Blood Pressure and Its Control
Introduction
Blood pressure (BP) is one of the most important physiological parameters
of the cardiovascular system. It represents the force exerted by circulating
blood on the walls of blood vessels, especially arteries.
Proper maintenance of blood pressure is essential because:
- It ensures adequate blood flow to
tissues.
- It maintains oxygen and nutrient
delivery.
- It removes metabolic wastes.
- It preserves normal organ
function.
Abnormal blood pressure may lead to:
- Hypertension
- Shock
- Stroke
- Heart failure
- Kidney disease
According to standard physiology references, arterial blood pressure
depends mainly on:
- Cardiac output (CO)
- Peripheral resistance (PR)
Definition Of Blood Pressure
Blood pressure is defined as: “The lateral pressure exerted by blood
on the walls of arteries during its flow.”
It is measured in: millimeters of mercury (mmHg)
Types of Blood Pressure
1. Systolic Blood Pressure (SBP)
- Maximum pressure during
ventricular systole (heart contraction).
- Produced when the left ventricle
ejects blood into the aorta.
Normal Value: Approximately 120 mmHg
2. Diastolic Blood Pressure (DBP)
- Minimum arterial pressure during
ventricular diastole (heart relaxation).
Normal Value: Approximately 80 mmHg
Thus, normal BP is written as: 120/80 mmHg
Pulse Pressure
Definition
Difference between systolic and diastolic pressure.
Pulse Pressure=SBP−DBP
Normal Value: About 40 mmHg
Increased In
- Exercise
- Hyperthyroidism
- Aortic regurgitation
Decreased In
- Shock
- Heart failure
Mean Arterial Pressure (Map)
Definition
Average pressure in arteries during one cardiac cycle.
It is the best indicator of tissue perfusion.
MAP = DBP + 
(SBP-DBP)
Normal Value: About 93 mmHg
Determinants of Blood Pressure
Arterial BP mainly depends on:
BP=Cardiac Output × Peripheral Resistance
Where:
Cardiac Output (CO)
Amount of blood pumped by heart per minute.
CO=Heart Rate × Stroke Volume
Peripheral Resistance (PR)
Resistance offered by blood vessels to blood flow
Factors Affecting Blood Pressure
1. Age- BP increases with age due to arterial stiffness.
2. Gender- Adult males usually have slightly higher BP than females. After
menopause, females may develop higher BP.
3. Exercise- Systolic BP increases during exercise.
4. Emotion- Fear, anxiety, stress increase BP through sympathetic activation.
5. Sleep- BP decreases during sleep.
6. Posture- Standing suddenly may transiently lower BP.
7. Obesity- Increases peripheral resistance and cardiac workload.
8. Diet- Excess salt intake raises BP.
Physiological Variations of Blood Pressure
|
Condition |
Effect on BP |
|
Exercise |
↑ Systolic BP |
|
Sleep |
↓ BP |
|
Fear/Stress |
↑ BP |
|
Hemorrhage |
↓ BP |
|
Standing suddenly |
Temporary ↓ BP |
Methods of Measuring Blood Pressure
1. Direct Method
- Cannula inserted into artery.
- Connected to manometer.
- Very accurate.
- Used in ICUs and research.
2. Indirect Method
Most common clinical method.
Instrument- Sphygmomanometer
Principle- Based on Korotkoff sounds.
These are sounds heard during BP measurement.
Phases
|
Phase |
Sound |
Significance |
|
Phase I |
Clear tapping |
Systolic BP |
|
Phase II |
Murmur |
Turbulent flow |
|
Phase III |
Loud sounds |
Increased flow |
|
Phase IV |
Muffling |
Transition |
|
Phase V |
Disappearance |
Diastolic BP |
Regulation (Control) of Blood Pressure
BP is maintained by:
- Short-term mechanisms
- Intermediate mechanisms
- Long-term mechanisms
Short-Term Regulation of Blood Pressure
Acts within seconds to minutes, mainly neural mechanisms.
Definition
Baroreceptors are stretch receptors present in arterial walls.
Location
- Carotid sinus
- Aortic arch
Afferent Nerves
|
Receptor |
Nerve |
|
Carotid sinus |
Glossopharyngeal nerve (CN IX) |
|
Aortic arch |
Vagus nerve (CN X) |
Mechanism
When BP Increases
- Stretch of baroreceptors
increases.
- Increased impulses sent to
medulla.
- Cardioinhibitory center
stimulated.
- Vasomotor center inhibited.
- Heart rate decreases.
- Vasodilation occurs.
- BP decreases back to normal.
When BP Decreases
- Reduced receptor firing.
- Sympathetic activity increases.
- Heart rate and vasoconstriction
increase.
- BP rises.
Importance of Baroreceptor Reflex
- Prevents sudden fluctuations in
BP.
- Important during:
- Change in posture
- Exercise
- Hemorrhage
2. Chemoreceptor Mechanism
Chemoreceptors Located In
- Carotid bodies
- Aortic bodies
Stimulated By
- ↓ Oxygen
- ↑ Carbon dioxide
- ↑ Hydrogen ions
Effect
- Stimulates vasomotor center.
- Causes vasoconstriction.
- Raises BP.
3. CNS Ischemic Response
Trigger- Severe fall in cerebral blood flow.
Mechanism
- Brain ischemia stimulates
medullary vasomotor center.
- Massive sympathetic discharge
occurs.
