Deck 16: The Respiratory System: Pulmonary Ventilation

A) respiratory bronchioles
B) secondary bronchi
C) tertiary bronchioles
D) bronchi
E) terminal bronchioles

A) increase chest volume and elasticity (resilience)
B) increase tidal volume
C) maximize surface area and minimize thickness
D) maximize density and volume
E) maximize surface area

A) internal respiration
B) respiration
C) secondary ventilation
D) pulmonary ventilation
E) expiration

A) It lands in the respiratory bronchiole, where it is coughed out
B) It lands in the mucociliary ladder, where type II macrophages phagocytize it.
C) It is inhaled and then exhaled.
D) It lands in the bronchi, where it is absorbed.
E) It lands in the mucociliary ladder, where it is moved to the trachea to be exhaled.

A) speed the rate of diffusion
B) allow for nutrients to reach the alveolar cells
C) a portal for diapedesis
D) equalize pressure in the lungs
E) allow for exhalation of H₂O formed during cellular respiration

A) propel mucus containing trapped particles toward the glottis
B) engulf foreign material that has been trapped within the mucus
C) move macrophages down the conducting zone toward the respiratory zone
D) provide the rigid support that keeps the conducting zone open
E) produce a viscous solution called mucus

A) cartilage
B) goblet cells
C) macrophages
D) smooth muscle cells
E) type II alveolar cells

A) terminal bronchioles.
B) alveolar ducts.
C) tertiary bronchi.
D) respiratory bronchioles.
E) alveoli.

A) respiratory membrane
B) type I alveolar cell
C) type II alveolar cell
D) alveolar macrophage
E) endothelial cell

A) bacterial pneumonia
B) pulmonary fibrosis
C) pneumothorax (air leaking into the intrapleural space)
D) adhesions to the parietal pleura
E) acute respiratory distress syndrome (ARDS)

A) the absence of cartilage
B) the presence of macrophages
C) the absence of goblet cells
D) the presence of smooth muscle and the absence of cartilage
E) the thickness of the walls surrounding the air spaces

A) cartilage
B) cilia
C) goblet cells
D) smooth muscle
E) type I alveolar cells

A) the exchange of oxygen and carbon dioxide between the blood and tissues by diffusion
B) the use of oxygen and generation of carbon dioxide by the mitochondria during energy metabolism
C) the transportation of oxygen and carbon dioxide between the lungs and body tissues by the blood
D) the movement of air into and out of the lungs by bulk flow
E) the exchange of oxygen and carbon dioxide between the lungs and blood by diffusion

A) It lands in the mucociliary ladder and moves to the pharynx to be swallowed.
B) It lands in the bronchi, where it is absorbed.
C) It lands in the mucociliary ladder, where type II macrophages phagocytize them.
D) It lands in the respiratory bronchiole, where it is coughed out.
E) It lands in the mucociliary ladder, where it is moved to the trachea to be exhaled.

A) The surface area is increased with this membrane.
B) Its thickness prohibits the alveoli from pulling away from the capillary.
C) It is covered with surfactant to accelerate gas exchange.
D) Epithelial and endothelial cells share a common basement membrane.
E) All three surfaces are kept moist through interstitial fluid exchange.

A) decreased traction.
B) surface tension decrease.
C) mixing of oxygenated/deoxygenated blood.
D) airway collapse.
E) the use of secondary breathing muscles.

A) vocalization
B) acid -base balance of blood
C) enhancing venous return
D) heat loss
E) electrolyte balance of blood

A) It is just small enough to land in the mucociliary ladder, where it is moved to the alveoli to infect macrophages.
B) It is just small enough to land in the bronchi, where it is absorbed by alveolar macrophages.
C) It is too small to be caught in the mucociliary ladder and too large to be immediately exhaled, thereby landing it in the alveoli.
D) It is just large enough to land in the respiratory bronchiole, where it migrates to the alveoli.
E) It is just large enough to land in the mucociliary ladder, where type II macrophages phagocytize them.

