Circulatory System Notes (PDF)

Summary

These notes cover the circulatory system, a critical biological system. They delve into the components of the circulatory system, including the cardiovascular and lymphatic systems, the heart's function, and its relation to blood circulation. Diagrams and flowcharts aid comprehension.

Full Transcript

CIRCULATORY SYSTEM

CIRCULATORY SYSTEM consists of

a) CARDIOVASCULAR SYSTEM-
Consists of HEART and BLOOD VESSELS
Circulates BLOOD

b) LYMPHATIC SYSTEM-
Consists of LYMPH NODES and LYMPH VESSELS
Circulates lymph, nutrients, waste matters, hormones
CARDIOVASCULAR SYSTEM

HEART
&
BLOOD VESSELS

Kardia (Greek): Heart
Vasculum (Latin): Blood vessels
WHAT IS THE ROLE?

It Service the needs of tissues
– It transports oxygen and nutrients to the tissues
– It transports waste material away
– It transports the hormones from one part of the body
to another

* In general to maintain an appropriate environment in
all the tissue fluids of the body for optimal survival
and function of the cells
ANATOMY OF HEART
Cone shaped -the hollow muscular organ

Weight- 330 gms

Sized roughly like a man’s closed fist

Contracts- 100,000 times per day

Pumps out 5 litres of blood per minute

Situated in the thoracic cavity between the lungs
ANATOMY OF HEART
ANATOMY OF HEART

It consists of –

Chambers
Valves
Vessels
Cardiac layers
HEART
HEART : INTERNAL STRUCTURE

4 Layers

Pericardium (outermost covering of Heart)
Epicardium (outer layer)
Myocardium (middle layer)
Endocardium (inner layer)

4 Chambers

2 Atria: Right Atrium & Left Atrium
2 Ventricles: Right Ventricle & Left Ventricle
HEART : INTERNAL STRUCTURE
4 Vessels

Vena Cava
Pulmonary Artery
Pulmonary Vein
Aorta

4 Valves

Aortic valve
Pulmonary valve
Tricuspid valve
Bicuspid valve (Mitral valve)
 LAYERS OF HEART
1 The outermost sac -Pericardium

2 The outer layer- Epicardium

3 The middle layer- Myocardium
(cardiac muscle)
4 The inner layer- Endocardium

Epicardium
Endocardium
Myocardium
PROPERTIES OF CARDIAC MUSCLE

I. Excitability
II. Conductivity
III. Contractility
IV. Rhythmicity
PROPERTIES OF CARDIAC MUSCLE
EXCITABILITY = the ability of cardiac muscle to respond to adequate stimuli by
generating an action potential followed by a mechanical contraction.

CONDUCTIVITY = the ability of cardiac ms fibers to conduct the cardiac impulses that
are initiated in the SA-node (the pacemaker of the heart).

CONTRACTILITY = the ability of the cardiac muscle to convert
chemical energy into mechanical work.

RHYTHMICITY= the ability of cardiac ms to contract in a regular
constant manner w/out nerve supply.
♥ It’s myogenic in origin (i.e. not neurogenic).
♥ Its initiated by the ‘pacemaker’ of the ht, the SA- node.
VESSELS CONNECTED TO HEART

PULMONARY PULMONARY
SUPERIOR ARTERY VEIN
VENA
CAVA
RIGHT ATRIUM LEFT ATRIUM
INFERIOR
VENA RIGHT LEFT
CAVA VENTRICLE VENTRICLE

AORTA
HEART & BLOOD CIRCULATION
CIRCULATION FLOWCHART
Superior Vena Cava & Inferior Vena Cava
(Deoxygenated blood)

Right Atrium

Tricuspid Valve

Left Atrium

Pulmonary Valve

Pulmonary Artery

Lungs (Exchange of gases CO2 O2 )
CIRCULATION FLOWCHART
Pulmonary Vein
(Oxygenated blood)

Left Atrium

Bicuspid Valve

Left Ventricle

Aortic Valve

Aorta
(largest artery)

Different body parts
CONDUCTING SYSTEM OF HEART

There are small groups of specialized cells in the
myocardium which initiate and conduct
impulses causing coordinated and synchronized
contraction of the heart muscles
CONDUCTIVITY SYSTEM

