Respiratory Pathophysiology PDF

Summary

This document provides an overview of respiratory pathophysiology, including respiratory failure, its types (acute and chronic), and related disorders like pulmonary fibrosis and pneumoconiosis. It also details the manifestations, causes, and mechanisms of various respiratory conditions.

Full Transcript

Pathophysiology of the respiratory system

primary → Disorder in external respiration
Respiratory failure
secondary → Pathologies of blood, cardiovascular sys,
and other systems

RF results

Hypoxemic Hypercapnic

Manifested by:
Damage to lung Parenchyma Airway obstruction
Impaired alveolar diffusion Hypoventilation

Chronic form is called Dyspnea Cyanosis

Types of RF

Acute Chronic
Bronchial asthma attack Pulmonary fibrosis
Pneumothorax Pneumoconiosis
Asphyxia

Acute RF hypoxemic type Acute RF hypercapnic type

Hyperventilation Respiratory alkalosis Hypoventilation Respiratory acidosis

Chronic RF
Slow compensatory mechanism Hyperventaliation

To Prevent hypoxemia, hypocapnia does not occur by the time compensatory

depletion, myocardial hypertrophy occur Metabolic acidosis
 Rf degrees
1st 2nd 3rd
Pa02 > 70 mmHg Pa02 70-50 mmHg Pa02 less than 50 mmHg

Dyspnea develops in Dyspnea in Dyspnea and cyanosis
physical activity light Physical in rest
(mild to moderate) work organs are in deep hypoxia

Normal Pa02 is 96-98 mmHg

Components of external respiration

Lung ventilation Alveolar diffusion

Disorders of Pulmonary ventilation:

Alveloar hyperventaliation

occurs due to hypoxemia
Hypocapnia and gaseous alkalosis occur
decrease calcium ionization
Hypocalcemia
Hypocapnia will cause spasm of cerebral vesseles can also cause hypotension indirectly

Hypocalcemia will cause Arrhythmia, hypotension

oxygen curve shift to the left
 Alveolar hypoventaliation
Hypoxemia, hypercapain, gaseous acidosis develop
oxygen curve shift to the right

causes of alveolar hypoventilation

Reduced the excitability of the respiratory center

reduce Partial Pressure of Co2 in arterial blood, alkalosis, BP Hypoventilation

Infants hypoventaliation underdevelopment of Peripheral chemoreceptors and weakness

of exciting afferent influences

Damage to the respiratory muscle and their nerves

Inflammation (Botulism, tetanus) affecting Innervation of respiratory muscles, Autoimmune

(myasthenia gravis), dystrophic changes (collagenosis), cramps (tetany, epilepsy)

Damage to the Phrenic nerve will cause Paradoxical breathing

accompined by an asymmetry movements of the right and left halves of the chest

called breathing dissociation (Grocco-frugoni breathing)

Thoraco diaphragmatic Pathology:

Diseases accompanid by restricting chest and diaphragm movements include

Congenital defect of the skeletal cartilaginous apparatus of the chest, Rickets,Kyphosis, lordosis, scoliosis....

Bronchi and lung disease:

observed in chronic bronchitis, bronchial asthma, Pneumonia, tuberculosis.....

Uneven lung ventilation
Combination of

Emphysema Impaired bronchial obstruction Exudate formation in
(eg. asthma) alveoli
(decrease elasticity
(e.g. Pneumonia)
of alveoli)
 Types of hypoventilation

Obstructive Restrictive
Upper tract Lower tract
Pulmonary Extra Pulmonary
Fluids (water, sputum) Pathologies affect lower tract
Tumor tissues (asthma) Pneumonia Pleural Pathology (pleurisy, pneumo,
hydro, hemothorax)

Inspiration difficulty Expiration difficulty TB Diaphragm mobility damage
Tumors
Inspiratory dyspnea Expiration dyspnea (Phernic nerve....)

resection of lung tissue Respiratory muscle disorders
(myositis....)
Pulmonary edema
Chest excursion difficulties
Pneumosclerosis (kyphosis, lordosis....)

