Hello friends. In this PPT I am talking about Cardiovascular system drugs. If you like it, please do let me know in the comments section. A single word of appreciation from you will encourage me to make more of such videos. Thanks. Enjoy and welcome to the beautiful world of pharmacology where pharmacology comes to life. This video is intended for MBBS, BDS, paramedical and any person who wishes to have a basic understanding of the subject in the simplest way.
1. Drugs Affecting Renin Angiotensin
System
Dr. Karun Kumar
Senior Lecturer
Dept. of Pharmacology
2.
3. Actions of Angiotensin II
1. The most prominent action of Ang II is
vasoconstriction—produced directly as well as by
enhancing Adr/NA release from adrenal
medulla/adrenergic nerve endings and by
increasing central sympathetic outflow. BP rises
acutely. As a pressor agent, Ang II is much more
potent than NA
4. 2. Ang II increases force of myocardial contraction.
Reflex bradycardia predominates and cardiac output is
often reduced while cardiac work is increased (due to
rise in peripheral resistance)
3. Ang II acting on a chronic basis induces hypertrophy
and hyperplasia in the myocardium and vascular
smooth muscle by direct cellular effects. Indirectly,
volume overload and increased t.p.r. caused by Ang II
contributes to the hypertrophy and remodeling
(abnormal redistribution of muscle mass) in heart and
blood vessels.
5. Angiotensin receptors
• Two subtypes (AT1 and AT2) have been differentiated
pharmacologically
• Losartan is a selective AT1 antagonist, while PD
123177 is a selective AT2 antagonist.
• Both subtypes are GPCRs
• All major effects of Ang II are mediated by AT1
receptor
6. Pathophysiological roles
1. Mineralocorticoid secretion Ang II (also Ang III) is
the physiological stimulus for aldosterone secretion
from adrenal cortex
2. Electrolyte, blood volume and pressure homeostasis
The RAS plays an important role in maintaining
electrolyte composition and volume of extracellular
fluid. Changes that lower blood volume or blood
pressure, or decrease Na+ content induce renin
release
7. • Increased renin is translated into increased plasma
Ang II which produces acute rise in BP by
vasoconstriction, and more long-lasting effects by
directly as well as indirectly increasing Na+ and water
reabsorption in the kidney. Rise in BP in turn inhibits
renin release.
3. Development of hypertension The RAS is directly
involved in renovascular hypertension. In essential
hypertension and pregnancy induced HTN it appears to
have a permissive role.
8.
9. 4. Secondary hyperaldosteronism The RAS is
instrumental in the development of secondary
hyperaldosteronism
5. CNS Ang II can be formed locally in the brain and
may function as transmitter or modulator
• Regulation of thirst, hormone release and
sympathetic outflow may be the responses
mediated.
10. Inhibition of renin-angiotensin system
1. Sympathetic blockers (β blockers, adrenergic
neurone blockers, central sympatholytics)—
decrease renin release
2. Direct renin inhibitors (DRIs): block renin action—
interfere with generation of Ang I from
angiotensinogen (rate limiting step)
3. Angiotensin converting enzyme (ACE) inhibitors—
prevent generation of the active principle Ang II.
4. Angiotensin receptor blockers (ARBs)— antagonise
the action of Ang II on target cells.
5. Aldosterone antagonists—block mineralocorticoid
receptors
11. Angiotensin converting
enzyme inhibitors
• Captopril Abolishes the pressor action of Ang I but
not that of Ang II: does not block AT1 or AT2 receptor
• It ↑ plasma kinin levels and potentiates the
hypotensive action of exogenously administered
bradykinin
• Elevated kinins (and PGs whose synthesis is
enhanced by kinins) may be responsible for cough
and angioedema induced by ACE inhibitors in
susceptible individuals.
12.
13. • Captopril lowers BP. This is more marked when Na+
has been depleted by dietary restriction or diuretics,
because renin level is high.
• Captopril induced hypotension is a result of
decrease in total peripheral resistance. Both systolic
and diastolic BP fall.
• It has no effect on cardiac output
• Cardiovascular reflexes are not interfered with and
there is little dilatation of capacitance vessels
Postural hypotension is not a problem.
14.
15. • Reflex (postural) changes in plasma aldosterone are
abolished and basal levels are somewhat decreased
as a consequence of loss of its regulation by Ang II.
• However, physiologically sufficient mineralocorticoid
is still secreted under the influence of ACTH and
plasma K+
16. Adverse Effects,C/I & DI
C Cough
A Allergies (Angioedema, urticaria, rashes)
P Potassium level inc.
