Basics of respiration
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Transcript of Basics of respiration
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Lung volume ,capacities and mechanics of respiation
Dr.Sivaramakrishnan
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Introduction
Respiration includes two parts External respiration Internal respiration
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External & Internal Respiration
External Respiration The movement of gases into & out of
body Gas transfer from lungs to tissues of
body Maintain body & cellular
homeostasis
Internal Respiration Intracellular oxygen metabolism Cellular transformation ATP generation O2 utilization
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Goals of Respiration
Primary Goals Of The Respiration System
Distribute air & blood flow for gas exchange
Provide oxygen to cells in body tissues
Remove carbon dioxide from body Maintain constant homeostasis for
metabolic needs
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Functions of Respiration
Respiration divided into four functional events:
1.Mechanics of pulmonary ventilation2.Diffusion of O2 & CO2 between alveoli
and blood3.Transport of O2 & CO2 to and from
tissues4.Regulation of ventilation & respiration
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Physiological Lung Structure
Lung weighs 1.5% of body weight Alveolar tissue is 60% of lung weight
Alveoli have very large surface area 70 m2 internal surface area
Short diffusion pathway for gases Permits rapid & efficient gas exchange into blood 1.5 µm between air & alveolar capillary RBC Blood volume in lung (10% of total blood
volume)
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Air passages
After passing through the nasal passages and pharynx, where it is warmed and takes up water vapor, the inspired air passes down the trachea and through the bronchioles, respiratory bronchioles, and alveolar ducts to the alveoli
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Branching pattern
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Total airway cross section area
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Alveoli
The alveoli are surrounded by pulmonary capillaries.
In most areas, air and blood are separated only by the alveolar epithelium and the capillary endothelium, so they are about 0.5 mcm apart
300 million alveoli in humans, and the total area of the alveolar walls in contact with capillaries in both lungs is about 70 m2.
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Type I cells are flat cells with large cytoplasmic extensions and are the primary lining cells.
Type II cells (granular pneumocytes) are thicker and contain numerous lamellar inclusion bodies. These cells secrete surfactant
Also helps in alveolar repair
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Anatomic Dead Space Dead Space = ventilated
but not perfused The portion of tidal
volume fresh air which does not go directly to the terminal respiratory units (30%)
The conducting airways do not participate in O2 & CO2 exchange
Dead space roughly 2 ml/kg ideal body weight or weight in pounds
Anatomical differs from physiological dead space also described as wasted ventilation
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Wasted Ventilation
The concept of physiologic dead space (VPD) describes a deviation from ideal ventilation relative to blood flow
Wasted ventilation includes anatomical dead space plus any portion of alveolar ventilation that does not exchange O2 or CO2 with pulmonary blood flow (alveolar dead space)
Ventilation/blood flow (V/Q) mismatch where blood flow blocked ( clot or emboli)
Wasted ventilation = VPD = VD + VAD
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Wasted Ventilation
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Bronchi and innervation
The trachea and bronchi have cartilage in their walls.
Lined by a ciliated epithelium that contains mucous and serous glands.
Cilia are present as far as the respiratory bronchioles, but glands are absent from the epithelium of the bronchioles and terminal bronchioles
Bronchioles and term bronchioles do not have but contain more smooth muscle
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Abundant muscarinic receptors, and cholinergic
discharge causes bronchoconstriction.
There are β2-adrenergic receptors in the bronchial epithelium and smooth muscle.
The β2 receptors mediate bronchodilation. They increase bronchial secretion while α1 adrenergic receptors inhibit secretion
Noncholinergic, non-adrenergic innervation of the bronchioles that produces bronchodilation, and there is evidence that VIP is the mediator responsible for the dilation.