SA node
AV node
Bundle of His
Right and Left Bundle of His
Purkinje Fibers
CONDUCTING SYSTEM OF HEART
CARDIAC MUSCLE CONTRACTION

Action potential over the cardiac muscle membrane

Spreads to the interior

Release of Ca++ ions into the muscle

Ca++ ions diffuse in myofibrils

Muscle contraction
 CARDIAC CYCLE
Sequence of events which occur in the heart during a beat
It consists of two phases-

Systole
Phase of contraction- When heart pumps the blood

Diastole
Phase of relaxation- When the chambers of the heart receive blood from different
sites

Normal Cardiac Cycle = Systole and Diastole of both atria and both
ventricles (lasts for 0.8 s)
ANIMATED HEART
BLOOD CIRCULATION
TYPES OF BLOOD VESSELS

 Artery
 Vein
 Capillaries
 ARTERIES VEINS

 Carry blood away from the heart  Carry the blood towards the heart

 Usually carry deoxygenated blood
 Usually carry oxygenated blood

 Contains no valves  Contains valves

 Walls are thicker  Walls are thinner
 LAYERS OF BLOOD VESSELS
1. Tunica Externa- Outer layer- protection
2. Tunica Media- Middle layer-made up of smooth muscles- responsible for
vasoconstriction and vasodilation
3. Tunica Interna- Intima/Endothelial layer
 CAPILLARIES

- Wall formed by a single
layer of endothelial cells

- Provides large filtering
surface -

- Exchange of gases,
electrolytes ,etc, takes
place at this level
TWO TYPES OF CIRCULATION
 CIRCULATION
Aorta

Artery

Arterioles

Capillaries
(Exchange of gases between organ and blood)

Venules

Veins

Superior and Inferior Vena cava
BLOOD PRESSURE

It is the lateral pressure exerted by the flowing blood on
the walls of the blood vessels

It is expressed as

BP = Cardiac Output  Peripheral Vascular
(CO) Resistance
(PVR)
Normal BP should be 120/80 mm/Hg
BLOOD PRESSURE
Arterial blood pressure varies
rhythmically with the beating of the
heart

Rising to the maximum during the
ventricular contraction (Systole) when
the blood is pumped into the arteries:
Systolic Blood Pressure

Falling to the minimum when ventricle
relaxes (Diastole):
Diastolic Blood Pressure
BLOOD PRESSURE
Formula for Blood Pressure is –

B.P = C.O x PVR
(Blood Pressure) (Cardiac Output) (Peripheral Vascular Resistance)

S.V X H.R X PVR
(Stroke Volume) (Heart Rate)

B.V X F.O.C X H.R X PVR
(Blood Volume) (Force of Contraction)

Hence, BP= BV X FOC X HR X PVR
DEFINITIONS

 CO= Cardiac Output
It is the volume of blood being pumped by the heart, right ventricle in the
time interval of one minute

 PVR=Peripheral Vascular Resistance
It is the resistance applied by the walls of blood vessels on the circulating
blood

 S.V= Stroke Volume
It is the volume of blood pumped out of the heart with each beat/stroke
Generally, its 70 mL
DEFINITIONS

 HR=Heart Rate
It is the speed of the heartbeat, specifically the number of heartbeats per
unit of time. Generally, its 72 times/minute

BV= Blood Volume
It is the volume of blood (both red blood cells and plasma) in
the circulatory system of any individual

FOC= Force of Contraction
It is the force with which the heart contracts to pump out the blood
Common Terminology

Tachycardia: Increase in Heart Rate

Bradycardia: Decrease in Heart Rate

Arrhythmia: Abnormal Rhythm of Heart
 Common Terminology
CHRONOTROPHIC EFFECT : Effect on Heart Rate (HR)
Positive Chronotropic Effect- Increased HR
Negative Chronotropic Effect- Decreased HR

IONOTROPHIC EFFECT: Effect on Force Of Contraction (FOC)
Positive Ionotropic Effect- Increased FOC
Negative Ionotropic Effect- Decreased FOC

DROMOTROPHIC EFFECT: Effect on the conduction of the Cardiac Impulse
Positive Dromotropic Effect- Increased Conduction Rate
Negative Dromotropic Effect- Decreased Conduction Rate
BLOOD VESSELS AND ORGANS

Coronary Artery- Heart

Carotid / Cerebral Artery- Brain

Peripheral Arteries- Peripheral Organs (Legs)
Can you Guess?

