Physiology of Respiratory System PDF

Summary

This document discusses the physiology of the human respiratory system. It provides information on lung volumes and capacities, gas laws, and gas exchange. The document is suitable for undergraduate students learning about human respiration.

Full Transcript

RNB10603
BASIC ANATOMY AND PHYSIOLOGY 1
RESPIRATORY SYSTEM
RESPIRATORY SYSTEM
RNB10603
 Learning Outcomes
At the end of this session, students should be
able to:
▪ describe the lung volumes and capacities of
respiratory system
▪ explain the pulmonary ventilation in respiratory
system
▪ explain the external and internal respiration
▪ describe the transport of respiratory gases
▪ explain the control of respiration
 Lung Volumes And Capacities

❑A healthy adult breath about 12 times a minute
with each inhalation and exhalation moving about
500 mL of air into and out of lungs
❑Measurement of lung volumes provides a tool for
understanding normal function of the lungs as well
as disease states
❑ In normal breathing at rest, approximately one-
tenth of the total lung capacity is used. Greater
amounts are used as needed (i.e., with exercise).
 Lung Volumes And Capacities
The following terms are used to describe lung
volumes :
❑Tidal volume (TV)
❑Inspiratory reserve volume (IRV)
Volume
❑Expiratory reserve volume (ERV)
❑Residual volume (RV)
❑Total Lung Capacity(TLC)
❑Vital capacity (VC). Capacity
❑Functional residual capacity (FRC)
❑Inspiratory capacity (IC)
Lung Volumes And
Capacities
❑Tidal Volume (TV)
❖The amount
of gas inspired
or expired with
each normal
breath.
❖About 500 ml
Lung Volumes And
Capacities
❑Inspiratory
Reserve Volume
(IRV)
❖ Maximum
amount of
additional air
that can be
inspired from
the end of a
normal
inspiration
Lung Volumes And
Capacities
❑Expiratory
Reserve Volume
(ERV)
❖The maximum
volume of
additional air
that can be
expired from
the end of a
normal
expiration.
Lung Volumes And
Capacities
❑Residual Volume
(RV)
❖The volume of
air remaining in
the lung after a
maximal
expiration.
Lung Volumes And
Capacities
❑Total Lung Capacity(TLC)

❖The volume of air
contained in the lungs at
the end of a maximal
inspiration.
❖Called a capacity
because it is the sum of
the 4 basic lung volumes
❖TLC= RV+IRV+TV+ERV
Lung Volumes And
Capacities
❑Vital Capacity (VC)
❖The maximum volume
of air that can be
forcefully expelled from
the lungs following a
maximal inspiration.
❖Called a capacity
because it is the sum of
inspiratory reserve
volume, tidal volume
and expiratory reserve
volume.
❖VC= IRV+TV+ERV = TLC
- RV
Lung Volumes And
Capacities
❑Functional residual
capacity (FRC)

❖The volume of air
remaining in the lung at
the end of a normal
expiration.
❖Called a capacity
because it equal
residual volume plus
expiratory reserve
volume.
❖FRC= RV+ERV
Lung Volumes And
Capacities
❑Inspiratory Capacity (IC)
❖Maximum volume of air
that can be inspired from
end expiratory position.
❖Called a capacity because
it is the sum of tidal
volume and inspiratory
reserve volume.
❖This capacity is of less
clinical significance than
the other three.
❖IC= TV+IRV
Lung Volumes And Capacities
 Understanding Gases
To understand how this mechanical coupling
between the lungs, the pleural cavities and the
chest wall results in breathing, we first need to
discuss some physics of gases called the
gas laws.
 Understanding Gases
The respiratory system depends on the medium of
the earth’s atmosphere to extract the oxygen
necessary for life.
The atmosphere is composed of these gases:
– Nitrogen (N2) 78%
– Oxygen (O2) 21%
– Carbon Dioxide (CO2) 0.04%
– Water Vapor variable, but on average
around 1%
 Understanding Gases
Gases obey laws of physics called the gas laws.
– These laws apply equally to the gases of the
atmosphere, the gases in our lungs, the gases dissolved
in the blood, and the gases diffusing into and out of the
cells of our body.
– To understand the mechanics of ventilation and
respiration, we need to have a basic understanding of 4
common gas laws.
 Understanding Gases
Boyle’s law applies to containers with flexible walls
– like our thoracic cage.
– It says that volume and pressure are inversely related.
If there is a decrease in volume – there will be an increase in
pressure.
V ∝ 1/P
 Understanding Gases
❑Henry's law: quantity of gas that will dissolve in a
liquid is proportional to the partial pressure of the
gas and its solubility

