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Mechanism of Breathing

Breathing has two stages: Inspiration (inhaling air) and Expiration (exhaling air). Movement of air is due to the pressure gradient between the lungs and the atmosphere.

Inspiration

Inspiration happens when the intra-pulmonary pressure is lower than atmospheric pressure, creating a negative pressure inside the lungs.

Steps involved:

  • Diaphragm contracts: Increases the volume of the thoracic cavity along the antero-posterior axis.
  • External intercostal muscles contract: Lifts the ribs and sternum, increasing thoracic volume along the dorso-ventral axis.
  • Increased thoracic volume leads to increased pulmonary volume, lowering intra-pulmonary pressure.
  • Air flows into the lungs due to this pressure difference.

InspirationInspiration

Expiration

Expiration occurs when intra-pulmonary pressure becomes higher than atmospheric pressure.

Steps involved:

  • Diaphragm and intercostal muscles relax: The diaphragm and sternum return to their normal positions.
  • Thoracic and pulmonary volumes decrease, causing intra-pulmonary pressure to increase.
  • Air is expelled from the lungs as a result.

ExpirationExpiration

Muscle Involvement: Diaphragm and intercostal muscles (external and internal) are key for generating pressure gradients. Additional abdominal muscles can be used to enhance both inspiration and expiration.

Breathing Rate and Measurement: A healthy human breathes 12-16 times per minute. The volume of air during breathing can be measured with a spirometer, which helps assess pulmonary function.

Question for Mechanism of Breathing and Exchange of Gases
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What is the main muscle responsible for increasing the volume of the thoracic cavity during inspiration?
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Respiratory Volumes and Capacities

  • Tidal Volume (TV): The amount of air inhaled or exhaled during a normal breath, which is about 500 mL. A healthy person can breathe in or out approximately 6000 to 8000 mL of air per minute.
  • Inspiratory Reserve Volume (IRV): The extra volume of air that can be inhaled with force after a normal inhalation, averaging between 2500 mL to 3000 mL.
  • Expiratory Reserve Volume (ERV): The additional volume of air that can be exhaled with force after a normal exhalation, averaging between 1000 mL to 1100 mL.
  • Residual Volume (RV): The volume of air remaining in the lungs after a forcible exhalation, averaging between 1100 mL to 1200 mL.

By combining various respiratory volumes, different pulmonary capacities can be derived, which are useful in clinical diagnosis.

  • Inspiratory Capacity (IC): The total volume of air that can be inhaled after a normal exhalation, calculated as TV + IRV.
  • Expiratory Capacity (EC): The total volume of air that can be exhaled after a normal inhalation, calculated as TV + ERV.
  • Functional Residual Capacity (FRC): The volume of air remaining in the lungs after a normal exhalation, calculated as ERV + RV.
  • Vital Capacity (VC): The maximum volume of air that can be inhaled after a forced exhalation, or the maximum volume of air that can be exhaled after a forced inhalation. This includes ERV, TV, and IRV.
  • Total Lung Capacity (TLC): The total volume of air that can be accommodated in the lungs at the end of a forced inhalation, which includes RV, ERV, TV, and IRV, or VC + RV.

Question for Mechanism of Breathing and Exchange of Gases
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Which of the following respiratory volumes represents the maximum volume of air that can be inhaled after a forced exhalation?
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Exchange of Gases

Gas exchange primarily occurs in the alveoli, where O2(oxygen) and CO2(carbon dioxide) are exchanged between the blood and the tissues through a process called diffusion. This process relies on the difference in partial pressure or concentration gradient between the gases. Partial pressure is the pressure exerted by an individual gas in a mixture, indicated as pO2 for oxygen and pCO2 for carbon dioxide.