Parameters Blood Pressure change

Vasodilation ?

Vasoconstriction ?

Increased cardiac
?
output
Increased venous
?
return
REGULATION OF BLOOD
CIRCULATION
REGULATION OF BLOOD CIRCULATION

 NERVOUS SYSTEM

 ROLE OF KIDNEYS
NERVOUS SYSTEM

SYMPATHETIC
Predominant role

PARASYMPATHETIC
Minor role
 SYMPATHETIC NERVOUS SYSTEM
Operates through release of nor-adrenaline/adrenaline Receptors
Two types of receptors are present-

 

1 2 1 2

Blood Vessels CNS Heart Blood Vessels
Kidney Bronchioles
NERVOUS SYSTEM
Receptor Tissue Response

Increased
 Heart Rate
Cardiac
1 receptor  Force of Contraction
 Atrio-Ventricular conduction

Kidneys Renin release

Lungs Bronchodilation
2 receptor
Blood vessels Vasodilation
NERVOUS SYSTEM

Receptor Tissue Response

 1 Receptor Blood vessels Vasoconstriction

Central mediated blood
 2 receptor CNS
pressure depression
PARASYMPATHETIC NERVOUS SYSTEM

PARASYMPATHETIC
Minor role

Decreases Heart Rate
Slightly Decreases Force of Contraction (FOC)of heart
 Vasoconstrictor Agents Vasodilator Agents

Noradrenaline/ Adrenaline Bradykinin

Angiotensin Histamine

Vasopressin (ADH)
 Role of Kidneys in BP Control

Hypertension Hypotension

Regulate output of salt
and water Release of Renin

Increase Urination Stimulate RAAS
Decrease BP Increase BP
RENIN ANGIOTENSIN ALDOSTERON SYSTEM
Angiotensinogen (Liver)
Renin (Kidney)

Angiotensin I
ACE (Angiotensin Converting Enzyme)
Angiotensin II
AT1 AT2 ( Role in CVS is not clear)
receptors receptors
Heart
Blood Vessels
Kidney
Adrenal gland
Pituitary gland
Brain
 ACTION OF ANGIOTENSIN II
HEART - Increase myocardial contractility

BLOOD VESSELS - Vasoconstriction

KIDNEY - Increase sodium and water retention, suppress Renin secretion

ADRENAL GLANDS - Increase Aldosterone release

PITUITARY GLAND - Increase ADH/ Vasopressin

BRAIN - Increase thirsty feeling

INCREASE IN BLOOD PRESSURE
 HYPERTENSION

The Persistent elevation (increase) in the Blood
pressure than the normal which is sustained is
called as Hypertension

It is a chronic medical condition in which
the blood pressure in the arteries is elevated
 TYPES OF HYPERTENSION
Hypertension is classified into two majorly :

 Primary (Essential) Hypertension
About 90–95% of cases are categorized as "Primary Hypertension" which means high
blood pressure with no obvious underlying medical cause

 Secondary (Non-essential) Hypertension
5–10% of cases (Secondary Hypertension) are caused by other conditions that affect the
kidneys, arteries, heart or endocrine system. It is with known cause. E.g. Renal,
Endocrinal
OTHER TYPES OF HYPERTENSION

 Isolated Systolic Hypertension
When there is rise only in systolic BP but Diastolic BP is
normal. It is defined as Systolic BP > 140 mm Hg and Diastolic
BP < 90 mm Hg

 White Coat Hypertension
Patient’s BP is elevated when measured by a physician but
normal when measured outside the health care setting
 JOINT NATIONAL COMMITTEE VIII (JNC)

TARGET GOAL ACHIEVEMENT

Patients below 60 yrs of age-
140/90 mm/Hg

Patients above 60 yrs age-
150/90 mm/Hg
JOINT NATIONAL COMMITTEE VII (JNC)
TARGET GOAL ACHIEVEMENT

Seventh report of Joint National Committee (JNC VII) guidelines, 2004

SBP- Systolic Blood Pressure; DBP – Diastolic Blood Pressure
RISK FACTORS
 Age :
Blood pressure rises with age in both men and women

 Sex:
Hypertension is less common in pre-menopausal women than
in men.
The cardiovascular risk in elderly men and women is similar in
postmenopausal period