❑Charles' law: as temperature increases the pressure
increases therefore as temperature decreases the
pressure decreases

❑Dalton's law: each gas in a mixture of gases exerts
its own pressure as if no other gases were present.
 Gases Exchange
Gas Exchange
 Understanding Gases
❑Gas will always move from a region of high pressure
to a region of low pressure. Applying Boyle's law: If
the volume inside the thoracic cavity , the
pressure .
 Pulmonary Ventilation
Mechanics of Breathing
What is breathing / ventilation?
A process of moving air in and out
of the lungs
There are 2 phases:
i) Inspiration/inhalation –air in to lungs
ii) Expiration/exhalation – air out of lungs
Air movement is due to changes in the volume of
the thorax, which influence the air pressure in the
lungs
 Pulmonary Ventilation
❑Cycle of Breathing
3 phases are involved:
▪ inspiration
▪ expiration
▪ pause
 Ventilation and Respiration
Pulmonary ventilation is the movement of air
between the atmosphere and the alveoli, and
consists of inhalation and exhalation.
– Ventilation, or
breathing, is made
possible by changes
in the intrathoracic
volume.
 Pulmonary Ventilation
❑ Inspiration / Inhalation
External intercostals muscles contract during inspiration
Diaphragm contracts (downwards and flattens)
This pulls the rib cage upwards and outwards
These actions cause the thoracic cavity size to increase
This decreases the pressure inside the thoracic cavity
Gases move from areas of high pressure to low pressure
areas
Therefore oxygen moves from the atmosphere (higher
pressure) into the lungs (now low in pressure)
During exercise, a more forceful inspiration is required so
extra muscles are involved in this process –
sternocleidomastoid and pectoralis minor
 Pulmonary Ventilation
❑ Expiration/ Exhalation
Usually a passive process
As the intercostals muscles relax the rib cage moves
downwards
The diaphragm relaxes and returns to its dome shape
This decreases the size of the thoracic cavity
This causes the pressure to increase in the thoracic cavity
(smaller volume)
Therefore gases move out of the lungs (high pressure) into
the atmosphere (lower pressure)
During exercise breathing rate is increased, expiration is aided
by the internal intercostal muscles and the abdominal
muscles,
This pulls the rib cage down more quickly and with greater
force
 Pulmonary Ventilation
Inpiration Expiration
Pulmonary Ventilation
 Pulmonary Ventilation
❑Muscles of Respiration
❖Inspiratory muscles
– Diaphragm.
– External intercostals.
– Accessory muscles.
Include
sternomastoids,
scalene muscles
❖Expiratory muscles
– Abdominal muscles.
– Internal
intercostals.
 Pulmonary Respiration
Also called external respiration
Exchange of oxygen (O2) and carbon dioxide
(CO2) between the alveoli of the lungs and
pulmonary blood capillaries
Deoxygenated blood from the heart is
converted into oxygenated blood returning to
the heart
 Pulmonary Respiration
❑External Respiration
Pulmonary Respiration
Gas Exchange During Respiration 35
 Tissue Respiration
Also called internal respiration

Exchange of oxygen (O2) and carbon dioxide (CO2)
between blood in the capillaries and the body cells.