T Taste alteration
O On 1st dose hypotension (orthostatic)
P Pregnancy, Pancreatitis (C/I)
R Renal artery stenosis
I Indomethacin & other NSAIDs
L Lithium
17.
18. Interactions
1. Indomethacin (and other NSAIDs) attenuate the
hypotensive action by retaining salt and water while
diuretics synergise with them
2. Hyperkalemia can occur if K+ supplements/ K+
sparing diuretics are given with captopril
3. Antacids reduce bioavailability of captopril
4. ACE inhibitors reduce Li+ clearance and predispose
to its toxicity
19. Uses
• Hypertension The hypotensive effect of lower
doses develops gradually over 2–3 weeks. They offer
the following advantages:
1. Free of postural hypotension, electrolyte
disturbances, feeling of weakness and CNS effects.
2. Safety in asthmatics, diabetics and peripheral
vascular disease patients.
3. Renal blood flow is well maintained.
4. Left ventricular hypertrophy and increased wall-to-
lumen ratio of blood vessels that occurs in
hypertensive patients is reversed.
20. 5. No hyperuricaemia, no deleterious effect on plasma
lipid profile.
6. No rebound hypertension on withdrawal.
7. Minimum worsening of quality of life parameters like
general wellbeing, work performance, sleep, sexual
performance, etc
21. CHF
• First line drugs
• ACE inhibitors cause both arteriolar and
venodilatation in CHF patients; reduce afterload as
well as preload.
• ACE inhibitors retard the progression of left
ventricular systolic dysfunction and prolong survival
of CHF patients of all grades (I to IV)
• In addition to improved haemodynamics, long-term
benefits of ACE inhibitors accrue from withdrawal of
Ang II mediated ventricular hypertrophy, remodeling,
accelerated myocyte apoptosis and fibrosis.
22. 3. Myocardial infarction (MI) ACE inhibitors
administered while MI is evolving (within 24 hrs. of an
attack) and continued for 6 weeks reduce early as well
as long-term mortality
4. Prophylaxis in high cardiovascular risk subjects
ACE inhibitors are protective in high cardiovascular risk
subjects even when there is no associated hypertension
or left ventricular dysfunction.
• Protective effect is exerted both on myocardium as
well as vasculature, and is independent of
hypotensive action.
23. 5. Diabetic nephropathy Prolonged ACE inhibitor
therapy has been found to prevent or delay end-stage
renal disease in type I as well as type II diabetics.
6. Scleroderma crisis The marked rise in BP and
deterioration of renal function in scleroderma crisis is
mediated by Ang II. ACE inhibitors produce dramatic
improvement and are life saving in this condition
24. Angiotensin receptor blockers or ARBs
• Losartan It is a competitive antagonist and inverse
agonist, 10,000 times more selective for AT1 than for
AT2 receptor; does not block any other receptor or
ion channel
• All of Ang II actions are blocked. No inhibition of ACE
has been noted.
• Pharmacologically, ARBs differ from ACE inhibitors in
that they do not interfere with degradation of
bradykinin
25. • Losartan causes fall in BP in hypertensive patients
which lasts for 24 hours, while HR remains
unchanged and cardiovascular reflexes are not
interfered.
• No significant effect on plasma lipid profile,
carbohydrate tolerance, insulin sensitivity has been
noted.
• A mild Probenecid like uricosuric action is produced
• Same potential for regressing LVH as ACE inhibitors
26. Adverse effects
• Losartan is well tolerated
• Hypotension and hyperkalemia, but first dose
hypotension is uncommon
• Losartan is considered to be free of cough and
dysgeusia
• Headache, dizziness, weakness and upper g.i. side
effects are mild and occasional.
• Has fetopathic potential like ACE inhibitors—not to
be administered during pregnancy.
28. Calcium channel blockers
• Act by inhibiting L type voltage sensitive calcium
channels in smooth muscles and heart
• The two most important actions of CCBs are:
1. Smooth muscle (especially vascular) relaxation
2. Negative chronotropic, inotropic and dromotropic
action on heart
• Smooth muscle DHPs have the most marked
smooth muscle relaxant and vasodilator action
31. Verapamil
• It causes vasodilatation as well as cardiac depression
• Along with BP lowering, it produces bradycardia,
slowing of A-V conduction and may worsen heart
failure
• It should not be used concurrently with β blockers or
other cardiac depressants
• Adverse effects Nausea, constipation and
bradycardia
32. Diltiazem
• Less marked cardiodepressant activity
• Fall in BP with little change or decrease in HR
• Milder side effects
• Drug interactions & contraindications same as for
Verapamil
33. Nifedipine
• Rapidly acting DHP with short duration of action
• Frequent side effects are palpitation, flushing, ankle
edema, headache
• Paradoxically worsened angina
• Higher mortality among post MI subjects
• Slow onset and longer acting DHPs have replaced
Nifedipine
34. Uses
1. Angina pectoris All CCBs are effective in reducing
frequency and severity of classical as well as variant
angina.