A) macrophages
B) goblet cells
C) type I alveolar cells
D) type II alveolar cells
E) type III alveolar cells

A) diaphragm and external intercostals
B) diaphragm and abdominal muscles
C) diaphragm and internal intercostals
D) external and internal intercostals
E) diaphragm and the external and internal intercostals

A) decrease in the volume of the thoracic cavity and, therefore, a decrease in atmospheric pressure
B) decrease in the volume of the thoracic cavity and, therefore, a decrease in intra -alveolar pressure
C) increase in the volume of the thoracic cavity and, therefore, an increase in intra -alveolar pressure
D) decrease in the volume of the thoracic cavity and, therefore, an increase in intra -alveolar pressure
E) increase in the volume of the thoracic cavity and, therefore, a decrease in intra -alveolar pressure

A) atmospheric and intrapleural
B) central venous and intracoronary
C) atmospheric and intra -alveolar
D) pulmonary venous and atmospheric
E) intrapleural and intra -alveolar

A) difference between intra -alveolar pressure and atmospheric pressure
B) transpulmonary pressure
C) intrapleural pressure
D) intra -alveolar pressure
E) atmospheric pressure

A) chronic obstructive pulmonary disease
B) restrictive pulmonary disease
C) air moving into the lungs
D) air moving out of the lungs
E) a pneumothorax (the lung will collapse)

A) lung volume : airway resistance
B) lung volume : transpulmonary pressure
C) intra -alveolar pressure : lung volume
D) lung volume : intra -alveolar pressure
E) airway resistance : lung volume

A) intrapleural pressure.
B) atmospheric pressure.
C) transpulmonary pressure.
D) systolic blood pressure.
E) end -diastolic pressure.

A) active : contraction of the internal intercostals
B) active : relaxation of the diaphragm
C) passive : relaxation of the internal intercostals
D) active : the contraction of the diaphragm
E) passive : relaxation of the diaphragm and external intercostals

A) will follow Starling's law.
B) will follow the ideal gas law.
C) decreases.
D) increases.
E) will not change.

A) atmospheric pressure only
B) intrapleural pressure only
C) intra -alveolar pressure only
D) both intrapleural pressure and intra -alveolar pressure
E) both atmospheric pressure and intrapleural pressure

A) zero
B) tidal volume
C) residual volume
D) functional residual capacity
E) total lung capacity

A) Intra -alveolar pressure is greater than atmospheric pressure.
B) Intra -alveolar pressure is less than intrapleural pressure.
C) Intrapleural pressure is zero.
D) The elastic recoil of the lungs is balanced by the elastic recoil of the chest wall.
E) Intra -alveolar pressure is less than atmospheric pressure.

A) increases : out of
B) decreases : out of
C) decreases : into
D) increases : into
E) does not change : neither into nor out of

A) tuberculosis
B) pulmonary edema
C) pulmonary fibrosis
D) asthma
E) chronic obstructive pulmonary disease (COPD)

A) Air moves into the lung.
B) Air moves out of the lung.
C) The lung must be expanding.
D) Intrapleural pressure is greater than intra -alveolar pressure.
E) The lung collapses.

A) transpulmonary pressure.
B) the driving force for air flow into and out of the lungs.
C) zero.
D) approximately 100 mm Hg.
E) atmospheric pressure.

A) decrease in intra -alveolar pressure.
B) increase in transpulmonary pressure.
C) increase in atmospheric pressure.
D) decrease in transpulmonary pressure.
E) increase in intrapleural pressure.

A) intra -alveolar pressure only
B) transpulmonary pressure only
C) intrapleural pressure only
D) both intra -alveolar and transpulmonary pressures
E) both intra -alveolar and intrapleural pressures

A) volume.
B) airway resistance.
C) surface tension.
D) intra -alveolar pressure.
E) transpulmonary pressure.

A) skeletal muscle, innervated by the somatic nervous system.
B) smooth muscle, innervated by the autonomic nervous system.
C) smooth muscle, without innervation.
D) skeletal muscle, innervated by the autonomic nervous system.
E) smooth muscle, innervated by the somatic nervous system.

A) minute ventilation
B) total lung capacity
C) vital capacity
D) tidal volume
E) functional residual capacity

A) electroencephalogram
B) spirometer
C) X -ray
D) ratiometer
E) electrocardiograph

A) increased secretion of mucus
B) increased release of corticosteroids
C) increased airway resistance
D) increased histamine release
E) increased inflammatory response

A) increase in compliance
B) increase in airway resistance
C) decrease in airway resistance
D) bronchodilation
E) decrease in compliance

A) minute ventilation
B) forced expiratory volume
C) vital capacity
D) tidal volume
E) residual volume

A) epinephrine
B) norepinephrine
C) carbon dioxide
D) histamine
E) bronchodilators

A) 10
B) 50
C) 20
D) 80
E) 100

A) tidal volume
B) residual volume
C) inspiratory reserve volume
D) vital capacity
E) inspiratory capacity

A) functional residual volume
B) residual volume
C) vital capacity
D) tidal volume
E) functional residual capacity

A) 1000
B) 4500
C) 100
D) 9000
E) 500

A) They decrease mucus secretion into the airways.
B) They increase blood flow to the airways.
C) They reduce inflammation of the airways.
D) They induce bronchodilation.
E) They induce bronchoconstriction.

