Download The Respiratory System

PSK4U
The Respiratory System
 Composed of structures
that allow:
 Passage of air from
outside the body to
the lungs
 Gas exchange to
occur
The Respiratory System
 Three main
functions:
1. Supply O2 to the
blood
2. Remove CO2 from
the blood
3. Regulate blood
pH (acid-base
balance)
The Respiratory System
 External Respiration
 Internal Respiration
 Cellular Respiration
 Divided into two
zones:
 Conductive zone
 Respiratory zone
Respiratory System Structure
Nasal cavity
Pharynx
Larynx
Right and left
primary bronchi
Secondary
bronchi
Tertiary bronchioles
Pulmonary venule
Pulmonary
arteriole
Mouth
Epiglottis
Trachea
Smooth muscle
Terminal bronchiole
Respiratory bronchiole
Alveolar sacs
Respiratory System Structure
The Conductive Zone
 The conductive zone is composed
of structures that transport air to
the lungs:
 Mouth and nose
 Larynx
 Trachea
 Primary and secondary
bronchi
 Tertiary and terminal
bronchioles
 Filters, warms and humidifies air
taken in with each breath
 Filtration by nasal hairs and
mucus membranes
 37oC and saturated
The Respiratory Zone
 The respiratory zone is
composed of structures
involved with the
exchange of gases
between inspired air and
blood:
 Respiratory
bronchioles
 Alveolar ducts
The Respiratory Zone
 Alveolar sacs (alveoli)
 Grape like structures
 Large surface area for
diffusion of gas into and
out blood
 Surrounded by
capillaries and elastic
fibers
 Walls are only one cell
thick
Mechanisms of Breathing
 Inspiration:
 Contraction of diaphragm

Stimulation from brain
 Thoracic cavity expands

Air pressure in thoracic cavity is lower than air pressure
outside the body
•Air rushes in to lungs to
restore balance
•Lung pressure =
atmospheric pressure
•Active process
•Require respiratory muscles
See diagram on page 250
Mechanisms of Breathing
 Expiration:
 Alveolar sacs recoil as diaphragm relaxes
 Air is expelled
 Thoracic cavity reduces
 Lung pressure>atmospheric pressure
 Passive
 Quiet breathing

Alveolar sacs recoil passively
 Active
 Forced Breathing


Muscles of the thoracic and abdominal cavity
contract actively
Decreasing the volume of the thoracic cavity and
increase pressure in lungs
Ventilation
 Ventilation (VE) is the volume
of air moved by the lungs in 1
minute
 Combination of inspiration and
expiration
 Influenced by two factors:
1. Tidal volume (V T)
Volume of air in each
breath
 At rest 0.5L/breath
 Exercise 3-4L/breath

Ventilation
2. Respiratory frequency (f)
 Number of
breaths
taken per minute
 At rest 12
breaths/minute
 Exercise 30-40 breaths
per minute
 VE = V T x f
Respiratory Control Centers
 Breathing is result of contraction and relaxation of
inspiratory and expiratory muscles
 Stimulate by CNS-special areas of brain and feedback loops
 Associated with overall need of O2, metabolic
processes, muscle activity and CO2 production
Respiratory Control Centers
 Respiratory control centres found within brain stem (not under conscious
control)
 Medulla oblongata

Inspiratory centre




Sends messages to respiratory muscles, diaphragm and external
intercostals-rhythmic pattern
15-20 breaths per minute at rest
During exercise the rate is increases do to feedback mechanism
Expiratory centre

Two main functions:
 Ensure the inspiratory muscles never completely relax
 Stimulate forceful expiration when required (during exercise)
Respiratory Control Centres
 Pons

Pneumotaxic and apneustic centres
Ensure smooth transition of inhalation to
exhalation
 Fine-tune the breathing pattern
 Other areas of brain can influence ventilation



Stimulation of skeletal muscle also leads to
stimulation of breathing control centres
Specialized sensory systems in order to
provide feedback to control centres
 For example monitor blood pH level
Lung Volumes
 Lung Volumes are divided into two categories:
 Static lung volumes
Determined by the actual structure of the lung
 Not influenced by breathing or flow of air
 Dynamic lung volumes
 Dependent on volume as well as movement/flow
of air

Static Lung Volume
 Three important static lung volumes:
1.
Total lung capacity (TLC)