Atelectasis

Inspiratory dyspnea
Hypoxemia, Hypercapnia, Gas acidosis, Hypoxia
cerebral edema

Hypoventilation will cause

Decrease Partia Pressure Increase Pulmonary Pulmonary edema
of O2 in the alveolar air Vessels tone reflex
(Euler-Lillestrand
reflex)

Causes of Restrictive type of alveolar ventaliation:
Atelectasis
Pneumothorax
Pneumonia
 Disorders of obstructive hypoventilation
Chronic bronchitis:
Result due to Prolonged regular irritation of the mucous membrane of the
respiratory tract
Affect upper respiratory tract
obstruction is at the level of Trachea, bronchi, bronchioles
wall deformation occur
Extension occur (bronchiectasis)
by the time Emphysema occur

Bronchiectasis:
Dependent disease
Expansion of the lumen of bronchi or bronchioles
Two main factors
chronic Persistance of the respiratory tract infection
obstruction in a certain Part of the bronchi/bronchioles

Hyperemia, mucous hyper secretion occur
Asthma:
characterized by Broncho spasm, airway obstruction and Expiratory dyspnea
eg. narrowing bronchial lumen 2 times Increase resistance 16 times (Poissel's law)

Hereditary Predisposition allergic components stimulate the Pathogenesis
Types of astma 1

Atopic Non-atopic
Type I hypersensitivity reaction Allergic (Immune) mechanism is not involved

Hereditary Predisposition No hereditary predisposition

related to allergic disease Normal IgE synthesis,
e.g atopic dermatitis, urticaria
High eosinophils synthesis
Childhood
Bronchial epithelium damage,

Increase mucus secretion
broncial muscle layer wall hypertrophies

Develop due to hyperergic inflammatory
reaction

chronic irretation decrease irretation

threshold of subepithelial parasympathetic
receptors
 Types of asthma 2

Infections Non-infections

Can associate with allergic, Psedo-allergic, non-allergic
e.g. aspirin related asthma develop in Pseudo-allergic and
non-allergic mechanisms
Asthma associated with the Profession develop in
non-allergic mechanisms

Emphysema:
Terminal broncioles obstruction, destructive changes in the wall of the distal Part (acini),

Expansion of the alveolar cavities

Interalveolar septum undergo atrophy large air bags

Expiratory dyspnea occurs
 Emphysema Pathophysiology:
Imbalance in 1

Protease-Anti Protease sys Oxidant-Antioxidant sys

Protease Enzymes break down Ptns oxidants (Ros)

(Elastase, collagenase) Antioxidants (glutathione, superoxide

Anti protease (α 1 Protease) dismutase)

protect lung tissue

2
Chronic irritation of the alveolar wall

Leukocytes (neutrophils, macrophages)

Release Protease breakdown alveolar Ptn wall

Increase Ros Damage

Anti Protease defficency Damage

Smoking Antioxidant sys

Emphysema occur ✗ X
Disorders of restrictive hypoventilation
Atelectasis:
Dependent disease (nosological unit)
characterized by wrinkling of the alveoli and close their lumen
Three types: Resorption, compression, contraction

Resorption atelectasis:
Blockage of the bronchi lumen
Remaning available air in alveoli is reabsorbed
Lumen of alevoli closes
Compression atelectasis:
Lungs are compressed from outside
Results in growth of connective tissue in the lung Parenchyma with
Pneumosclerosis contraction atelectasis develops Irrevesible Process
If atelectasis is not treated it will cause severe respiratory failure

Pneumothorax:
Air accumulates in the Pleural cavity
Pressure increase in Pleural cavity lungs are compressed
Three types: closed, open, valvular

Closed Pneumothorax:
The air that enters the Pleural cavity loses
contact with the external environment
Respiratory failure depends on the volume of air that
has entered the cavity
Open Pneumothorax:
Air can enter and leave Pleural cavity freely
Disturbance depends on the hole (defect) size
 By the time during exhlation Part of the air discharge from the healthy lung enters

the compressed lung Volume relatively increases and expels air from the Pleural cavity

Valvular Pneumothorax:
Air enters while inhlation BUT while Exhlation air cannot escape
Soft tissues of the damaged area creats a valve around the wound
opens in inhlation close in exhlation
Pluera cavity pressure = atmospheric pressure Air flow stops