• Benefit in classical angina appears to be primarily
due to reduction in cardiac work: mainly as a result
of reduced afterload
• Though, they can increase coronary flow in normal
individuals, this is unlikely to be significant in
patients with fixed arterial obstruction.
• Exercise tolerance is increased
35. • Myocardial ischaemia may be aggravated by short-
acting DHPs (↓ coronary flow secondary to fall in
mean arterial pressure, reflex tachycardia and
coronary steal)
• Trials using high dose regular short-acting nifedipine
formulation have reported increased mortality
among MI patients.
36. • The sudden rush of sympathetic activity evoked by
each dose of these preparations has been held
responsible for the deleterious effect.
• The slow and long-acting DHPs do not share this
disadvantage. The direct cardiac effect of verapamil
and diltiazem to reduce O2 requirement and less
marked reflex sympathetic stimulation makes them
unlikely to aggravate ischaemia.
• DHPs prevent arterial spasm (Variant angina)
37. 2. Hypertension
3. Cardiac arrhythmias Verapamil and diltiazem are
highly effective in PSVT and for control of ventricular
rate in supraventricular arrhythmias
4. Hypertrophic cardiomyopathy The negative
inotropic action of verapamil can be salutary in this
condition.
38. Antihypertensive Drugs
• Many patients presenting for dental treatment are
likely to be on long term antihypertensive drug
therapy
• Beta blockers are not considered first line drugs
• Thiazides are the DOC
43. Thiazides (hydrochlorothiazide,
Chlorthalidone)
• The proposed mechanism of antihypertensive action
is:
1. Initially, the diuresis reduces plasma and e.c.f.
volume by 5–15%, and this decreases C.O.
2. Subsequently, compensatory mechanisms operate
to almost regain Na+ balance and plasma volume;
C.O. is restored, but the fall in BP is maintained by a
slowly developing reduction in t.p.r.
44. 3. The reduction in t.p.r. is most probably an indirect
consequence of a small (~5%) persisting Na+ and
volume deficit
• Decrease in intracellular Na+ concentration in the
vascular smooth muscle may reduce stiffness of
vessel wall, increase their compliance and dampen
responsiveness to constrictor stimuli (NA, Ang II)
• Similar effects are produced by salt restriction
45. • The fall in BP develops
gradually over 2–4 weeks
• Maximal antihypertensive
efficacy is reached at 25
mg/day dose, though
higher doses produce
greater diuresis
• Their antihypertensive
action is attenuated by
NSAIDs
46.
47. High ceiling diuretics (Furosemide)
• Furosemide is a weaker antihypertensive than
thiazides (brief duration of action)
• The natriuretic action lasting only 4–6 hr after the
conventional morning dose is followed by
compensatory increase in proximal tubular
reabsorption of Na+
• The Na+ deficient state in vascular smooth muscle
may not be maintained round-the-clock
48. Indications
1. Chronic renal failure Thiazides are ineffective,
both as diuretic and as antihypertensive.
2. Coexisting refractory CHF
3. Resistance to combination regimens containing a
thiazide, or marked fluid retention due to use of
potent vasodilators
49. Potassium sparing diuretics
(Spironolactone, Eplerenone)
• Lower BP slightly
• Used in conjunction with a thiazide diuretic to
prevent K+ loss and to augment the antihypertensive
action
• Spironolactone is not favoured because of its
hormonal side effects (gynaecomastia, impotence,
menstrual irregularities)
50.
51. Sodium nitroprusside
• It is a rapidly (within seconds) and consistently acting
vasodilator; has brief duration of action (2–5 min) so
that vascular tone can be titrated with the rate of i.v.