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Pulmonary circulation
Almost all the blood in the body passes via the pulmonary artery to the pulmonary capillary bed, where it is oxygenated and returned to the left atrium via the pulmonary vein
The separate and much smaller bronchial arteries come from systemic arteries. They form capillaries, which drain into bronchial veins or anastomose with pulmonary capillaries or veins
The bronchial veins drain into the azygos vein. The bronchial circulation nourishes the bronchi and pleura. Lymphatic channels are more abundant in the lungs than in any other organ
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Tidal volume is the amount of air that moves into the lungs with each inspiration and expiration
Inspiratory reserve volume is the air inspired with a maximal inspiratory effort in excess of the tidal volume
The volume expelled by an active expiratory effort after tidal expiration is the expiratory reserve volume
The air left in the lungs after a maximal expiratory effort is the residual volume
Vital capacity is defined as the amount of air moved in out of the lungs with max inspiration and expiration
Total lung capacity is the volume of gas occupying the lungs after maximum inhalation
Functional residual capacity is the amount of air left in the lungs after tidal expiration• Remember: A
capacity is always a sum of certain lung volumes
• TLC = IRV + TV + ERV + RV
• VC = IRV+ TV + ERV
• FRC = ERV + RV• IC = TV + IRV
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Spirometry
REMEMBER: Spirometry cannot measure Residual Volume (RV) thus Functional Residual Capacity (FRC) and Total Lung Capacity (TLC) cannot be determined using spirometry alone.
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Chest wall
Chest wall compliance is a major determinant of FRC
FRC reached at a point where outward thoracic cage recoiling counterbalances inward lung recoiling
Measured FRC in infants is higher than expected
Increased chest wall compliance is a distinct disadvantage
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Poorly equipped to sustain large workloads
Easily fatigable thereby limiting their ability to maintain ventilation in lung disease
In poor compliance conditions, there is greater retraction of chest wall leading to more loss of FRC
Obstructive lung diseases produce greater chest recoil and reduced FRC
PEEP beneficial in these conditions
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Respiratory Mechanics
Multiple factors required to alter lung volumes
Respiratory muscles generate force to inflate & deflate the lungs
Tissue elastance & resistance impedes ventilation
Distribution of air movement within the lung, resistance within the airway
Overcoming surface tension within alveoli
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The Breathing Cycle
Airflow requires a pressure gradient Air flow from higher to lower
pressures During inspiration alveolar pressure
is sub-atmospheric allowing airflow into lungs
Higher pressure in alveoli during expiration than atmosphere allows airflow out of lung
Changes in alveolar pressure are generated by changes in pleural pressure
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Elastance Property of a substance to oppose
deformation or stretching Calculated as change in pressure / change
in volume Elastic recoil is a property that enables it
to return to its original state after it is no longer subjected to pressure
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Compliance Is the reciprocal of elastance Refers to distensibility
Resistance Amount of pressure required to generate
flow of gas across the airways Poiseuille’s law – R = 8 Lη/Πr⁴
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Newborns and young infants have inherently smaller airways
Prone to marked increase in airway resistance from inflamed tissues and secretions.
In diseases in which airway resistance is increased, flow often becomes turbulent.
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Re =2rvd/η Turbulance in airflow is most likely if
Re number exceeds 2000 Neonates and young infants are
predominantly nose breathers and, therefore, even a minimal amount of nasal obstruction is poorly tolerated.
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Inspiration
Active Phase Of Breathing Cycle
Motor impulses from brainstem activate muscle contraction
Phrenic nerve (C 3,4,5) transmits motor stimulation to diaphragm
Intercostal nerves (T 1-11) send signals to the external intercostal muscles
Thoracic cavity expands to lower pressure in pleural space surrounding the lungs
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Pressure in alveolar ducts & alveoli decreases
Lungs expand passively as pleural pressure falls(-2.5mmHg to -6mmHg)
Fresh air flows through conducting airways into terminal air spaces until pressures are equalized
The act of inhaling is negative-pressure ventilation
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Muscles of Inspiration: Diaphragm
Most Important Muscle Of Inspiration
Responsible for 75% of inspiratory effort
Thin dome-shaped muscle attached to the lower ribs, xiphoid process, lumbar vertebra
Innervated by Phrenic nerve (Cervical segments 3,4,5)
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During contraction of diaphragm Abdominal contents forced downward &
forward causing increase in vertical dimension of chest cavity
Rib margins are lifted & moved outward causing increase in the transverse diameter of thorax
Diaphragm moves down 1cm during normal inspiration
During forced inspiration diaphragm can move down further
Paradoxical movement of diaphragm when paralyzed Upward movement with inspiratory drop of
intrathoracic pressure Occurs when the diaphragm muscle is
denervated
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Expiration
The Passive Phase Of Breathing Cycle
Chest muscles & diaphragm relax contraction
Elastic recoil of thorax & lungs return to equilibrium
Pleural & alveolar pressures rise Gas flows passively out of the lung Expiration - active during hyperventilation
& exercise
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Movement of Thorax During Breathing Cycle
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Movement of Diaphragm
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THAT’S ALL FOR TODAY thank you
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