 Family History

 Salt Intake:
Blood pressure increases proportionately with the salt intake
RISK FACTORS

 Smoking:

Nicotine and carbon monoxide, in tobacco smoke, are both
potent vasoconstrictors.
Smoking of two cigarettes causes 16mm Hg rise of both systolic
and diastolic blood pressure which does not return to pre
cigarette level for about 20 minutes.
Smoking is a very powerful contributor to morbidity and
mortality in hypertensive patients.
The incidence of stroke and coronary artery disease in
hypertensive patient who smoke is 2 -3 times greater than in
non-smoking patients with comparable blood pressure
RISK FACTORS

 Alcohol Intake:
Excessive alcohol intake is an important risk factor for
hypertension

 Physical Inactivity:
Sedentary individuals have a 20 to 50% increased risk of
developing hypertension

 Weight Gain:
Increased weight is a major controllable risk factor for new onset
of hypertension
RISK FACTORS

 Emotional Stress:
Mental stress is known to produce an acute rise of blood
pressure

Diabetes:
There is link between diabetes and hypertension
PATHOPHYSIOLOGICAL MECHANISMS

BP = Cardiac Output x PVR

The development of hypertension is due to
either increased Cardiac Output or elevated
Vascular Resistance
 SYMPTOMS OF HYPERTENSION
Asymptomatic - In early stages

Common Symptoms:

Headache, Giddiness, Irritability and Fatigue

Symptoms due to Organ Damage

Heart - Breathlessness
Coronary arteries - Angina, Acute MI
Kidneys - Polyuria, Nocturia
 COMPLICATIONS OF HYPERTENSION
BLOOD VESSELS
a) MACROVASCULAR Complications: Occurring in BIGGER blood vessels
Heart- Myocardial Ischemia, Angina, MI (Myocardial Infarction)
Brain- TIA( Transient Ischemic Attack) , Stroke
Peripheral Organs- Intermittent Claudication (Painful walking), PAD/ PVD
b) MICROVASCULAR Complications: Occurring in microscopic blood vessels
(CAPILLARIES)
Neuropathy, Nephropathy, Retinopathy, Hemorrhage

HEART
LVH-Left Ventricle Hypertrophy
CCF- Congestive Cardiac Failure
 LVH-Left Ventricular Hypertrophy

Left Ventricular Hypertrophy (LVH) is the thickening
of the myocardium (muscle) of the left ventricle of
the heart

While LVH itself is not a disease, it is usually a marker for
disease involving the heart

Disease processes that can cause LVH include any disease that
increases the Afterload that the heart has to contract against,
and some primary diseases of the muscle of the heart
LVH-Left Ventricular Hypertrophy

Cross-sectional Diagram
 PRELOAD

Preload is the end diastolic pressure that stretches the right
or left ventricle of the heart to its greatest geometric
dimensions under variable physiologic demand

In other words, it is the initial stretching of the cardiomyocytes
prior to contraction

Preload is theoretically most accurately described as the initial
stretching of a single cardiomyocytes prior to contraction

Atrial pressure is a surrogate for preload
PRELOAD

Stretching of Ventricles
AFTERLOAD

After load is the tension or stress developed in the wall of
the left ventricle during ejection

In other words, it is the end load against which the heart
contracts to eject blood

After load can also be described as –

the pressure that the chambers of the heart must generate
in order to eject blood out of the heart
AFTERLOAD

After load is readily broken into components:
It is the aortic pressure the left ventricular muscle must
overcome to eject blood

The greater the aortic/pulmonary pressure, the greater the after
load on the left/right ventricle, respectively

As After load increases, Cardiac Output decreases
AFTERLOAD

Ventricular Systole
CHF- Congestive Heart Failure

Chronic/Congestive Heart Failure (CHF) often used to mean
Heart Failure (HF), occurs when the heart is unable to pump
sufficiently to maintain blood flow to meet the needs of the
body

The terms Congestive Heart Failure (CHF)
or
Congestive Cardiac Failure (CCF) are often used interchangeably with
chronic heart failure

Heart failure is a physiological state in which Cardiac Output (CO) is
insufficient to meet the needs of the body and lungs
CAUSE
Common causes of CHF include-
CAD including
- A previous Myocardial Infaraction (heart attack)
- High Blood Pressure
- Atrial fibrillation
- Valvular Heart Disease
- Cardiomyopathy