A) ciliated
B) goblet
C) type I alveolar
D) type II alveolar
E) type III alveolar

A) pulmonary ventilation
B) minute ventilation
C) total lung capacity
D) tidal volume
E) alveolar ventilation

A) expiration : increase residual volume and total lung capacity
B) expiration : decrease total lung capacity and vital capacity
C) inspiration : increase total lung capacity and vital capacity
D) inspiration : decrease total lung capacity and vital capacity
E) expiration : increase vital capacity

A) 1000
B) 100
C) 10,000
D) 5000
E) 500

A) surrounding atmospheric pressure
B) sensitivity of smooth muscle cells to allergens
C) passive forces exerted on the airways
D) autonomic nervous system
E) contractility of smooth muscle cells

A) tidal volume is indicative of an obstructive pulmonary disease.
B) forced vital capacity
C) minute ventilation
D) residual volume
E) forced expiratory volume

A) tractive forces exerted on the airway by surrounding tissue
B) contractile activity of bronchiolar smooth muscle cells
C) pulmonary surfactant concentration
D) transpulmonary pressure
E) secretion of mucus into the airway

A) residual volume and expiratory reserve volume only
B) tidal volume and inspiratory reserve volume only
C) vital capacity and expiratory reserve volume only
D) tidal volume, inspiratory reserve volume, and expiratory reserve volume
E) tidal volume and expiratory reserve volume only

A) functional residual capacity
B) residual volume
C) total lung capacity
D) vital capacity
E) inspiratory capacity

A) atmospheric pressure
B) intra -alveolar pressure
C) rebound pressure (elastic recoil)
D) transpulmonary pressure
E) intrapleural pressure

A) total lung capacity
B) alveolar ventilation
C) pulmonary ventilation
D) minute ventilation
E) tidal volume

A) rebound pressure (elastic recoil)
B) atmospheric pressure
C) transpulmonary pressure
D) intrapleural pressure
E) intra -alveolar pressure

A) thins
B) no change
C) increases
D) decreases
E) It is not found in the conducting zone.

A) intra -alveolar pressure
B) atmospheric pressure
C) transpulmonary pressure
D) rebound pressure (elastic recoil)
E) intrapleural pressure

A) type I alveolar cells
B) alveolar macrophages
C) type II alveolar cells
D) ciliated cells
E) goblet cells

A) increases
B) no change
C) atrophies
D) decreases
E) thickens

A) alveolar macrophages
B) goblet cells
C) type II alveolar cells
D) type I alveolar cells
E) ciliated cells

A) ciliated cells
B) goblet cells
C) alveolar macrophages
D) type II alveolar cells
E) type I alveolar cells

A) increases
B) no change
C) thickens
D) decreases
E) changes to ciliated pseudostratified epithelium

A) no change
B) hypertrophies
C) decreases
D) thickens
E) increases

A) intra -alveolar pressure
B) rebound pressure (elastic recoil)
C) transpulmonary pressure
D) intrapleural pressure
E) atmospheric pressure

A) intra -alveolar pressure
B) exhalation pressure
C) atmospheric pressure
D) intrapleural pressure
E) transpulmonary pressure

A) type II alveolar cells
B) alveolar macrophages
C) ciliated cells
D) goblet cells
E) type I alveolar cells

A) anatomical dead space
B) residual volume
C) dead volume
D) functional dead space
E) functional residual volume

A) intra -alveolar pressure
B) rebound pressure (elastic recoil)
C) atmospheric pressure
D) intrapleural pressure
E) transpulmonary pressure

A) ciliated cells
B) type II alveolar cells
C) goblet cells
D) type I alveolar cells
E) alveolar macrophages

A) inspiratory reserve volume.
B) inspiratory capacity.
C) vital capacity.
D) tidal volume.
E) residual volume.

A) transpulmonary pressure
B) intrapleural pressure
C) intra -alveolar pressure
D) atmospheric pressure
E) rebound pressure (elastic recoil)

A) decreases
B) increases
C) thins
D) no change
E) thickens