Download Respiratory Physiology Anatomy of the Respiratory System

11/8/12
Respiratory Physiology
Cellular Respiration
Pulmonary ventilation
(breathing)
Gas exchange between
lungs and blood
Transportation of gases
in blood
Gas exchange between
blood and body tissues
Anatomy of the Respiratory System
Conducting airways
(Nasal passages, pharynx,
trachea, bronchii,
bronchioles)
Inspired air is warmed and
humidified in these tubes.
Moistening of air is essential
to prevent drying out of
alveolar linings.
Photomicrograph of Tracheal Epithelium
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Defence mechanisms
Respiratory system is largest area of the body in
direct contact with the environment.
Large particles filtered out in hairs in nasal passages
Respiratory airways lined with mucus to trap foreign
objects
Cilia move mucus upwards towards throat to be
swallowed
Coughs and sneezes
Alveolar macrophages scavenge within the alveoli
Function of the alveoli
Exchange of gases between air and blood by diffusion
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Alveoli
Site of gas exchange
300 million alveoli/lung (tennis court size)
Rich blood supply- capillaries form sheet
over alveoli
Alveolar pores
Type I alveolar cells – make up wall of alveoli
Single layer epithelial cells
Type II alveolar cells – secrete surfactant
Alveolar macrophages
Resin cast of pulmonary
blood vessels
Scanning electron
micrograph of capillaries
around alveoli
Pulmonary Circulation is low-pressure, low-resistance
Ventilation-perfusion matching: blood flow through the pulmonary
circulation is matched to ventilation
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Structures of the Thoracic Cavity
Chest wall – air tight, protects lungs
Skeleton: rib cage;sternum; thoracic vertebrae
Muscles: internal/external intercostals; diaphragm
Lungs are surrounded by pleural sac
Role of Pressure in pulmonary ventilation
Air moves in and out of lungs by bulk flow
Pressure gradient drives flow (air moves from high to low
pressure)
Atmospheric pressure = Patm (760mmHg at sea level)
Intra-alveolar pressure = Palv
Pressure of air in alveoli
During inspiration = negative (less than
atmospheric)
During expiration = positive (more than
atmospheric)
Difference between Palv and Patm drives ventilation
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Atmospheric Pressure
760 mm Hg at sea level
Decreases as altitude increases
Increases under water
Other lung pressures given relative to atmospheric (set Patm = 0 mm Hg)
Intrapleural Pressure
Pressure inside pleural sac
Always negative under normal conditions
Always less than Palv
Varies with phase of respiration
At rest, -4 mm Hg
Negative pressure due to elasticity in lungs and chest wall
Lungs recoil inward
Chest wall recoils outward
Opposing pulls on intrapleural space
Surface tension of intrapleural fluid holds wall and lungs
together
Pneumothorax
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Mechanics of Breathing
Movement of air in and out of lungs due to pressure gradients
Mechanics of breathing describes mechanisms for creating pressure
gradients
Boyle’s Law (pressure and volume are inversely related)
The lungs follow the movement of the rib cage
Forces for Air Flow
Flow =
Patm – Palv
R
Force for flow = pressure gradient
Atmospheric pressure constant (during breathing cycle)
Therefore, changes in alveolar pressure creates/changes gradients
Muscles of Respiration
Inspiratory muscles increase volume of thoracic cavity
•  Diaphragm & external intercostals
Expiratory muscles decrease volume of thoracic cavity
•  Internal intercostals & abdominal muscles
Expiration is generally passive (no muscles required): elastic recoil
Active expiration requires expiratory muscles
•  Contraction of expiratory muscles creates greater and faster
decrease in volume of thoracic cavity
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Inspiration and Expiration
Figure 17.11b
Factors affecting ventilation
Compliance
Airway resistance
Lung Compliance:
Ease with which lungs can be stretched
Larger lung compliance, easier to inspire
Factors Affecting Lung Compliance:
Elasticity
Less elastic: less compliant
Surface tension of lungs
Greater tension: less compliant
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Surface Tension in Lungs
Thin layer of fluid lines alveoli
Surface tension due to attractions between water molecules
Force for alveoli to collapse or resist expansion
To Overcome Surface Tension
Surfactant secreted from type II cells
Surfactant: detergent that decreases surface tension
Surfactant increases lung compliance
Makes inspiration easier
Physiology Research Focus: the developing lung
& ageing
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Airway Resistance
Like blood vessels, the resistance of the airways affects air flow
Airway radius affects airway resistance
Disease states:
Asthma – caused by spasmic contractions of smooth muscle of bronchioles.
Histamine is a bronchoconstrictor
Chronic obstructive pulmonary diseases – COPD
Extrinsic control
Autonomic nervous system
Sympathetic
Relaxation of smooth muscle
Bronchodilation
Parasympathetic
Contraction of smooth muscle
Bronchoconstriction
Hormonal Control
Adrenaline
Relaxation of smooth muscle
Bronchodilation
Physiology Research Focus: respiratory disease
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