infusion
• Relaxes both resistance and capacitance vessels:
reduces t.p.r. as well as c.o. (by decreasing venous
return)
• Myocardial work is reduced
• Ischaemia is not accentuated, as occurs with
selective arteriolar dilators (hydralazine)
52. • Little reflex tachycardia is produced in supine posture
• Endothelial cells, RBCs (and may be other cells) split
nitroprusside to generate NO which relaxes vascular
smooth muscle
• 50 mg is added to a 500 ml bottle of saline/glucose
solution. The infusion is started at 0.02 mg/min and
titrated upward with the response: 0.1–0.3 mg/min
is often needed
• It decomposes on exposure to light: the infusion
bottle should be covered with black paper
53. • Side effects mainly due to vasodilatation are—
Palpitation, nervousness, vomiting, perspiration, pain
in abdomen, weakness, disorientation, and lactic
acidosis
• Other uses
1. Produce controlled hypotension
2. Refractory CHF
3. Pump failure accompanying MI
54. Treatment of hypertension
• Aim Prevent morbidity and mortality associated
with persistently raised BP by lowering it to an
acceptable level, with minimum inconvenience to the
patient
• Both systolic and diastolic BP predict the likelihood of
target organ damage (TOD) and complications such
as:
1. Cerebrovascular disease, transient ischaemic
attacks, stroke
2. Hypertensive heart disease—left ventricular
hypertrophy, CHF
55. 3. Coronary artery disease (CAD), angina, myocardial
infarction, sudden cardiac death
4. Arteriosclerotic peripheral vascular disease,
retinopathy
5. Dissecting aneurysm of aorta
6. Glomerulopathy, renal failure
• Non-pharmacological measures should be tried first
57. Stepped care approach
Step I Drug selected on basis of age and race of
patient
• Young (<55 y) non-black subjects ACEi/ARB
• Older non-blacks and blacks of all ages CCB/thiaz.
Step II If target BP is not achieved by single drug,
ACEi/ARB + CCB/diuretic irrespective of age or race
Step III All 3 1st line drugs used together
Step IV Ald. Antag. (Eplerenone) OR higher dose
thiazide OR β blocker OR sel. α1 blocker [4th drug]
58. Hypertensive emergencies and
urgencies
• Systolic BP > 220 or diastolic BP > 120 mm Hg with
evidence of target organ damage ‘hypertensive
emergency’
• Systolic BP > 220 or diastolic BP > 120 mm Hg
without target organ damage ‘hypertensive
urgency’
• Controlled reduction of BP over minutes (in
emergencies) or hours (in urgencies) is required to
counter threat to organ function and life
59. Parenteral Management
1. Nicardipine DOC for hypertensive emergencies
2. Sodium nitroprusside Restr. to cases with aortic
dissection or acute heart failure
3. Glyceryl trinitrate Suitable for lowering BP after
cardiac surgery and in acute LVF, MI, unstable
angina
4. Esmolol β1 blocker given as bolus followed by
slow i.v. injection,acts in 1–2 min; action lasts for
10–20 min. It is particularly useful when cardiac
contractility and work is to be reduced, such as in
aortic dissection and during/after anaesthesia
60. 5. Labetalol α + β blocker; useful for lowering ↑ BP
in hyperadrenergic states, e.g. hypertensive episodes in
pheochromocytoma, cheese reaction or clonidine
withdrawal. Injected i.v. it acts in 2 min and action lasts
5–15 min.
Oral drugs (Useful in HTN urgencies)
1. Amlodipine 10 mg repeat after 12 h; then OD
2. Labetalol 100-200 mg BD (1st line drug in
pheochromocyt., preeclampsia, ischemic heart d/s)
61.
62. Antianginal Drugs
• Antianginal drugs are those that prevent, abort or
terminate attacks of angina pectoris
• Since a patient may develop an attack of angina
during dental procedure, dentists should be familiar
with its management
• Angina is a symptom complex caused by transient
myocardial ischemia and constitutes a “clinical
syndrome” rather than a disease
63. • The term derives from the Latin angina ("infection of
the throat") from the Greek ankhonē ("strangling"),
and the Latin pectus ("chest"), and can therefore be
translated as "a strangling feeling in the chest"
• Anti anginal drugs relieve cardiac ischaemia but do
not alter the course of coronary artery pathology
No permanent benefit is afforded
67. Nitrates
• All organic nitrates share the same action; differ only
in time course
• Major action Nonspecific smooth muscle
relaxation
1. Preload reduction The most prominent action is
exerted on vascular smooth muscle
• Nitrates dilate veins more than arteries → peripheral
pooling of blood → decreased venous return, i.e.