Blood arriving at the tissues has been cleansed of
its CO2 and saturated with O2
Tissue Respiration
Pulmonary And Tissue
Respiration
Pulmonary And Tissue
Respiration
Movement of Oxygen and Carbon Dioxide 40
 Transport Of Respiratory Gases
❑Blood transport gases between lung and body
tissue
❑Oxygen and carbon dioxide in the blood will have
physical and chemical changes throughout the
transport and exchange.
 Transport Of Respiratory Gases
❑Oxygen Transport
Molecular oxygen is carried in the blood:
❖Bound to hemoglobin (Hb) within red blood cells
(98.5%)
❖Dissolved in plasma(1.5%)
 Transport Of Respiratory Gases
❑Oxygen Transport
Each Hb molecule binds four oxygen atoms in a
rapid and reversible process
The hemoglobin-oxygen combination is called
oxyhemoglobin (HbO2)
Hemoglobin that has released oxygen is called
reduced hemoglobin (HHb)
Lungs
HHb + O2 HbO2 + H+
Tissues
 Transport Of Respiratory Gases
❑Oxygen Transport
When blood Po₂ is high, hemoglobin binds with
large amount of O₂ and it is saturated
When blood Po₂ is low, hemoglobin releases O₂
Systemic capillaries has low Po₂
Hemoglobin release oxygen
Oxygen diffuse from blood plasma to interstitial
fluid and to tissue cells
 Transport Of Respiratory Gases
❑Other factors influence the amount of oxygen
release by hemoglobin
Carbon dioxide
❖Pco₂ rises in any tissue ,hemoglogin release more
O₂ into the blood flow (muscular tissues during
exercise )
Acidity
❖Acidic environment ,hemoglobin release more O₂
into the blood flow. During exercise ,muscles
produce lactic acid which promote release of O₂
 Transport Of Respiratory Gases
❑Other factors influence the amount of oxygen
release by hemoglobin
Temperature
❖Temperature increase the release of O₂ from
hemoglobin.Active tissues produce more heat,
which elevates the local temperature and promotes
release of O₂
 Transport Of Respiratory Gases
❑Carbon Dioxide Transport
Carbon dioxide is transported in the blood in three
forms
❖Dissolved in plasma – 7 to 10%
❖Chemically bound to hemoglobin – 20% is carried in
RBCs as carbaminohemoglobin
❖Bicarbonate ion in plasma – 70% is transported as
bicarbonate (HCO3–)

+ -
CO2 + H2O H2CO3 H + HCO3
 Transport Of Respiratory Gases
❑Carbon Dioxide Transport
Carbon dioxide diffuses into RBCs and combines
with water to form carbonic acid (H2CO3), which
quickly dissociates into hydrogen ions and
bicarbonate ions
CO2 + H2O  H2CO3  H+ + HCO3–
Carbon Carbonic Hydrogen Bicarbonate
Water
dioxide acid ion ion

In RBCs, carbonic anhydrase reversibly catalyzes the
conversion of carbon dioxide and water to carbonic
acid
Transport and Exchange of Carbon Dioxide
 Transport Of Respiratory Gasses
❑Carbon Dioxide Transport
At the tissues:
❖Bicarbonate quickly diffuses from RBCs into the
plasma
❖The chloride shift – to counterbalance the
outrush of negative bicarbonate ions from the
RBCs, chloride ions (Cl–) move from the plasma
into the erythrocytes
 Transport Of Respiratory Gasses
❑Carbon Dioxide Transport
At the lungs, these processes are reversed
❖Bicarbonate ions move into the RBCs and bind
with hydrogen ions to form carbonic acid
❖Carbonic acid is then split by carbonic anhydrase
to release carbon dioxide and water
❖Carbon dioxide then diffuses from the blood into
the alveoli
Transport and Exchange of Carbon Dioxide
 Control of Respiration
❑Regulation of breathing
Voluntary
– Somatic motor neurons controlled by centers in
medulla oblongata and pons
Involuntary
– Feedback from receptors that detect changes in
blood chemistry
Control of Respiration
 Control of Respiration
The medulla rhythmicity area, located in the
brainstem, has centers that control basic
respiratory patterns for both inspiration and
expiration.
– The inspiratory center

