Deck 11: The Blood

Pulmonary surfactant is secreted by Type II alveolar cells.

The inspiratory and expiratory neurons both display pacemaker activity.

During hyperventilation, arterial P_CO2 levels decrease because CO₂ is blown off more rapidly than it is being produced in the tissues.

Systemic arterial P_O2 is greater than tissue P_O2.

Administering O₂ to patients with severe chronic lung disease will not depress their drive to breathe.

The 500 mL of air that is inspired is the same 500 mL of air that enters the alveoli during a single breath.

The partial pressure of nitrogen in the atmosphere is greater than the partial pressure of oxygen in the atmosphere.

Exhaled air passes from the larynx through the trachea.

Newborn respiratory distress syndrome is caused by an excess of pulmonary surfactant.

Boyle's law states that the pressure exerted by a gas varies directly with the volume of the gas.

An increase in airway resistance and an increase in alveolar surface tension both increase the work of breathing.

The pneumotaxic and apneustic centres are located in the cerebellum.

The peripheral chemoreceptors are not activated during carbon monoxide poisoning despite the fact that the total O₂ content in the blood can become lethally low.

If there is a deficient supply of pulmonary surfactant, the lungs become more compliant.

Increased acidity at the tissue cells stimulates increased dissociation of oxyhaemoglobin.

Slow, deep breathing is more effective for increasing alveolar ventilation than is rapid, shallow breathing.

Pulmonary surfactant decreases surface tension to a greater degree in large alveoli than in small alveoli.

The most important factor that determines the extent to which haemoglobin is saturated with oxygen is the blood P_O2.

Arterial P_O2 remains normal or may even increase slightly during exercise, despite the fact that O₂ consumption by the tissues is greatly increased.

At the end of inspiration and at the end of expiration, intra-alveolar pressure is always equal to atmospheric pressure.

At a constant temperature, the pressure that a gas exerts depends on the volume that it occupies.

Intrapleural pressure is usually less than atmospheric pressure.

The combination of Hb and CO₂ is known as carbamino haemoglobin.

Alveolar P_O2 is higher following inspiration than following expiration.

The bronchioles are rigid, nonmuscular airways encircled by a series of cartilaginous rings.

Inspiration is always an active process.

The alveoli are encircled by capillaries.

At the systemic capillaries, the P_O2 is in the range of the steep portion of the O_2-Hb curve.

Intrapleural pressure normally does not equilibrate with the intra-alveolar pressure.

To produce a normal tidal volume, the expiratory muscles must be stimulated.

At the end of inspiration and at the end of expiration, intrapleural pressure is always equal to atmospheric pressure.

Respiration is reflexively inhibited by alkalosis caused by a reduction in concentration of non-carbon dioxide-generated H⁺, the result of which is accumulation of H⁺-generating carbon dioxide to restore the acid-base balance toward normal.

Pulmonary surfactant reduces the work of breathing and increases lung stability by increasing alveolar surface tension.

Gases are transported during external respiration by active transport mechanisms.

Respiration is accomplished entirely by the respiratory system.

A slight decrease in arterial P_O2 below normal is a more potent stimulus toward increasing respiration than is a slight increase in P_CO2 above normal.

Elastic recoil refers to the tendency of the chest wall to expand.

A molecule of nitrogen gas exerts more pressure than a molecule of oxygen gas because nitrogen gas is a larger molecule.

The skeletal muscles for breathing are located in the walls of the lungs.

O₂ levels are much more closely regulated than CO₂ levels in the arterial blood.

Air flow through the smaller bronchioles can be adjusted by varying the contractile activity of the smooth muscle within their walls.

A highly compliant lung is easier to stretch than a less compliant one.

Emphysema can be brought on by recurrent episodes of asthma and/or chronic bronchitis.

Carbonic anhydrase catalyzes the formation of the oxyhaemoglobin.

The respiratory system provides a route for water and heat elimination.

Deep and slow breaths usually result in the greatest alveolar ventilation rates.

Stimulation of the sympathetic nervous system and release of epinephrine lead to an increase in airway resistance.

During external respiration, the P_CO2 is greater in the blood of the pulmonary capillaries than in the alveoli.

The internal intercostal muscles are inspiratory muscles because they lift the ribs upward and outward to enlarge the thoracic cavity.

The partial pressure of a gas in blood depends on the amount that is physically dissolved and not on the total content of the gas present in the blood.

If a person is breathing rapidly, it is safe to assume that he or she is getting adequate ventilation.

Expiration is always a passive process.

In the plateau region of the O₂-Hb curve, a large decrease in P_O2 results in a small decrease in Hb saturation, whereas in the steep portion of the curve, a small decrease in P_O2 results in a large decrease in percent Hb saturation.

The tidal volume is the sum of the vital capacity, expiratory reserve volume, and inspiratory reserve volume.

If the tidal volume is 500 mL and the anatomic dead space volume is 150 mL, only 350 mL of air enters the alveoli during inspiration.

The respiratory centre is located in the cerebral cortex.

Patients suffering from chronic obstructive pulmonary disease generally have more trouble exhaling than inhaling.

Both the respiratory system and the circulatory system are involved in the process of respiration.

During external respiration, the P_O2 is greater in the alveoli than in the blood of the pulmonary capillaries.

Pneumothorax develops from the accumulation of fluid in the alveoli.

The most important factor controlling respiration is the P_O2 of arterial blood.

The primary factor believed to be responsible for stimulating the profound and abrupt increase in ventilation during exercise is increased arterial P_CO2.

Systemic arterial P_CO2 is less than tissue P_CO2.

Intrapleural pressure is negative to maintain lung inflation.

The respiratory system is the only system involved with the exchange of gas between the cells of an organism and the external environment.

According to the law of LaPlace, the magnitude of the inward-directed collapsing pressure of a spherical bubble is directly proportional to both the surface tension and the radius of the bubble.

When the inspiratory neurons stop firing, the expiratory muscles contract.

Receptors in the CNS that detect changes in arterial P_CO2 are actually sensitive to the H⁺ concentration of the brain extracellular fluid.

The residual volume is the amount of air remaining in the lungs at the end of a normal expiration.

The respiratory airways filter, warm, and humidify incoming air.

Pores of Kohn permit air flow between adjacent alveoli, a process known as collateral ventilation.

The quantity of O₂ that will diffuse between the alveolar air and pulmonary blood depends solely on the partial pressure gradients that exist between the alveoli and the blood.

All respiratory airways are held open by cartilaginous rings.

The pleural cavity normally is not in direct communication with the lungs or atmosphere.

Alveolar partial pressures do not fluctuate to any extent between inspiration and expiration.

Pulmonary surfactant increases alveolar surface tension and does not affect lung expansion.

The quantity of air that will flow into and out of the lungs depends solely on the radius of the respiratory airways.

O₂ moves from the alveoli to the blood by active transport.

In the breathing cycle, the atmospheric pressure normally does not change.