Pneumonia:
Is an inflammatory process of various origins that develops in the lung tissue
Types of Pneumonia

Bactiral (Atypical) Non-bacterial (Atypical)

Preamocci Mycoplasma
Streptococci chlamydia
Staphylococci Adenoviruses
Klebsiella Influenza viruses

They multiply in the cavity of They Pass from the alveolar cavity to the
alveoli Inflammatory process intestition region and multiply
leading to strong exudation (fluids) Alveolar infiltration is NOT observed
and alveolar infiltration occur

lung tissue is damaged exudation Either alveolar or interstitial edema

Hering-Breuer reflex is enhanced Dyspnea occurs

* Pneumonia can also be acute and chronic OR community-accuired and nosocomial
Pneumonitis (allergic alveolitis):
occurs due to hypersensitivity reaction of the alveoli, intestitial tissue to exogenous antigen

Type 3 and 4 of allergic reaction, manisisted by damage and gradual fibrosis of the alveolar wall and
interstitial tissue

Pleurisy:
It's an iflammatory disease of the Pleura
Develop for many reasons (e.g. Pneumonia, HF, Quincke edema)
Two types are available Dry Pleurisy, Exudative Pleurisy
Exudative Pleurisy:
fluid accumulates in the Pleural cavity (Hydrothorax)

leading to atelectasis, respiratory and heart failure

Important terms in Plural cavity:
Fluid accumulation Hydrothorax

Blood ← Hemothorax

Lymp = Chylothorax

Alveolar diffusion:
In norm alveolar diffusion provides the transition of oxygen from the alveolar cavity to the Pulmonary
capillaries and carbon dioxide in the opposite direction

Pa 02 in the blood is less than in the alveolar air

Blood flowing to the lungs the Po 2 is 40mm Hg, blood returning from the lungs to the heart is
100 mmHg

Pco2 of blood in the initial Part of the Pulmonary capillaries is 46 mmHg, final Part is 40mm Hg
Disturbance of alveolar diffusion:
Difference in gas gradiants

Surface diffusion area of the lung normal 180-200 m² Pneumonia, allergic alveolitis, Pulmonary edema-..

the area of the diffuse surface and the volume of alveolar diffusion are reduced

Thickness of the alveolar capillary membranes (ACM) Norm is 0.2-2 microns. e. g. in respiratory distress syndrome

of newborns the thickness of the Acm increase Gas diffusion throng the membrane decrease

Molecular weigh of diffused gases and their solubility:

CO2 is able to diffuse in the alveolar capillary 20 times higher than of oxygen

Hypoxemia develops while normocapria is preserved deeper damage to the ACM (e.g. adult

respiratory distress syndrome hypercapnia and hypoxemia occur

* Alveolar diffusion also depends on the condition of Pulmonary circulation e. g. increase blood flow
velocity in the Pulmonary capillaries RBCs doesn't have time to connect with oxygen

Disturbance of lung Perfusion:
Decreased Pressure in the right ventricle (e.g. Shock, collapse)

Increase Pressure in the left atrium (e.g. mitral stenosis)

Increased resistance in the Pulmonary vessels (e.g. reflex spasm, thromboemboli in Pulmonary arterioles)

Disturbance in lung Perfusion can lead to Pulmonary hypertension

Causes of Pulmonary hypertension: 6

1- Euler-Lillestrand reflex
2- Kitayev reflex
3- Increase intra-alveolar pressure
4- Decrease total area of capillary network of the lungs (e.g. Pneumo sclerosis)
5- Increase norepinephrine levels
6- Thickening of the blood
 Types of Pulmonary hypertension

Precapillary Mixed
Postcapillary
Compression of Pulmonary arteriols
start in one form then Progress

Compression of Pulmonary veins

In Pulmonary hypertension hypertrophy of the right Part of the heart develops Called a corpulmonary.