stimulates the diaphragm

via the phrenic nerve, and

the external intercostal nerve
 Control of Respiration
Exhalation is mostly a passive process, caused
by the elastic recoil of the lungs. Usually, the
expiratory center is inactive during quiet
breathing (nerve impulses cease for about 3
sec).
– During forced exhalation,
however, impulses from this
center stimulate the internal
intercostal and abdominal
muscles to contract.
 Control of Respiration
❑Medullary Rhythmicity Area
❖Medullary Inspiratory Neurons are main control
of breathing
Pons neurons influence inspiration, with
Pneumotaxic area limiting inspiration and
Apneustic area prolonging inspiration.
The apneustic center in the pons increases the
depth and duration of inspiration, whereas the
pneumotaxic center decreases depth and
duration.
Lung stretch receptors limit inspiration from being
too deep
 Control of Respiration
Groups of neurons in the brainstem comprise the
respiratory areas that control breathing
Impulses travel on cranial nerves and spinal nerves,
causing inspiration and expiration
Respiratory area also adjust the rate and depth of
breathing
The respiratory areas include
❖respiratory center of the medulla
❖respiratory group of the pons
 Control of Respiration
Medullary Respiratory Center
❑The dorsal respiratory group (DRG), or inspiratory
center:
❖Is located near the root of nerve IX
❖Appears to be the pacesetting respiratory center
❖Excites the inspiratory muscles and sets eupnea (12-15
breaths/minute)
❖Becomes dormant during expiration
❑The ventral respiratory group (VRG) is involved in
forced inspiration and expiration
 Control of Respiration
Pon Respiratory Centers
❑Pons centers:
❖Influence and modify activity of the medullary centers
❖Smooth out inspiration and expiration transitions and
vice versa
❑The pontine respiratory group (PRG) – continuously
inhibits the inspiration center
Control of Respiration
 Control of Respiration
Medullary Respiratory Center
 Control of Respiration
Respiratory Rhythm
❑A result of reciprocal inhibition of the
interconnected neuronal networks in the medulla
❑Other theories include
❖Inspiratory neurons are pacemakers and have intrinsic
automaticity and rhythmicity
❖Stretch receptors in the lungs establish respiratory
rhythm
 Control of Respiration
Depth and Rate of Breathing
Inspiratory depth is determined by how
actively the respiratory center stimulates the
respiratory muscles
Rate of respiration is determined by how long
the inspiratory center is active
Respiratory centers in the pons and medulla
are sensitive to both excitatory and inhibitory
stimuli
 Control of Respiration
Depth and Rate of Breathing :Reflexes
Pulmonary irritant reflexes – irritants promote
reflexive constriction of air passages
Inflation reflex (Hering-Breuer) – stretch
receptors in the lungs are stimulated by lung
inflation
Upon inflation, inhibitory signals are sent to
the medullary inspiration center to end
inhalation and allow expiration
 Control of Respiration
Medullary Respiratory Center
Control of Respiration
 Control of Respiration
Depth and Rate of Breathing :Higher Brain
Center
Hypothalamic controls act through the limbic
system to modify rate and depth of respiration
Example: breath holding that occurs in anger
A rise in body temperature acts to increase
respiratory rate
Cortical controls are direct signals from the cerebral
motor cortex that bypass medullary controls
Examples: voluntary breath holding, taking a deep
breath
 Control of Respiration
Depth and Rate of Breathing :Pco₂
Changing PCO2 levels are monitored by
chemoreceptors of the brain stem
Carbon dioxide in the blood diffuses into the
cerebrospinal fluid where it is hydrated
Resulting carbonic acid dissociates, releasing
hydrogen ions( Respiratory Acidosis)
PCO2 levels rise (hypercapnia) resulting in
increased depth and rate of breathing
 Control of Respiration
Depth and Rate of Breathing :Pco₂
Hyperventilation – increased depth and rate of
breathing that:
❖Quickly flushes carbon dioxide from the blood
❖Occurs in response to hypercapnia
 Control of Respiration
Depth and Rate of Breathing :Pco₂
Arterial oxygen levels are monitored by the
aortic and carotid bodies
Substantial drops in arterial PO2 (to 60 mm Hg)
are needed before oxygen levels become a
major stimulus for increased ventilation
 Control of Respiration
Depth and Rate of Breathing :Pco₂
 Control of Respiration
Depth and Rate of Breathing :Arterial pH
Changes in arterial pH can modify respiratory
rate even if carbon dioxide and oxygen levels
are normal
Increased ventilation in response to falling pH
is mediated by peripheral chemoreceptors
 Control of Respiration
Depth and Rate of Breathing :Arterial pH ( pH )
 Control of Respiration
Depth and Rate of Breathing :Arterial pH and
Pco₂
Control of Respiration