preload on heart is reduced → end diastolic size and
pressure are reduced → decreased cardiac work
68. • The decrease in end diastolic pressure abolishes the
sub endocardial crunch by restoring the pressure
gradient across ventricular wall due to which sub
endocardial perfusion occurs during diastole
• It is through their action on peripheral veins that
nitrates exert major beneficial effects in classical
angina
69. 2. Afterload reduction
• Nitrates also produce some arteriolar dilatation →
slightly decrease total peripheral resistance (t.p.r.) or
afterload on heart; BP falls somewhat; systolic more
than diastolic (reflex sympathetic activity tends to
maintain diastolic BP)
• Contributes to the reduction in cardiac work ∝ to
aortic impedance
70. 3. Redistribution of coronary flow
• In the arterial tree, nitrates preferentially relax bigger
conducting (angiographically visible) coronary
arteries than arterioles or resistance vessels
• This pattern of action may cause favorable
redistribution of blood flow to ischemic areas in
angina patients
71. Mechanism of relief of angina
• The relaxant effect on larger coronary vessels is the
principal action of nitrates benefiting variant angina
by counteracting coronary spasm
• In classical angina the primary effect is to reduce
cardiac work by action on peripheral vasculature,
though increased blood supply to ischaemic area
may contribute
• Exercise tolerance of angina patients is improved
72. Heart and peripheral blood flow
• Nitrates have no direct stimulant or depressant
action on the heart
• They dilate cutaneous (especially over face and neck
→ flushing) and meningeal vessels causing headache
• Splanchnic and renal blood flow decreases to
compensate for vasodilatation in other areas
• Nitrates tend to decongest lungs by shifting blood to
systemic circulation
73. Mechanism of action
Rapidly denitrated in smooth muscle cell
Nitric oxide released
Activation of guanylyl cyclase
Increased cyclic guanosine monophosphate (cGMP)
Dephosphorylation of myosin light chain kinase (MLCK)
No actin myosin complex formation
74.
75. Adverse effects
• Due to vasodilatation
1. Fullness in head, throbbing headache; some degree
of tolerance develops on continued use
2. Flushing, weakness, sweating, palpitation, dizziness
and fainting (mitigated by lying down)
3. Methemoglobinemia Insignificant with clinically
used doses
4. Rashes are rare
76. Tolerance
• Attenuation of haemodynamic and antiischaemic
effect of nitrates occurs in a dose and duration of
exposure dependent manner if they are continuously
present in the body
• This tolerance weans off rapidly (within hours) when
the body is free of the drug
• Clinically, no significant tolerance develops on
intermittent use of sublingual GTN for attacks of
angina
77. • However, it may become important when GTN is
used orally, transdermally or by continuous i.v.
infusion round the clock, as well as with the use of
long acting agents, especially sustained release
formulations
• The most practical way to prevent nitrate tolerance is
to provide nitrate free intervals everyday
78. Interactions
• Sildenafil causes dangerous potentiation of nitrate
action: severe hypotension, MI and deaths are on
record
• Additive hypotension is also possible when nitrate is
given to a patient receiving other vasodilators
79. Uses
1. Angina pectoris Nitrates are effective in classical
as well as variant angina. For aborting or
terminating an attack, sublingual GTN tablet or
spray, or isosorbide dinitrate is taken on ‘as and
when required’ basis
• Since dental procedures may provoke anxiety, an
anginal attack may be precipitated
• Sublingual GTN tablet or spray should be readily
available for aborting or terminating an attack on the
dental chair
80. 2. Myocardial infarction (MI)
• Carefully titrated i.v. infusion to avoid hypotension
and tachycardia, GTN is frequently used during
evolving MI with the aim of relieving chest pain,
pulmonary congestion and limiting the area of
necrosis by favourably altering O2 balance in the
marginal partially ischaemic zone by reducing cardiac
work
81. 3. CHF and acute LVF
• Nitrates afford relief by venous pooling of blood
(which can be aided by sitting posture while
managing acute LVF or severe chronic CHF) →
reduced venous return (preload) → decreased end
diastolic volume → improvement in left ventricular
function and regression of pulmonary congestion.
• Intravenous GTN is the preparation of choice for
emergency use.
82. 4. Biliary colic due to gallstone and that caused by
morphine responds to sublingual GTN or isosorbide
dinitrate.
5. Esophageal spasm Sublingual GTN promptly
relieves pain.
6. Cyanide poisoning Nitrates generate
methaemoglobin which has high affinity for cyanide
radical and forms cyanomethaemoglobin.
83. • In cyanide poisoning, sodium nitrite injected i.v.
produces methaemoglobin which has high affinity for
cyanide radical and forms cyanomethaemoglobin.
• However, this may again dissociate to release
cyanide.
• Therefore, sodium thiosulfate is given to form Sod.
thiocyanate which is poorly dissociable and is
excreted in urine.
• Cytochrome and other oxidative enzymes are thus
protected from cyanide
84.