Maximum volume of air that lungs can hold

Sum of vital capacity and residual volume
Static Lung Volume
 Three important static lung volumes:
2. Vital capacity (VC)

Maximum amount of air that can be exhaled
following a maximal inhalation

Measured using a Forced Vital Capacity (FVC)
Static Lung Volume
 Three important static lung volumes:
3. Residual volume (RV)

Air that remains in lungs following a maximal
exhalation
 TLC = VC + RV
Dynamic Lung Volume
 Tests that involve the measurement of the movement of air
by breathing
 Forced Expiratory Volume (FEV)
 Over 1 or 3 seconds of FVC
Dynamic Lung Volume
 Tests that involve the measurement of the movement of air
by breathing
 Maximal Voluntary Ventilation (MVV)
 Amount of air an individual can move over 15 seconds
 Inhale and exhale
 Multiply value to give value for 1 minute
Gas Exchange
 Diffusion mediates gas exchange
 Diffusion is the movement of a gas, liquid, or solid
from a region of high concentration to low
concentration
 Can only occur if a difference in concentration
exists
 Concentration gradient
Gas Exchange
 Concentration for specific
gases involved in respiration
are measured using partial
pressure
Fractional Concentrations and Partial Pressures of
Main Gasses Found in Air
Gas Exchange
 Diffusion pathway
 Area through which gases move from the lungs into
the blood; from the blood into the tissue, and back
 Rates of diffusion depend on:
 Size of concentration gradient


Increase gradient, increase rate
Governed by Henry’s Law


Thickness of barrier between two areas



Gas will dissolve into a liquid until equilibrium has been
reached
Decrease thickness, increase rate
Alveoli and capillary is only 2 cells thick
Surface area between two areas

Increase surface area, increase rate

Alveoli have large surface area, folded on top of another
Oxygen Transport
 Oxygen (O2) transport within the blood achieved in two
ways:
1. O2 dissolved within the plasma

Represents 2% of O2 found in the blood

0.05 mL O2/100 mL of blood
Oxygen Transport
 Oxygen (O2) transport within the blood achieved in two
ways: 2. Binds to Hemoglobin



1.34 mL of O2 for each gram of Hgb
16g Hgb/100 mL of blood
21.4 mL O2/100 mL blood
Oxygen Transport
 Amount of O2 that can be carried by Hgb is termed percent saturation
of hemoglobin

Sb%O
 Main factor that determine % saturation is PO2 within the
blood
Carbon Dioxide Transport
 Carbon dioxide (CO2)
 Moved from tissues back to lungs
 Moved into alveoli and then exhaled and removed from body
 Transport achieved in three ways:
 1. Trace amounts of CO2 dissolved within the plasma (5-
10%)
Carbon Dioxide Transport
 2. Binds to hemoglobin (20%)-binds to globin rather than
heme



Forming carbaminohemoglobin when [O2] is low, depends on PCO2
Once it arrives at the lungs the high [O2] stimulate the exchange
CO2 then diffuses into alveoli and is exhaled
Carbon Dioxide Transport
 Transport achieved in three ways:
 3. Bicarbonate system (70-75%)
 Chemical reaction with H2O in RBCs forming carbonic acid
(H2CO3)
 Carbonic anhydrase is enzyme responsible
 H2CO3
H+ + HCO3- where proton is carried by Hgb and
bicarbonate is in the plasma
 At lungs the process is reversed because the PCO2 reduced


H+ + HCO3H2CO3
CO2 + H2O
CO2 then diffuses from blood to alveoli to be exhaled
Carbon Dioxide Transport
 Transport achieved in three ways:
 3. Bicarbonate system (70-75%)
 At lungs the process is reversed because the PCO2 reduced


H+ + HCO3H2CO3
CO2 + H2O
CO2 then diffuses from blood to alveoli to be exhaled
Ventilation and Control of Blood pH
 Measure of how acidic or basic the blood is
 Usually maintain at 7.4
 Lactic acid release during exercise will result in a
decline in blood pH
 Due to increase in H+
Ventilation and Control of Blood pH
 Ventilation helps regulate the amount of H+ ions in
the blood
 Bicarbonate system

Increase in ventilation, expel extra amounts of CO2
 Cause H+ to combine with HCO3
 Lowers the H+ therefore increases the pH level back to
normal