Long Pulmonary hypertension will lead to Pulmonary edema

Mechanisms of Pulmonary edema

Hydrostatic Membrane

Exogenous and endogenous intoxications,
cardiogenic Pulmonary edema Type one allergic reactions, Infections and inflammatory
oncotic process

In nephoretic syndrome

Stages of Pulmonary edema

1 2
Plasma Passes from the Plasma enters the lament of the
Pulmonary capillaries into alveoli (alveolar edema)
interstitial space (Inerstital edema)
Dyspnea at rest
cause compression of the bronchi and
alveoli from the outside
Asphyxia may develop
decrease in the volume of the respiratory surface

Hypoxemia occurs dyspnea in normal
Physical activity
 Ventiation Perfusion index (V/P): Reflects the effectiveness of respiration based on the ventilation of the lung

alveolar diffusion and Perfusion of the lungs normal V/P = 0.8-1

V/P > 1 when alveolar ventilation increase and Perfusion decrease it occurs during the increase

of the volume of the alveolar dead space (e.g. obstruction or the Pulmonary arterioles with a thrombus

or embolus)

V/P < 0.8 blood flow is more than air (ventilation is less than Perfusion)

e.g. Atelectasis atreiovenous shunt occur

* Sometime even with Pulmonary disease V/P index can remain within the normal range
even with the presence or uneaven ventilation of the lung due to compensatory mechanisms

Disturbance in regulation of respiratory system:

Respiratory center in medulla the center of inspiration and expiration receive impulses
from Pneumotoxic and apneustic centers located in the Pons as well as from Peripheral chemo,
baro and mechanoreceptors and from the cerebral cortex

Pneumotaxic center inhibits inhalation and enhance exhalation

Apneustic center enhance inhlation

Neurons of exhlation center does not Participate in normal breathing

(active during heavy Physical work..).

Peripheral receptors:

In the synocarotid region (chemo, baroreceptors)

Mechanoreceptors

Irritant receptors (Between the epithelial cells of the respiratory tract)

J-receptors (interstitial regions

Peripheral chemoreceptor irretated by decrease in the blood pH

Peripheral baroreceptors regulate respiration according to BP (increased BP decrease respiratory rate)

Hering Breuer reflex When Pressure in the alveoli is high Vagus nerve trigger exhlation

to prevent over inflation of the lung namely HBV in infirmation reflex become more sensitive rapid, shallow breathing

Irritant receptors cause narrowing of the airway (Protecting the lung from exposure to toxic

substances)

J-receptor Is irritated in lung congestion causing superficial, rapid breathing
 Impaired respiration

central (medulla oblongata) Efferent
Slow down inhibition of the impulse
Organic changes (edema, tumors....)
Functional (Psychosis...) Involuntary breathing is disturbed Voluntary
Anemia.... breathing occur respiratory arrest occurs while
sleeping (curse of Undine)
P. 3 4 0 Afferent

Increase decrease impulses

Normal respiratory rate (euponea) at rest is 16-20 Per minutes

Types of respiratory rhythm disturbance:

1 Tachypnea or Polypnoea

Rapid, superficial Observed with Pulmonary Hering-Brener reflex is accelerated
respiration Pathology (e.g. Pneumonia,
Pulmonary edema)

Hyperpnea
2

Rapid, deep Observed in increased Severe hypercapria leading to
breathing Oxegyn demand Kussmaul breathing
(e.g. workout, anemia...)
Deep, rapid noisily breathing
occurs due to acidosis that irritates
respiratory center
 3 Bradypnea

Decrease respiratory Narrowing of the Steatonic breathing
lumen of the upper
rate, deep breaths Due to increased resistance
respiratory tract due to
to air flow, inflation difficulties
(tumor, edema,
foreignbody..)
complete opening of the
alveoli is delayed
(delayed Hering-Brier reflex)

Apnea
4

Temprory respiratory occurs due to
severe hypocapain Pickwick' syndrome
arrest

Apnea while sleeping
due to obesity

Periodic breathing:
Normal respiratory rhythm is accompanied by regularly recouring apnea

Two forms are available Cheyne stokes, Biot breathing
B r a in t r a u m a s ,
H e at s t ro k e s
D e c o m p e n s a t e d
h e a r t d e f e c t s

Cheyne stokes breathing: Inspiration gradually deepens and accelerates

reaching certain maximum level Amplitude of respiration decrease gradually and respiration stops