85. β Blockers
• Reduce cardiac work and O2 consumption
• These drugs do not dilate coronaries or other blood
vessels; total coronary flow is rather reduced due to
blockade of dilator β2 receptors
• However, flow to the ischaemic subendocardial
region is not reduced because of favourable
redistribution and decrease in ventricular wall
tension.
• Cardioselective agents (atenolol, metoprolol) are
preferred over nonselective (e.g. propranolol)
86. CCBs Mechanism of action
Block voltage gated L-type calcium channels
↓ frequency of opening in response to depolarization
↓ transmembrane calcium current
↓ in contractility throughout the heart & ↓ sinus node
pacemaker rate and AVN conduction velocity
87. Potassium channel openers
• Nicorandil This dual mechanism antianginal drug
activates ATP sensitive K+ channels thereby
hyperpolarizing vascular smooth muscle
• Like nitrates it also acts as a NO donor—relaxes
blood vessels by increasing cGMP
• Thus, arterial dilatation is coupled with
venodilatation
• Coronary flow is increased; dilatation of both
epicardial conducting vessels and deeper resistance
vessels has been demonstrated
88. • No significant cardiac effects on contractility and
conduction have been noted
• Beneficial effects on angina frequency and exercise
tolerance comparable to nitrates and CCBs have
been obtained in stable as well as vasospastic angina
• Side effects of nicorandil are flushing, palpitation,
weakness, headache, dizziness, nausea and vomiting
• Mouth ulcers are frequent
89. Acute coronary syndromes
1. Unstable angina (UA) Vascular obstruction is
incomplete, myocardial necrosis is absent—
biochemical markers of ischaemia do not appear in
blood, and ST segment is not elevated in ECG.
2. Non ST segment elevation myocardial infarction
(NSTEMI): Vascular obstruction is incomplete, but is
attended by relatively smaller area of myocardial
necrosis; biochemical markers appear in blood, but
ST segment is not elevated
90. 3. ST segment elevation myocardial infarction (STEMI):
Vascular obstruction is complete, larger area of
myocardium is necrosed, biochemical markers are
prominent and ST segment in ECG is elevated
• However, UA and NSTEMI may progress to STEMI
• Management of NSTEMI (MONA)
• Management of STEMI (SONAM)
91. Drug therapy in myocardial
infarction
• MI Ischaemic necrosis of a portion of the
myocardium due to sudden occlusion of a branch of
coronary artery
• An acute thrombus at the site of atherosclerotic
obstruction is the usual cause
• About ¼ patients die before therapy can be instituted
• The remaining are best treated in specialized
coronary care units with continuous monitoring of
the haemodynamic parameters, biochemical markers
and ECG to guide the selection of drugs and dosage
92. Management
1. Pain, anxiety and apprehension After pain is not
relieved by 3 doses of GTN given 5 mins. apart, an
opioid analgesic (Morphine/Pethidine) or diazepam
is administered parenterally
2. Oxygenation By O2 inhalation and assisted
respiration, if needed
3. Maintenance of blood volume, tissue perfusion and
microcirculation Slow i.v. infusion of saline/low
molecular weight dextran (avoid volume overload)
93. 4. Correction of acidosis Occurs due to lactic acid
production; can be corrected by i.v. Sod. bicarbonate
infusion.
5. Prevention and treatment of arrhythmias
Prophylactic i.v. infusion of a β blocker (unless
contraindicated) is recommended.
• Its continuation orally for a few days has been shown
to reduce the incidence of arrhythmias and mortality
94. • β blockers used early in evolving MI can reduce the
infarct size (myocardial salvage) and subsequent
complications
• Tachyarrhythmias may be treated with i.v. Lidocaine,
Procainamide or Amiodarone
• Bradycardia and heart block may be managed with
Atropine or Electrical pacing
95. 6. Pump failure
• The objective is to increase C.O. and/or decrease
filling pressure without unduly increasing cardiac
work or lowering BP
• Drugs used for this purpose are:
1. Furosemide Indicated if pulmonary wedge
pressure is > 20 mm Hg. It decreases cardiac
preload.
96. 2. Vasodilators Venous or combined dilator is
selected according to the monitored haemodynamic
parameters
• Drugs like GTN (i.v.), or nitroprusside have been
mainly used
3. Inotropic agents Dopamine or Dobutamine i.v.
infusion may be needed to augment the pumping
action of heart and tide over the crisis
97.