These cause heart failure by changing either the structure or the functioning
of the heart

HF/CHF is caused by any condition which reduces the efficiency of the
myocardium, or heart muscle, through damage or overloading
TYPES OF CHF
There are two main types of HF/CHF:

- Heart Failure/CHF due to Left Ventricular Dysfunction
&
-Heart Failure/CHF with Normal Ejection Fraction,
depending on if the ability of the left ventricle to contract is affected, or the heart's
ability to relax

The severity of disease is usually graded by how much the ability to exercise is decreased

HF/CHF is not the same as myocardial infarction (in which part of the heart muscle
dies) or Cardiac arrest (in which blood flow stops altogether)

Diseases that may have symptoms similar to heart failure include: obesity, kidney
problems, liver problems, anemia and thyroid disease among others
EJECTION FRACTION

TYPICAL NORMAL
MEASURE
VALUE RANGE
Ejection Fraction (EF) End Diastolic
represents the volumetric Volume 120 mL 65–240 mL
fraction of blood pumped (EDV)
End Systolic
out of the left and Volume 50 mL 16 – 143 mL
right ventricle with each (ESV)
heartbeat or cardiac cycle Stroke
70 mL 55 – 100 mL
Volume (SV)
Ejection
Reduction in the ejection Fraction 58% 55 – 70%
fraction can manifest itself (Ef)
clinically as HF/CHF Heart Rate
75 bpm 60 – 100 bpm
(HR)
Cardiac
5.25L/min 4 – 8 L/min
Output (CO)
 Left Ventricular Dysfunction (LVD)
Left ventricular dysfunction (LVD) occurs as a series of
compensatory mechanisms are triggered which lead to a host of
structural and neuro-hormonal adaptations

LVD produces many changes in the structure and function of the
heart through a variety of mechanisms
MICROALBUMINURIA

Microalbuminuria (Urine albumin) occurs when the
kidney leaks small amounts of albumin into the urine,
in other words, when there is an abnormally high
permeability for albumin in the renal glomerulus
Albumin/Creatinine Ratio (ACR)

To compensate for variations in urine concentration in spot-check
samples, it is helpful to compare the amount of albumin in the sample
against its concentration of creatinine

This is termed the albumin/creatinine ratio (ACR)

Microalbuminuria is defined as –

ACR ≥3.5 mg/mmol (female) or ≥2.5 mg/mmol (male),
or,
with both substances measured by mass, as an ACR between 30 and
300 µg albumin/mg creatinine
DIAGNOSIS
The level of albumin protein produced by microalbuminuria can be
detected by special albumin-specific urine Dipsticks

A Microalbumin Urine Test determines the presence of the albumin in urine

In a properly functioning body, albumin is not normally present in urine because it
is retained in the bloodstream by the kidneys

An albumin level above the upper limit values is called “Macroalbuminuria", or
sometimes just Albuminuria

Sometimes, the upper limit value is given as one less (such as 300 being given as 299)
to mark that the higher value (here 300) is defined as Macroalbuminuria
SIGNIFICANCE
It is an indicator of subclinical cardiovascular disease

It is a marker of vascular endothelial dysfunction

It is an important prognostic marker for kidney disease in
Diabetes Mellitus
Hypertension
Post-streptococcal glomerulonephritis

Increasing microalbuminuria during the first 48 hours after admission to
an ICU predicts elevated risk for acute respiratory failure, multiple organ
failure, and overall mortality

It is a risk factor for venous thromboembolism
METABOLIC SYNDROME

Metabolic Syndrome is a disorder of energy utilization
and storage, diagnosed by a co-occurrence of three out
of five of the following medical conditions: abdominal
(central) obesity, elevated blood pressure, elevated
fasting plasma glucose, high serum triglycerides, and low
high-density cholesterol (HDL) levels

Metabolic syndrome increases the risk of developing CV disease
particularly Heart failure, and Diabetes
TREATMENT OF HYPERTENSION

Lifestyle Modification:

Weight reduction
Alcohol restriction
Regular Exercise
Restricting dietary sodium
Special diets
Relaxation/ Reducing stress
CLASSES OF ANTIHYPERTENSIVE DRUGS
 Beta Blockers
 Diuretics
 ACE Inhibitors (ACEI)
 Angiotensin - II Receptor Blockers (ARB)
Calcium Channel Blockers (CCB)
Other Antihypertensive drugs are-
 Alpha Blockers
 Central Alpha Agonists
 Renin Inhibitors, including aliskiren
 Vasodilators
 ANTIHYPERTENSIVE DRUG CLASS

BETA BLOCKERS & HYPERTENSION

One of the most frequently prescribed
antihypertensive agents

First introduced as therapy for Angina

In 1964, Propranolol was considered as an
antihypertensive agent
 CLASSIFICATION OF
BETA BLOCKERS
They are competitive blockers of beta-adrenoreceptors

Properties by which Beta-Blockers differ:

Propranolol
Non Selective
SELECTIVITY

Sotalol
Blocks β1 & β2 Timolol

Atenolol
Selective
Metaprolol
Blocks only β 1
PHARMACOKINETICS
Solubility of BETA BLOCKERS

Lipid Soluble Water Soluble
Eg. Metaprolol Eg. Atenolol
Timolol
Sotalol

Cross blood brain barrier Does not cross blood brain
So side effects of fatigue, barrier
Insomnia and nightmares
Metabolized by liver at rapid
Slowly excreted by kidney
rate.
MECHANISM OF ACTION
(In Hypertension)

Main suggested mechanisms are:

a) Reduction in Cardiac Output

Reduction in cardiac output is a major cause in chronic
Hence, reduction of BP

b) Reduction of Peripheral Vascular Resistance

Due to inhibition of Renin release
Hypertension In High Risk Patients

In such patients, preference needs to be given to an agent
with:
Established long term mortality and morbidity benefits

Evidence says in favor of beta blockers

Beta blockers significantly reduce:

- Sudden Cardiac Death
- Overall Coronary events
- Incidence of Stroke
Hypertension With IHD

BETA BLOCKERS are the drugs of choice

BETA BLOCKERS

- Reduces the frequency of attacks
- Reduces severity of symptoms
 IDEAL
BETA BLOCKERS

 Cardio-selective
 Long acting
 Simple pharmacokinetics (hydrophilic, no liver
metabolism, little protein binding)
 Must favorably alter mortality and morbidity

Of the available beta blockers, Atenolol comes closest to this profile
BETA-BLOCKERS IN ANGINA
Often agents of 1st choice in angina

BETA BLOCKERS

 Heart Rate  Force of Contraction

Reduces myocardial oxygen consumption
BETA-BLOCKERS IN ANGINA

 Effective in prophylactic angina
 Improve angina
 Reduce the frequency of attacks
 Reduce severity of symptoms
 Prolong the exercise tolerance endurance time
 ANTIHYPERTENSIVE DRUG CLASS
DIURETICS
These are the drugs which increase the rate of urine formation

Classification of Diuretics

A. Thiazide and related diuretics
e.g. Chlorthalidone, Chlorthiazide, Hydrochlorothiazide

B. Loop diuretics
e.g. Furosemide

C. Potassium sparing diuretics
e.g. Amiloride, Spironolactone, Triamterene
 MECHANISM OF ACTION

Elimination of edema in
Depletion of plasma volume
arterial walls
Reduced extracellular fluid volume including
plasma volume Reduces Arterial edema

Cardiac Output PVR

BP
BP
ADVANTAGES OF
DIURETICS

 Reduces cardiovascular morbidity and mortality in
controlled treatment trials
 Reduce rate of stroke
 Reduce coronary artery disease events (only with low
dose)
 Well tolerated by most patients
 Augment the effects of other antihypertensive agents
 Long acting hence once daily dosing
SAFETY OF
DIURETICS
This issue revolves around

A. Metabolic Side-effects
-Dyslipidemia
-Hyperuricemia
-Hyperglycemia

B. Arrhythmogenic Side-effects
-Hypokalemia

All these ADRs are dose-dependent and rarely seen with low doses
 ANTIHYPERTENSIVE DRUG CLASS
ACEI/ ARB
Angiotensinogen (Liver)