Apnea lasts 30-40 Seconds

Biot breathing: suddenly accelerated with deep breath replaced by periods of apnea
Pathogenesis of Periodic breathing: weakness or the excitability or the respiratory center

carbon dioxide cannot irritate respiratory center apnea occur Increased CO2 levels

Stimulates respiratory center

Terminal breathing: The body is between life and death
Two forms are available Apneustic breathings, Gasping breathings

Apneustic breathing: Characterized by single short term acts of exhlation occurring through the
Prolonged acts of inspiration (Inspiration is more the exhlation) occurs due to barbiturates
Poisoning, brain injures, infarction of the brain stem vagus nerve and brainstems are the key Players

Gasping breathing (agonal breathing): characterized by separate (rare) acts of inspiration
trying to swallow air all muscles are working (cant continue for long time)
occurs in the agonal stage of terminal state Inhibition in central and Peripheral respiratory
system

Dyspnea:
Felling Lack of air

Doesn't occur in unconscious state

Main sign of respiratory failure
occurs due to increase the activity of the inspiration center or weakning the inhibition system

Rapid and deep breath may be slow and superficial

Types of dyspnea

Inspiratory Expiratory Mixed

Restrictive diseases Obstructive diseases

Pneumothorax, Asthma,
Pneumonia, Emphysema,
Pneumo sclerosis, Bronchiectasis
Atelectasis
Coughing:
Reflexogenic zones of coughing reflex are located in the wall Respiratory tract, lung tissue, Pluera, diaphragm

Extraordinary excitation of the inspiratory center cause deep short inhlation while lungs are filled with air Epiglottis

Closes and Preassure increase in the lung, In exhlation strong air opens the epiglottis and Vocal cords,

the soft Palate Closes the nasal cavity Air explodes outward

Protective function (by removing mucus, foreign substances from the respiratory tract)
Induced cough from reflexogenic zones located outside of the respiratory system Is not Protective

Prolonged cough will damage the inter alveolar septa and cause gradual development of emphysema,
by the time it will also impair general circulation

Vagus nerve mediated

Sneezing:
Protective reflex

Receptors in nasal mucosa signals mediated by trigeminal nerve

Pharynx is squeezed Not epiglottis

Prolonged sneezing will cause dyspnea

Hiccups:
Intense act of inspiration results from the contraction of the diaphragm, stomach and glottis

occurs due to irritation of the receptors located directly in the diaphragmatic muscle itself, irritation of the
diaphragmatic nerves, damage to the central nervous system

Yawning:
Deep, long breathing while the non functioning alveoli (at rest) stretch and more air enters the lungs,
then energetic exulation occurs

Aim to improve the oxygen supply in the body

can be observed in Pathological conditions (brain hypoxia)

Disturbance of internal (tissue) respiration:
Internal respiration involves the transport of oxygen from the lungs to the tissues and carbon dioxied
from tissues to the lungs

oxygen transport depends on:
1- oxygen capacity of the blood Is the content of the oxygen in 100mL of blood (16.5-20.5 Vol)

Depends on the Partial Pressure of oxygen in the alveoli and blood, body
2- Ability of oxygen to bind to hemoglobin
temperature blood PH, levels 2,3diphosphoglycerate (2,3 DPH) and ATP in erythrocytes

3- Dissociation of oxyhemoglobin

4- Level of blood circulation and the micro circulatory network

Dissociation curve of oxyhemoglobin is shifted to the left, oxygen is more able to combine
with hemoglobin in the Pulmonary capilarie BUT in tissue capillaries it is difficult to separate oxygen from Hbo2

Carbon dioxide:
is transported in a form of compounds with bicarbonate and hemoglobin (carbhemoglobin)

Hypercapnia expaned cerebral vessels increase intercranial pressure, impaired cerebral circulation

Hypocapria Spasm of cerebral Vessels and brain hypoxia

Oxygen utilization index:

The amount of oxygen that is absorber by the tissues

Expressed as a Percentage the ratio between arteriovenous oxygen to arterial blood 02

Decrease blood flow velocity decrease in the content of oxygen in arterial blood index

Disturbance of biological oxidation include:
1- Deficiency of vitamine B1, B2, PP....)

2- cytochrome oxidase inhibition (e.g. in cyanide Poisoning, alcohol....)