98. 7. Prevention of thrombus extension,
embolism, venous thrombosis
• Aspirin (150–300 mg) should be given for chewing
and swallowing as soon as MI is suspected
• This is continued at 80–160 mg/day
• Anticoagulants (heparin followed by oral
anticoagulants) are used primarily to prevent deep
vein thrombosis (increased risk due to bed rest) and
pulmonary embolism
• Anticoagulants are not prescribed on long-term basis
now
99. 8. Thrombolysis and reperfusion
• Fibrinolytic agents, i.e. plasminogen activators—
Streptokinase/Urokinase/Alteplase/Tenecteplase to
achieve reperfusion of the infarcted area
• Unless thrombolysis can be started within 1–2 hours
of MI symptom onset, primary percutaneous
coronary intervention (PCI) with stenting is now the
preferred revascularization procedure, wherever
available
100. 9. Prevention of remodeling and subsequent CHF
ACE inhibitors/ARBs are of proven efficacy and afford
long-term survival benefit
10. Prevention of future attacks
(a) Platelet inhibitors Aspirin or Clopidogrel
(b) β blockers ↓ risk of reinfarction, CHF and
mortality. All patients not having any contraindication
are put on a β1 blocker for at least 2 years
(c) Control of hyperlipidaemia Dietary substitution
with unsaturated fats, hypolipidemic drugs especially
statins
101. Drugs for Heart Failure
• Cardiac glycosides Have cardiac inotropic
property. They increase myocardial contractility and
output in a hypodynamic heart without a
proportionate increase in O2 consumption
• In contrast, ‘cardiac stimulants’ (Adr, theophylline)
increase O2 consumption rather disproportionately
and tend to decrease myocardial efficiency
104. Pharmacological actions
1. Heart Digitalis causes a dose dependent increase
in force of contraction of heart—a positive inotropic
action.
• Heart rate is decreased by digitalis [Digitalis slows
the heart by vagal and extravagal actions (A direct
depressant action on SA and A-V nodes)]
107. • Digitalis increases force of cardiac contraction by
inhibiting membrane associated Na+K+ ATPase of
myocardial fibres
• Inhibition of this cation pump results in progressive
accumulation of Na+ intracellularly.
• This indirectly results in intracellular Ca2+
accumulation by Na+/Ca2+ exchange
• The excess Ca2+ remaining in cytosol is taken up into
SR which get loaded with more Ca2+ better
excitation-contraction coupling increased force of
contraction
108. Adverse effects
• Low therapeutic index 1.5–3
• Extracardiac Anorexia, nausea, vomiting and
abdominal pain
• Cardiac
1. Almost every type of arrhythmia can be produced
by digitalis: pulsus bigeminus, nodal and
ventricular extrasystoles, VT, VF
2. Partial to complete A-V block may be the sole
cardiac toxicity, or it may accompany other
arrhythmias
• DOC for digitalis-induced ventricular arrhythmias
Lignocaine
109. Contraindications of digitalis
• Contraindicated Carditis (Myocarditis)
• In Increased Ca2+ (Hypercalcemia)
• Weak WPW Syndrome
• H Hypokalemia & Hypomagnesemia
• E Elderly
• A AV Block (Partial)
• R Renal failure (Digoxin)
• T Thyroid (hyper or hypothyroidism)
110. Interactions
1. Diuretics cause hypokalemia which increases the
risk of digitalis arrhythmias; potassium supplements
should be given prophylactically.
2. Calcium synergises with digitalis → precipitates
toxicity.
3. Quinidine reduces binding of digoxin to tissue
proteins as well as its renal and biliary clearance by
inhibiting efflux → plasma concentration of digoxin
is raised → toxicity can occur.
111. 4. Adrenergic drugs can induce arrhythmias in
digitalized patients. Plain Lidocaine without Adr should
be injected for dental anaesthesia
5. Propranolol, verapamil, diltiazem and disopyramide:
may additively depress A-V conduction and oppose
positive inotropic action.
115. Arrest/reversal of disease progression
and prolongation of survival
1. ACE inhibitors/ARBs
2. β blockers
3. Aldosterone antagonist—Spironolactone,
Eplerenone
• Important nonpharmacological measures are rest
and salt restriction
122. Vaughan Williams & Singh classif.
1. M Membrane stabilizers (Class I)
2. B Beta blockers (Class II)
3. A AP widening agents (Class III)
4. College Calcium channel blockers (Class IV)
5. Miscellaneous (PADMA Shri)
1. Potassium
2. Adenosine
3. Digoxin
4. Magnesium
5. Atropine
123.
124. Drugs in AV block
• Definitive t/t of chronic heart block Pacing with an
implanted cardiac pacemaker
• Drugs are of value only for acute/transient A-V block
and as an interim measure
1. Atropine When A-V block is due to vagal overactivity,
e.g. digitalis toxicity, some cases of MI; it can be
improved by atropine 0.6–1.2 mg i.m.