Partial Pressures (in mm Hg) of Oxygen and Carbon dioxide at Different Parts Involved in Diffusion in Comparison to those in AtmospherePartial Pressures (in mm Hg) of Oxygen and Carbon dioxide at Different Parts Involved in Diffusion in Comparison to those in Atmosphere

  • The rate of diffusion can be influenced by factors such as the solubility of the gases and the thickness of the membranes involved in the diffusion process.
  • In the alveoli, there is a concentration gradient that facilitates the movement of oxygen from the alveoli into the blood and subsequently into the tissues. Conversely, carbon dioxide moves from the tissues into the blood and then into the alveoli.
  • Although the concentration gradient for carbon dioxide is in the opposite direction, its higher solubility (20-25 times greater than that of oxygen) allows it to diffuse more readily through the membrane.

Diagrammatic representation of exchange of gases at the alveolus and the body tissues with blood and transport of oxygen and carbon dioxideDiagrammatic representation of exchange of gases at the alveolus and the body tissues with blood and transport of oxygen and carbon dioxide

The diffusion membrane consists of three main layers:
  • Thin squamous epithelium of the alveoli
  • Endothelium of the alveolar capillaries
  • Basement substance, which includes a thin basement membrane supporting the squamous epithelium and the basement membrane surrounding the endothelial cells of the capillaries
A Diagram of a section of an alveolus with a pulmonary capillary.
A Diagram of a section of an alveolus with a pulmonary capillary.

The total thickness of this membrane is less than a millimeter, making it conducive for the diffusion of gases.

Overall, the conditions in the body are optimal for the diffusion of oxygen from the alveoli to the tissues and the diffusion of carbon dioxide from the tissues to the alveoli.

Question for Mechanism of Breathing and Exchange of Gases
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Which layer is involved in the gas exchange process in the alveoli?
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The document Mechanism of Breathing and Exchange of Gases | Biology Class 11 - NEET is a part of the NEET Course Biology Class 11.
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FAQs on Mechanism of Breathing and Exchange of Gases - Biology Class 11 - NEET

1. What is the mechanism of inspiration in breathing?
Ans. The mechanism of inspiration involves the contraction of the diaphragm and intercostal muscles. When the diaphragm contracts, it moves downward, increasing the volume of the thoracic cavity. Simultaneously, the intercostal muscles contract, lifting the ribs and expanding the chest. This increase in volume decreases the pressure inside the thoracic cavity, causing air to flow into the lungs.
2. How does expiration occur in the breathing process?
Ans. Expiration is primarily a passive process during normal breathing. When the diaphragm and intercostal muscles relax, the thoracic cavity volume decreases, which increases the pressure inside the lungs. This pressure difference causes air to be expelled from the lungs out into the atmosphere. During forced expiration, the abdominal muscles and internal intercostal muscles can contract to push air out more forcefully.
3. What are the different respiratory volumes and capacities?
Ans. Respiratory volumes include tidal volume (the amount of air inhaled or exhaled during normal breathing), inspiratory reserve volume (the additional air that can be inhaled after a normal inhalation), expiratory reserve volume (the additional air that can be exhaled after a normal exhalation), and residual volume (the air remaining in the lungs after a forceful exhalation). Capacities are combinations of these volumes, such as vital capacity (the maximum amount of air a person can exhale after a maximum inhalation) and total lung capacity (the total amount of air the lungs can hold).
4. How is gas exchange facilitated in the lungs?
Ans. Gas exchange in the lungs occurs in the alveoli, tiny air sacs surrounded by capillaries. Oxygen from the inhaled air diffuses through the alveolar walls into the blood in the capillaries, while carbon dioxide from the blood diffuses into the alveoli to be exhaled. This exchange is driven by the concentration gradients of oxygen and carbon dioxide, with oxygen moving from areas of higher concentration in the alveoli to lower concentration in the blood, and vice versa for carbon dioxide.
5. What role do the respiratory muscles play in breathing?
Ans. The respiratory muscles, including the diaphragm and intercostal muscles, play a crucial role in the mechanics of breathing. The diaphragm, when contracted, increases the thoracic cavity’s volume, allowing for inhalation. The intercostal muscles assist by expanding and contracting the rib cage during breathing. In forced breathing, other muscles such as the abdominal muscles and neck muscles can also be recruited to aid in both inspiration and expiration, allowing for greater airflow during vigorous activities.
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