3- Imbalance between oxidation and Phosphorylation (e.g. in thyrotoxicosis, nitrate Poisoning....)

4- Mitochondrial damage and ATP deficiency (eg, in cachexia, sepsis, radiation sickness....)

In these condition Normal oxygen content in arterial blood BUT oxygen is not used in tissues
leading to histotoxic hypoxia
 Impairment of non respiratory functions of lungs:

Metabolic functions Hemostasis functions Protective functions Lymphatic drainage

1- synthesis of coagulation 1- Air Purification 1- Remove accumulated
1- formation of angiotensin 2, in and anticoagulant factors substances in the
endothelial cells of the Pulmonary Such as 2- Alveolar macrophages lungs during Pathological
capillaries ACE convert angiotenin
1 to 2 (active) collagenase process
Thromboplastin Elastase
2- Inactivation of substances such as Heparin catalase
Bradykinin A Phospholipase
Plasminogen activator
3- Mucociliary apparatus
Norepinephrine Prostacyclin
4- Blood filtration
Serotonin Thromboxane A2
by the help of
alveolar macrophages

Acute lung injury (Acute respiratory distress syndrome * ARDS *):
Characterized by diffuse lessions to the alveolar capillaries and alveolar epithelium

Lead to Pulmonary edema and acute respiratory failure

ARDS form

Adults Newborns (Prematures)
Diffuse damage to the lung tissue known as hyaline membrane disease
Alveolar epithelium undergoes necrosis, Permability of the Main cause is surfactant deficiency
alveolar capillaries increase alveolar edema develops Alveoli are closed Atelectasis develops

Result due to direct injury of the lungs (infections, capillary Permability increase, exudation increase
allergic, inflammatory processes) OR extra pulmonary
Hyaline settles on the alveoli wall
Pathologies (Sepsis, Pancreatitis, Peritonitis, traumatic and burn
shock, disseminated intravascular coagulation DIC) severe hypoxia, acidosis develop in the body

Damage to the alveolar capillary membrane is due to
dysregulation of the acute inflammatory response (Imbalance Surfactant synthesis may also decrease due to
between Pro and anti inflammatory mediators) Hypoxia, Hypothermia, weakning of blood
flow in the lungs, acidosis
Neutrophils that are activated by macrophages secrete
excessively inflammatory mediator Leukotrines, PAF,
Protease, IL-1, I L-8, TNF....) damaging and necrotizing
alveolar epithelium

Destruction of Type 2 epithelial cells
synthesis of surfactant stop
Alveoli are closed Atelectasis develops
Neutrophils cannot be inhibited by
anti-inflammatory mediators (IL-10, endogenous,
Protease, antioxidants)
Hyaline membrane forms leading to
hypoxemia
Asphyxia:
Severe form of respiratory failure

Transfering oxygen to the blood and removing carbon dioxide from body become impossible * severe cases *

can occur for many reason squeezing airway from outside, drowning, Laryngeal edema, severe broncho spasm
Respiratory muscle Paralysis, glottis spasm... P. 347

Stages of asphyxia
First stage Second stage Third stage Fourth stage

weakining of the Breathing stops for Reflexes are lost
Acute increase in respiratory
respiratory center 1-2 minutes
center activity mydriasis
Inspiratory dyspnea Expiratory dyspnea Respiratory arrest due Very severe hypotension
to delay in the activity
Increase sympathetic tone increase Parasympathetic of the respiratory
center Gasping breathing
tone
explained by increase CO2 level
Explained by the effect severe hypotension Respiratory center
but not reaching the inhibition of acute hypercapria on paralysis and
and very slow Pulse
effect the Parasympathetic death occurs
Consciousness is
system 5-15 minutes after
lost
respiratory arrest
rare heart rate continue
within this time life can
be saved

During asphyxia, rising carbon dioxide levels and falling oxygen levels initially stimulate the respiratory and
vasomotor centers, increasing breathing, heart activity, and blood pressure. However, as carbon dioxide
continues to rise, it eventually inhibits these centers. At the same time, worsening oxygen deprivation
(hypoxemia) leads to brain hypoxia, further weakening the cardiovascular and respiratory systems, ultimately
paralyzing the respiratory center and stopping breathing.