2. Sympathomimetics (Adr, isoprenaline): These drugs
may overcome partial heart block or even complete
(3rd degree) heart block (↑ vent. Pacemaker activity)
Editor's Notes
ACE which is a dipeptidyl carboxypeptidase, an ectoenzyme located primarily on the luminal surface of vascular endothelial cells (especially in lungs).
Enzyme renin secreted by the kidney
Hypertr. inc. in size; hyperplasia inc. in number
AT1 Gq
Trophic Stimulating
Primary hyperaldosteronism is due to a problem of the adrenal glands themselves, which causes them to release too much aldosterone. In contrast, with secondary hyperaldosteronism, a problem elsewhere in the body causes the adrenal glands to release too much aldosterone. Secondary Hyperaldosteronism is typically caused by a reduced blood flow to the kidneys leading to excess aldosterone production. The causes of reduced kidney blood flow may include: Obstruction of the renal artery or renal artery stenosis. Heart failure
Angioedema is the rapid edema, or swelling, of the area beneath the skin or mucosa
Capacitance vessels are consid- ered to be the blood vessels that con- tain most of the blood and that can readily accommodate changes in the blood volume. They are generally considered to be veins.
Resistance arteries are usually arterioles or end-points of arteries.
Systemic scleroderma, also called diffuse scleroderma or systemic sclerosis, is an autoimmune disease of the connective tissue. It is characterized by thickening of the skin caused by accumulation of collagen, and by injuries to small arteries. There are two forms of scleroderma: localized and systemic.
Preload is related to the ventricular end-diastolic volume; a t.p.r.
The mechanism of the hypertensive effects of NSAIDs seem primarily related to their ability to block the cyclo-oxygenase pathway of arachidonic acid metabolism, with a resultant decrease in prostaglandin formation. The prostaglandins are important in normal modulation of renal and systemic vascular dilatation, glomerular filtration, tubular secretion of salt and water, adrenergic neurotransmission, and the renin-angiotensin-aldosterone system.
Organic nitrates are rapidly denitrated enzymatically in the smooth muscle cell to release the reactive free radical nitric oxide (NO) which activates cytosolic guanylyl cyclase → increased cGMP → causes dephosphorylation of myosin light chain kinase (MLCK) through a cGMP dependent protein kinase (Fig. 39.3). Reduced availability of phosphorylated (active) MLCK interferes with activation of myosin → it fails to interact with actin to cause contraction. Consequently relaxation occurs. Raised intracellular cGMP may also reduce Ca2+ entry—contributing to relaxation
Methemoglobin (English: methaemoglobin) (pronounced "met-hemoglobin") is a hemoglobin in the form of metalloprotein, in which the iron in the heme group is in the Fe3+ (ferric) state, not the Fe2+ (ferrous) of normal hemoglobin. Methemoglobin cannot bind oxygen, which means it cannot carry oxygen to tissues.
Troponin T, Troponin I, Myocardial fraction of CK, LDH; Necrosis (from the Greek νέκρωσις "death, the stage of dying, the act of killing" from νεκρός "dead") is a form of cell injury which results in the premature death of cells in living tissue by autolysis.
The pulmonary wedge pressure or PWP, or cross-sectional pressure (also called the pulmonary arterial wedge pressure or PAWP, pulmonary capillary wedge pressure or PCWP, or pulmonary artery occlusion pressure or PAOP), is the pressure measured by wedging a pulmonary catheter with an inflated balloon into a small pulmonary arterial branch.[1] It estimates the left atrial pressure.
stent is a tiny tube that your doctor can insert into a blocked passageway to keep it open
marked by or exhibiting a decrease in strength or power the failing or hypodynamic heart.
(Adr, theophylline)
uses
Digoxin toxicity Digibind( Digoxin specific crossreacts with digitoxin also. The Fab); COROnary blood flow occurs during diastole
Digitalis is contra-indicated in Wolff-Parkinson-White (WPW) syndrome because it decreases the conduction through the AV node but not through the aberrant pathway.
As nouns the difference between electrocardiograph and electrocardiogram is that electrocardiograph is a device used in the diagnosis and detection of heart abnormalities that measures electric potentials on the surface of the body and creates a record (electrocardiogram) of the electrical currents associated with heart muscle activity while electrocardiogram is (cardiology) the visual output that an electrocardiograph produces.
I VGSC blockers
Digoxin increases vagal activity and is used for controlling ventricular rate in atrial fibrillation and flutter.