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Respiratory ventilation

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1 Respiratory ventilation
Dr. Laila Al-Dokhi Assistant professor Physiology Department

2 Learning objectives By the end of the lecture you should be able to: -
1-Define the various lung volumes and capacities and provide typical values for each. 2-Define ventilation rates, their typical values, and their measurement. 3- Describe FEV1 and its role in differentiating obstructive and restrictive lung diseases. 4- Describe the types of dead space. State a volume for the anatomical dead space. 5- Define the term minute ventilation and state a typical value. 6- Distinguish minute ventilation from alveolar ventilation.

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5 Pulmonary volumes and capacities
Pulmonary volumes (by using spirometer): Tidal volume – is the volume of air inspired or expired with each normal breath = 500ml in young adult man. Inspiratory reserve volume – is the extra volume of air that can be inspired over and beyond the normal tidal volume = 3000ml. Expiratory reserve volume – is the extra amount of air that can be expired by forceful expiration after the end of a normal tidal expiration ~ 1100ml. Residual volume – is the volume of air that still remain in the lungs after the most forceful expiration ~ 1200ml.

6 The pulmonary capacities
Comprises more than one volume: Inspiratory capacity – is the volume of air inspired by a maximal inspiratory effort after normal expiration = 3500ml = inspiratory reserve volume + tidal volume. The functional residual capacity – is the volume of air remaining in the lungs after normal expiration = 2300ml = expiratory reserve volume + residual volume. The vital capacity – is the volume of air expired by a maximal expiratory effort after maximal inspiration ~ 4600ml = inspiratory reserve volume + tidal volume + expiratory reserve volume. Total lung capacity – is the maximum volume of air that can be accommodated in the lungs ~ 5800ml = vital capacity + residual volume. Minute respiratory volume – is the volume of air breathed in or out of the lungs each minute = respiratory rate x tidal volume = 12 X 500ml = 6000ml/min. All lung volume and capacity are about 20 to 25% less in women than in men and are greater in athletic persons than in small and asthenic persons.

7 Closed circuit Helium Dilution Method
C1xV1 = C2xV2 C1: concentration of Hi in spirometry V1: volume of air in the spirometry. C2: Final concentration of helium V2 :Volume of spirometry+ FRC FRC = ( Ci He (C1) - 1) Vi Spi (V1) Cf He (C2)

8 Forced Vital Capacity (FVC) and FEV1
(Timed vital capacity) The person is asked to inspire as deeply as possible and then to breath out as hard and as fast as he can. The expiration is continued until he expired all the air out and thus forced vital capacity is obtained. During this process the volume of air expired in the first second is collected and is known as FEV1.

9 FEV1/FVC ratio Normally it is about 80%.
This ratio differentiate between obstructive and restrictive lung diseases Is normal in restrictive lung diseases (e.g interstitial pulmonary fibrosis) It decreases in obstructive (bronchial asthma, emphysema)

10 FORCED EXPIRATION TIDAL BREATHING NORMAL FEV1 = 3.0L FVC = 4.2L FEV1/FVC = 72% FEV1 OBSTRUCTIVE FEV1 = 0.9L FVC = 2.3L FEV1/FVC = 40% FEV1 RESTRICTIVE FEV1 =1.8L FVC = 2.3L FEV1/FVC = 78% FEV1 1 SECOND

11 Minute respiratory volume
MRV = Respiratory rate x Tidal volume = RR X TV = 12 X = 6L/min. it could rise to 200 L/min or more than 30 times normal if RR = 40 TV = 4600 ml in young adults man

12 Anatomical dead space:-
Occupies the air-conducting system down to the terminal bronchioles No gas exchange Volume  150ml Physiological dead space = anatomical dead space + alveolar dead space Respiratory zone:- Occupies the space distal to the terminal bronchioles start from the respiratory bronchioles down to the alveolar sacs Gas exchange takes place Volume  350ml/min

13 The rate of alveolar ventilation
Alveolar ventilation per minute is the total volume of new air entering the alveoli and other adjacent gas exchange areas each minute. Va = Respiratory rate X (Vt – Vd) = Respiratory rate X (Vtidal volume – Vdead space) = 12 X (500 – 150) = 4200ml

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