Effects
- Intense vasoconstriction
- Increased heart activity
- Rise in BP
Importance
Emergency mechanism during severe hypotension.
Intermediate Regulation of Blood Pressure
Acts within minutes to hours
Mechanisms:
- Capillary fluid shift
- Stress relaxation of vessels
- Hormonal mechanisms
Capillary Fluid Shift Mechanism
When BP Falls
- Fluid moves from tissues into
blood vessels.
- Blood volume increases.
- BP rises.
When BP Rises
- Fluid moves out of capillaries.
- BP falls.
Stress Relaxation Mechanism
Blood vessels can stretch gradually.
If BP Rises
- Vessels dilate slowly.
- Pressure decreases.
If BP Falls
- Vessels constrict.
- Pressure increases.
Long-Term Regulation of Blood Pressure
Mainly controlled by kidneys.
Acts over hours to days
Most important for permanent BP regulation.
Renal Regulation of Blood Pressure
Kidneys regulate:
- Blood volume
- Sodium balance
These directly affect BP.
Renin–Angiotensin–Aldosterone System (RAAS)
One of the most important BP control systems.
Steps of RAAS
Step 1: Renin Release
Released from juxtaglomerular cells of kidney when:
- Renal blood flow decreases
- BP falls
- Sodium decreases
Step 2: Formation of Angiotensin I
Renin converts:
- Angiotensinogen → Angiotensin I
Step 3: Formation of Angiotensin II
Angiotensin Converting Enzyme (ACE mainly in lungs) converts:
- Angiotensin I → Angiotensin II
Actions of Angiotensin II
1. Vasoconstriction
- Increases peripheral resistance.
2. Aldosterone Secretion
- Increases sodium and water
reabsorption.
3. ADH Release
- Water retention increases.
4. Thirst Stimulation
- Water intake increases.
Overall effect: BP increases
Antidiuretic Hormone (ADH)
Also called: Vasopressin
Secreted By- Posterior pituitary.
Stimulated By
- Decreased BP
- Increased plasma osmolarity
Actions
- Water reabsorption in kidneys
- Vasoconstriction
Result: Increased BP
Atrial Natriuretic Peptide (ANP)
Secreted By- Atrial muscle fibers.
Released When- Atria are stretched due to increased blood volume.
Actions
- Increases sodium excretion.
- Increases water loss.
- Causes vasodilation.
Result: BP decreases
Role of Autonomic Nervous System
Sympathetic Nervous System
Effects
- Increases heart rate
- Increases force of contraction
- Causes vasoconstriction
Result
↑ BP
Parasympathetic Nervous System
Effects
- Slows heart rate
Result
↓ BP
Role Of Blood Vessels in BP Control
Vasoconstriction
- Increases resistance
- Raises BP
Vasodilation
- Decreases resistance
- Lowers BP
Hypertension
Definition
Persistent elevation of BP above normal.
Common Criterion- ≥140/90 mmHg (traditional definition)
Types of Hypertension
1. Primary (Essential) Hypertension
- No identifiable cause.
- Most common type.
2. Secondary Hypertension
Due to:
- Kidney disease
- Endocrine disorders
- Tumors
- Drugs
Complications Of Hypertension
- Stroke
- Heart attack
- Kidney failure
- Retinal damage
- Heart failure
Hypotension
Definition
Low blood pressure. Usually: Less than 90/60 mmHg
Causes of Hypotension
- Hemorrhage
- Dehydration
- Shock
- Cardiac failure
Definition
Fall in BP on standing suddenly. Due to: Pooling of blood in lower limbs.
Normally prevented by: Baroreceptor reflex.
Shock and Blood Pressure
Shock
Failure of circulation leading to inadequate tissue perfusion.
Types
- Hypovolemic
- Cardiogenic
- Septic
- Neurogenic
Common Feature
- Severe hypotension
IMPORTANT NEET POINTS
Very Important Values
|
Parameter |
Normal Value |
|
Systolic BP |
120 mmHg |
|
Diastolic BP |
80 mmHg |
|
Pulse Pressure |
40 mmHg |
|
Mean Arterial Pressure |
93 mmHg |
HIGH-YIELD FACTS
- Baroreceptors are stretch
receptors.
- Carotid sinus nerve travels
through glossopharyngeal nerve.
- Aortic arch receptor signals
travel via vagus nerve.
- RAAS is important in long-term BP
control.
- Angiotensin II is a powerful
vasoconstrictor.
- Aldosterone increases sodium
reabsorption.
- ADH increases water retention.
- ANP lowers BP.
- Sympathetic stimulation increases
BP.
- Kidneys are the most important
long-term regulators of BP.
FLOWCHART:
Fall in BP
↓
↓ Baroreceptor firing
↓
↑ Sympathetic activity
↓
↑ Heart rate + Vasoconstriction
↓
↑ BP
Simultaneously
↓ Renal perfusion
↓
Renin release
↓
Angiotensin II formation
↓
Vasoconstriction + Aldosterone
secretion
↓
↑ Blood volume
↓
↑ BP
SUMMARY
Blood pressure is the force exerted by blood on arterial walls. It
depends mainly on cardiac output and peripheral resistance. BP is maintained by
neural, hormonal, and renal mechanisms. Short-term control occurs through
baroreceptors and autonomic reflexes, while long-term regulation is primarily
achieved by kidneys through the RAAS and fluid balance mechanisms. Proper
regulation is essential for maintaining adequate tissue perfusion and overall
body homeostasis.