Deck 27: B: Physiology of the Respiratory System

A) inversely related to the concentration of that gas in the mixture and
B) directly related to the concentration of that gas in the mixture and
C) directly related to the concentration of that gas in the mixture and inversely related
D) inversely related to the concentration of that gas in the mixture and directly related

A) apnea.
B) hyperpnea.
C) dyspnea.
D) eupnea.

A) inspiration occurs.
B) expiration occurs.
C) lung tissue has collapsed.
D) the bronchioles are obstructed.

A) The total functional surface area of the respiratory membrane
B) Alveolar ventilation
C) The oxygen pressure gradient between alveolar air and incoming pulmonary blood
D) All of the above help determine the amount of oxygen that diffuses into the blood each minute.

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

A) 650
B) 700
C) 760
D) 800

A) Hyperpnea
B) Dyspnea
C) Biot's breathing
D) Eupnea

A) increased residual volume.
B) decreased vital capacity.
C) increased functional reserve volume.
D) decreased tidal volume.

A) thoracic cavity has a difficult time lowering the internal pressure below the lower atmospheric pressure.
B) lower atmospheric pressure lowers the PO2 and the diffusion gradient between the blood and the atmosphere is less.
C) lower atmospheric pressure lowers the PO2 and the diffusion gradient between the blood and the atmosphere is greater.
D) physiological dead air space increases and atmospheric pressure decreases.

A) orthopnea.
B) hyperpnea.
C) dyspnea.
D) eupnea.

A) Residual volume and vital capacity
B) Tidal volume, inspiratory reserve volume, and expiratory reserve volume
C) Residual volume and tidal volume
D) Vital capacity and tidal volume

A) Sternocleidomastoid and abdominal muscles
B) Sternocleidomastoid and intercostals
C) External intercostals and pectoralis muscles
D) Abdominal muscles and internal intercostals

A) 23
B) 160
C) 300
D) 590

A) inspiratory capacity and the residual volume.
B) inspiratory reserve volume, tidal volume, and expiratory reserve volume.
C) tidal volume, residual volume, and expiratory reserve volume.
D) inspiratory reserve volume, tidal volume, and inspiratory capacity.

A) maximum volume of air that can be moved into and out of the lungs during forced respiration.
B) volume of air that can be forcibly exhaled after a normal inspiration.
C) volume of air that can be forcibly exhaled at the end of a normal expiration.
D) total volume of air contained in the respiratory passages.

A) 50
B) 100
C) 150
D) 200

A) Transport of gases
B) Gas exchange in lungs and tissue
C) Control of cell metabolism rate
D) Pulmonary ventilation

A) dyspnea.
B) apnea.
C) Biot breathing.
D) Cheyne-Stokes respiration.

A) cohesion of visceral and parietal pleura.
B) a pressure gradient from alveoli to atmosphere.
C) a decrease in alveolar pressure.
D) an increase in intrathoracic pressure from about -6 to -4 mm Hg.

A) Increased PCO2, decreased arterial pressure, decreased pH, decreased PO2
B) Increased PCO2, decreased arterial pressure, increased pH, decreased PO2
C) Decreased PCO2, decreased arterial pressure, increased pH, increased PO2
D) Decreased PCO2, decreased arterial pressure, decreased pH, decreased PO2

A) Increased PO2
B) Decreased PCO2
C) Decreased PO2 and decreased PCO2
D) Decreased PO2 and increased PCO2

A) 10%
B) 15%
C) 20%
D) 25%

A) anatomical dead air space.
B) tidal volume.
C) reserve volume.
D) residual volume.

A) carbonic anhydrase.
B) carbaminohemoglobin.
C) the heme group.
D) the bicarbonate ion.

A) carbonic acid.
B) oxyhemoglobin.
C) carbaminohemoglobin.
D) All of the above are correct.

A) Serratus anterior
B) External intercostal muscles
C) Diaphragm
D) Neither A nor B

A) cause a reflex increase in rate and depth of respirations.
B) cause a reflex slowing of respirations.
C) have no effect on respirations because of the control mechanisms in the cerebral cortex.
D) cause an immediate decrease in respirations followed by a prolonged period of rapid and shallow respirations.

A) less than in the alveolar air.
B) greater than in the alveolar air.
C) equal to the alveolar air.
D) greater than arterial blood.

A) compliance.
B) elastic recoil.
C) expiration.
D) ventilation.

A) 550
B) 400
C) 300
D) 250

A) less than in the systemic venous
B) greater than in the systemic venous
C) equal to the systemic arterial
D) Both A and C are correct.

