery and 60 mg in the left coronary artery, increasing
the doses incrementally by 30 mg to a maximum of
150 mg . We suggest a higher bolus dose of IC
adenosine (100–150 mg) to ensure an adequate
hyperemic response
4. No reflow phenomenon
17. 2 studies in PPCI
1. AMISTAD I
2. AMISTAD II
3. Reduced infarct size, but did not reduce the primary clinical
endpoint, with in-hospital and 6-month clinical outcome being
similar to those in the placebo group
18. 2 Guidelines support
1. European Society of Cardiology
2. American Heart Association
3. Treatment of no-reflow using IC adenosine is recommended
19. 2 Conditionings
Pre-conditioning Post-conditioning
A1 and A3 receptors
10-min IV adenosine infusion (dose of 2 mg/min)
administered before the PCI pre-conditioned the
myocardium
improve outcomes in elective PCI and CABG
A2a and A3 receptor
a protocol :consisted of 4 cycles of 1 min of balloon
inflation followed by 1 min of balloon deflation
within 1 min of reflow after coronary stent
deployment
Reduces CPK/CPK-MB
20. Novel Agents for Achieving Hyperaemia
Cyclosporine Regadenoson
The most promising pharmacological
post- conditioning mimetic drug InhibitS
formation of the mitochondrialpermeability
transition pore,akey component of lethal
reperfusion injury . The mitochondrial
permeabilitytransition poreappearsto form in
the early stages of reperfusion in response
tothecalciumoverloadandreactive oxygen
species generation that develops with
reperfusion
Selective adenosine a2a receptor agonist And
in theory should produce hyperemic effects
similar to those of adenosine without the additional
side effects often seen with A1, a2b, and A3 receptor
activation
IV bolus
FFR study
21. Arrhythmia
1. IVadenosinein abolusdoseof 6to12mg(or higher) slowsA
Vnodal
conductionandbythis mechanism interruptsre-entrant pathwaysinvolving
theA
Vnodeandrestoressinusrhythmin mostpatients with SVT
2. TypicalA
Vnodalre-entrant tachycardia
3. A
Vreciprocating tachycardiawith aconcealedbypasstract,andA
V
reciprocating tachycardiain Wolff-Parkinson-White syndrome
4. Unmaskatrial flutter/atrial fibrillation
5. Correct diagnosis of broadcomplextachycardia
6. T
erminateVTof triggeredactivity