Renin (Kidney)
Angiotensin I
ACE (Angiotensin Converting Enzyme) ACEI

Angiotensin II
AT1 AT2 ( Role in CVS is not clear)
Receptors Receptors
Heart
Blood Vessels
Kidney
Adrenal gland ARB
Pituitary gland
Brain
 ANTIHYPERTENSIVE DRUG CLASS

ACEI ARB
Examples of ACE Inhibitors are: Examples of Angiotensin- II Receptor
Blockers:
 Ramipril
 Telmisartan
 Enalapril
 Losartan
 Lisinopril
 Olmesartan
 SIDE EFFECTS OF
ACE Inhibitors

 Cough - This is the most common side effect and occurs in 3 - 22%
of cases

 Hypotension - This is more common in patients with elderly and
those on diuretic therapy
CONTRAINDICATION OF
ARB

 Pregnancy

 Hyperkalaemia

 Bilateral Renal Artery Stenosis
 ANTIHYPERTENSIVE DRUG CLASS
Calcium Channel Blockers (CCB)
MECHANISM OF ACTION

Amlodipine inhibits the entry of calcium ions into the vascular
smooth muscle cells
(of heart & blood vessels)

By blocking the calcium channels

which leads to Vasodilation

in turn, reduction of B.P (Blood Pressure)
 EFFECTS OF
CCB
CCBs used as medications primarily have three effects:

By acting on vascular smooth muscle, they reduce contraction of the arteries
& cause an increase in arterial diameter, a phenomenon called vasodialation
(CCBs do not work on venous smooth muscle)

By acting on cardiac muscles (myocardium), they reduce the force of
contraction of the heart

By slowing down the conduction of electrical activity within the heart, they
slow down the heart beat
 EFFECTS OF
CCB
Since blood pressure is determined by cardiac output and
peripheral resistance, CCBs reduce blood pressure

With relatively low blood pressure, the after load on the heart
decreases; this decreases how hard the heart must work to
eject blood into the aorta, and so the amount of oxygen
required by the heart decreases accordingly

Reducing the force of contraction of the myocardium is known as the
negative inotropic effect of calcium channel blockers

This can help ameliorate symptoms of IHD such as Angina pectoris
 EXAMPLES OF
CCB

Dihydropyridines: E.g. Amlodipine, Nifedipine
More Vascular selective

Benzothiazepine: E.g. Diltiazem
It has both Vascular and Cardiac activity

Phenyalkylamine: E.g. Verapamil
More action on Cardiac tissue
 OTHER ANTIHYPERTENSIVE DRUGS
 Alpha-blockers, α-blockers, or α-adrenergic-antagonists act as receptor
antagonist of α-adrenoceptors

- Alpha-1 blocker or antagonist acts on Alpha-1 adrenoreceptors
- Alpha-1 blocker or antagonist acts on Alpha-2 adrenoreceptors

Examples of non-selective α-adrenergic blockers include:
 Phenoxybenzamine
 Tolazoline
Examples of Selective α1-adrenergic blockers include:
 Tamsulosin
 Prazosin
Examples of Selective α2-adrenergic blockers include:
 Atipamezole
 Idazoxan
 OTHER ANTIHYPERTENSIVE DRUGS

 Renin Inhibitors bind to the active site of renin and inhibit the binding of renin to
angiotensinogen, which is the rate-determining step of the RAAS cascade

Examples: Pepstatin(1st RI); Aliskerin

 Vasodilator agents act as blood vessel dilators (vasodilators) and open vessels by
relaxing their muscular walls

Examples: Nitroglycerine
 WHY
COMBINATIONS??
WHY COMBINATION THERAPY

Different Mode of More Flexible Dosing
Action Alternatives

Greater Efficacy of Less Adverse Effects
Combination agents (clinical or metabolic)
compared to separate if both components
components are in low dose

Better Patient
Compliance
WHY COMBINATION THERAPY
 The antihypertensive efficacy may be enhanced when two classes of agents
are combined

In addition, combination therapy enhances tolerability because one drug of
fixed combination can antagonize some of the adverse effects of the second
drug

 Fixed-dose combination therapy simplifies the treatment regimen, preventing
treatment failures that might result from missed doses

(Gonzalez Maqueda I et al, Rev Esp Cardiol. 1999;52 Suppl 3:59-72)
WHY COMBINATION THERAPY

JNC VII report as well as standard guidelines
also recommend the use of combinations in
stage II hypertension
BHS GUIDELINES