A) dissolved in the plasma, carbaminohemoglobin, and bicarbonate ion.
B) carbaminohemoglobin, bicarbonate ion, and dissolved in plasma.
C) bicarbonate ion, dissolved in plasma, and carbaminohemoglobin.
D) bicarbonate ion, carbaminohemoglobin, and dissolved in plasma.

A) in solution.
B) as bicarbonate ions.
C) as carbaminohemoglobin.
D) none of the above.

A) Dalton
B) Henry
C) Boyle
D) Charles

A) As oxyhemoglobin
B) Combined with the bicarbonate ion (HCO3-)
C) Dissolved in the plasma
D) All of the above are used to transport oxygen in the blood.

A) Sudden painful stimulus
B) Increase in carbon dioxide in the blood
C) Sudden cold stimulus applied to the skin
D) Both A and C

A) Internal intercostals
B) External intercostals
C) Abdominal muscles
D) None of the above

A) anatomical dead air space.
B) physiological dead air space.
C) functional residual capacity.
D) vital capacity.

A) 55%
B) 63%
C) 82%
D) 97%

A) The mediastinum is a mobile rather than a rigid partition between the two pleural sacs, thereby allowing the increased pressure in the side of the chest that is open to push the heart and other mediastinal structures toward the intact side, where they can exert pressure on the left lung.
B) Subatmospheric pressure increases from its normal level and thereby moves from high pressure area (right lung) to low pressure area (left lung).
C) When intrathoracic pressure increases, the mediastinum softens and thereby allows the increased pressure in the side of the chest that is open to push the heart and mediastinal structures toward the intact side, where they can exert pressure on the left lung.
D) Intrathoracic pressure increases from its subatmospheric level to an atmospheric level, thereby allowing the pressure within the chest to increase in proportion to the volume of the thorax.

A) Two
B) Four
C) Eight
D) Hemoglobin cannot carry carbon dioxide molecules.

A) Anything that decreases alveolar PO2 tends to increase the alveolar-blood oxygen pressure gradient and, therefore, tends to increase the amount of oxygen entering the blood.
B) Anything that decreases alveolar PO2 tends to decrease the alveolar-blood oxygen pressure gradient and, therefore, tends to decrease the amount of oxygen entering the blood.
C) Anything that decreases alveolar PO2 tends to increase the alveolar-blood diffusion rate and, therefore, tends to increase the amount of oxygen entering the blood.
D) Anything that decreases PO2 tends to increase arterial-blood PO2 and, therefore, tends to decrease the amount of oxygen entering the blood.

A) When atmospheric pressure is less than the pressure within the lung, air flows down this gas pressure gradient. Then air moves from the atmosphere into the lungs.
B) When atmospheric pressure is greater than the pressure within the lungs, air flows down this gas pressure gradient. Then air moves from the atmosphere into the lungs.
C) When atmospheric pressure is greater than the pressure within the lung, air flows away from this gas pressure gradient. Then air moves from the lungs out into the atmosphere.
D) When atmospheric pressure is less than the pressure within the lung, air flows up this gas pressure gradient. Then air moves from the atmosphere into the lungs.

A) Pons
B) Medulla
C) Cerebellum
D) Cerebrum

A) One
B) Two
C) Four
D) Eight

A) Pons
B) Medulla
C) Cerebellum
D) Cerebrum

A) the exchange of gases between the lung and the blood capillaries in the lung.
B) pulmonary ventilation.
C) the exchange of gases between the blood capillaries and the tissues cells.
D) both A and B.

A) Increased cellular respiration occurs during exercise, causing a rise in plasma PCO2, which is detected by central chemoreceptors in the brain and perhaps peripheral chemoreceptors in the carotid sinus and aorta to cause an increase in respiration rate.
B) Decreased cellular respiration occurs during exercise, causing a rise in plasma PCO2, which is detected by central chemoreceptors in the brain and perhaps peripheral chemoreceptors in the carotid sinus and aorta to cause a decrease in respiration rate.
C) Exercise causes a decrease in cellular respiration by shifting peripheral chemoreceptors in the heart to cause retention of oxygen.
D) Increased cellular respiration occurs during exercise, causing a decrease in plasma PCO2, which is detected by central chemoreceptors in the brain and perhaps peripheral chemoreceptors in the carotid sinus and aorta to cause a decrease in respiration rate.

A) the exchange of gases between the lung and the blood capillaries in the lung.
B) pulmonary ventilation.
C) the exchange of gases between the blood capillaries and the tissue cells.
D) both A and B.