ventilation

(noun)

The bodily process of breathing, the inhalation of air to provide oxygen, and the exhalation of spent air to remove carbon dioxide.

Related Terms

Examples of ventilation in the following topics:

  • Pressure Changes During Pulmonary Ventilation

    • Ventilation is the rate at which gas enters or leaves the lung.
    • Ventilation is generally expressed as volume of air times a respiratory rate.
    • Minute ventilation (VE): The amount of air entering  the lungs per minute.
    • The three types of ventilation are mathematically linked to one another, so changes in one ventilation rate can cause the change of the other.
    • Alveolar ventilation is the most important type of ventilation for measuring how much oxygen actually gets into the body, which can initiate negative feedback mechanisms to try and increase alveolar ventilation despite the increase in dead space.

  • Dead Space: V/Q Mismatch

    • This is referred to as ventilation/perfusion (V/Q) mismatch.
    • Dead space is created when no ventilation and/or perfusion takes place.
    • The lung has the capability to compensate for mismatches in ventilation and perfusion.
    • If ventilation is greater than perfusion, the arterioles dilate and the bronchioles constrict, increasing perfusion while reducing ventilation.
    • A physiological shunt can develop if there is infection or edema in the lung which decreases ventilation, but does not affect perfusion; thus, the ventilation/perfusion ratio is affected.

  • Respiratory Distress Syndrome

    • This condition is often fatal, usually requiring mechanical ventilation and admission to an intensive care unit.
    • Ventilation is usually delivered through oro-tracheal intubation, or tracheostomy whenever prolonged ventilation (≥2 weeks) is deemed inevitable.
    • However, mechanical ventilation may constitute a risk factor for the development, or the worsening, of ARDS.
    • Aside from the infectious complications arising from invasive ventilation with tracheal intubation, positive-pressure ventilation directly alters lung mechanics during ARDS.
    • This adds up to the impaired oxygenation which is the central problem of ARDS, as well as to respiratory acidosis, which is often caused by ventilation techniques such as permissive hypercapnia which attempt to limit ventilator-induced lung injury in ARDS.

  • Functional Anatomy of the Respiratory System

    • Ventilation is the rate at which gas enters or leaves the lung.
    • In respiratory physiology, ventilation rate is the rate at which gas enters or leaves the lung.
    • There are several different terms used to describe the nuances of the ventilation rate.
    • Minute Ventilation (VE): The amount of air entering  the lungs per minute.
    • Dead Space Ventilation (VD): The amount of air per unit of time that doesn't reach the alveoli.

  • Chemoreceptor Regulation of Breathing

    • Their increased ventilation rate will remove too much carbon dioxide from their body.
    • In cases of acidosis, feedback will increase ventilation to remove more carbon dioxide to reduce the hydrogen ion concentration.
    • Conversely, vomiting removes hydrogen ions from the body (as the stomach contents are acidic), which will cause decreased ventilation to correct alkalosis.
    • In cases where oxygen intake is too low, feedback increases ventilation to increase oxygen intake.
    • A more detailed example would be that if a person breathes through a long tube (such as a snorkeling mask) and has increased amounts of dead space, feedback will increase ventilation.

  • Getting over the hurdles

    • Under-floor ventilation and wiring and super-efficient windows and daylighting are also incorporated.
    • Construction expenses remain virtually unchanged (mostly because of a reduction in heating, ventilation and air-conditioning needs) with subsequent energy costs reduced by one-half to three-fourths.
    • Natural light and ventilation, the building's low energy and maintenance costs, a propensity to produce more income, and natural good looks and interior comfort means that everybody wins: the owners of the building, the occupants of the building, and the neighbourhood where the structure is located.

  • External Respiration

    • While a severe ventilation–perfusion mismatch indicates severe lung disease, minor imbalances can be corrected by maintaining air flow that is proportional to capillary blood flow, which maintains the balance of ventilation and perfusion.
    • In response, the arteries being supplied by the constricted airway undergo vasocontriction, reducing the flow of blood into those alveoli so that the perfusion doesn't become much greater relative to the decreased ventilation (a type of ventilation–perfusion mismatch called a shunt).
    • Ventilation adjusts from changes in PACO2.
    • When airflow becomes higher relative to perfusion, PACO2 decreases, so the bronchioles will constrict in order to maintain to the balance between airflow (ventilation) and perfusion.
    • External respiration is a result of partial pressure gradients, alveolar surface area, and ventilation and perfusion matching.

  • Basic Principles of Gas Exchange

    • The purpose of respiration is to perform gas exchange, a process that involves ventilation and perfusion and that relies on the laws of partial pressure.
    • Pulmonary ventilation provides air to the alveoli for this gas exchange process.
    • Two important aspects of gas exchange in the lung are ventilation and perfusion.
    • Ventilation is the movement of air into and out of the lungs, and perfusion is the flow of blood in the pulmonary capillaries.
    • For gas exchange to be efficient, the volumes involved in ventilation and perfusion should be compatible.

  • Chemical Composition of Bone

    • Carbon dioxide is produced constantly as the body's cells respire, and this CO2 will accumulate rapidly if the lungs do not adequately expel it through alveolar ventilation.
    • Acute respiratory acidosis occurs when an abrupt failure of ventilation occurs.
    • This failure in ventilation may be caused by depression of the central respiratory center by cerebral disease or drugs, inability to ventilate adequately due to neuromuscular disease (e.g., myasthenia gravis, amyotrophic lateral sclerosis, Guillain-Barré syndrome, muscular dystrophy), or airway obstruction related to asthma or chronic obstructive pulmonary disease (COPD) exacerbation.
    • During acute respiratory alkalosis, the person may lose consciousness where the rate of ventilation will resume to normal.
    • Respiratory alkalosis may be produced accidentally (iatrogenically) during excessive mechanical ventilation.

  • Disorders of Acid-Base Balance

    • Carbon dioxide is produced constantly as the body's cells respire, and this CO2 will accumulate rapidly if the lungs do not adequately expel it through alveolar ventilation.
    • Acute respiratory acidosis occurs when an abrupt failure of ventilation occurs.
    • This failure in ventilation may be caused by depression of the central respiratory center by cerebral disease or drugs, inability to ventilate adequately due to neuromuscular disease (e.g., myasthenia gravis, amyotrophic lateral sclerosis, Guillain-Barré syndrome, muscular dystrophy), or airway obstruction related to asthma or chronic obstructive pulmonary disease (COPD) exacerbation.
    • During acute respiratory alkalosis, the person may lose consciousness where the rate of ventilation will resume to normal.
    • Respiratory alkalosis may be produced accidentally (iatrogenically) during excessive mechanical ventilation.