Respiration | Animal Husbandry & Veterinary Science Optional for UPSC PDF Download

Mechanism of Respiration Simplified

  • Overview of Respiration:
    • Respiratory system facilitates the exchange of gases between air and blood.
    • Two main processes: external respiration (between blood and external environment) and internal respiration (between blood and body tissues).
  • Lung Structure:
    • Lungs are in the thoracic cavity, covered by visceral and parietal pleurae.
    • Pleural fluid maintains lung expansion through capillary cohesion.
  • Thoracic Cavity Movements:
    • Thoracic walls and diaphragm movements change thoracic cavity volume.
    • Diaphragmatic pleura and costal pleura create a potential space called phrenicocostal sinus.
    • Inspiration: Thoracic cavity expands, creating negative intrapleural pressure, causing lungs to expand.
    • Expiration: Thoracic cavity reduces, intrapleural pressure rises, and elastic lungs expel air.
  • Muscles Involved:
    • Inspiratory muscles: Expand thorax through cranial rib movement and lateral rib expansion.
    • External and internal intercostal muscles, transversus thoracis, and abdominal wall muscles contribute.
    • Diaphragm is the major muscle for respiration.
  • Breathing Process:
    • Inhalation is an active process.
    • Exhalation is primarily passive, driven by elastic lung recoil.

Transport and Exchange of Gases Simplified

Role of Hemoglobin

  • Blood can carry more oxygen and carbon dioxide due to hemoglobin in red blood cells.
  • Hemoglobin combines reversibly with oxygen and carbon dioxide, enhancing gas transport in blood.
  • Without hemoglobin, blood volume would need to be 75 times greater to meet oxygen and carbon dioxide needs.

Oxygen Combination with Hemoglobin

  • Oxygen combines with hemoglobin to form oxyhemoglobin, regulated by oxygen partial pressure in blood plasma.
  • Each gram of hemoglobin can chemically bind with 1.36 ml of oxygen.
  • Oxygen uptake is not directly proportional to oxygen partial pressure; it follows an S-shaped curve influenced by factors like carbon dioxide, pH, ionic concentration, and temperature.

Influence of Carbon Dioxide and pH

  • Increased carbon dioxide or blood pH enhances the release of oxygen from oxyhemoglobin.
  • Oxygen transfer to tissues is facilitated by carbon dioxide; carbamino-hemoglobin formation reduces oxygen affinity, and lower blood pH promotes oxygen release.

Carbon Dioxide Transport

  • Most carbon dioxide combines with other substances, forming carbonic acid, bicarbonate ion, and carbamino-hemoglobin.
  • About one-fifth of carbon dioxide in blood is in carbamino-hemoglobin form.
  • Special transport mechanisms enable the exchange of plasma carbon dioxide, carbonic acid, and bicarbonate ion within red blood cells.
  • Carbon dioxide dissociation is influenced by the presence of oxygen.

Carbon Dioxide Exchange

  • Role of Carbonic Anhydrase:
    • Carbonic anhydrase is an enzyme that speeds up the conversion of carbon dioxide to carbonic acid.
    • Adequacy of carbon dioxide exchange in tissues and lungs is determined by this enzyme.
  • Tissue Level Exchange:
    • Physically dissolved carbon dioxide moves from tissues to capillaries, increasing plasma carbon dioxide pressure.
    • Simultaneously, oxygen diffuses from blood to tissues.
    • Chloride shift maintains electrical balance in erythrocytes, countering outward diffusion of bicarbonate ion.
  • Pulmonary Level Exchange:
    • At the pulmonary level, the process reverses for the release of carbon dioxide and absorption of oxygen.
    • Five percent of absorbed carbon dioxide dissolves in plasma, while the rest forms plasma bicarbonate and carbamino-hemoglobin in erythrocytes.

Neural Control of Respiration

  • Muscles Involved:
    • Diaphragm, a key breathing muscle, is innervated by phrenic nerves (from spinal roots C3, C4, C5).
    • Intercostal muscles (ventral branches of thoracic nerves T1-T12) and other muscles assist in respiration.
  • Motor Act of Breathing:
    • Breathing starts with diaphragm contraction and muscle actions coordinated by spinal and cranial nerves.
    • Abdominal muscles are innervated by thoracic and lumbar nerves.
  • Respiratory Centers in Medulla Oblongata:
    • Rhythm and limits of breathing are controlled by respiratory centers in the medulla oblongata.
    • These centers integrate information from peripheral receptors, chemosensitive areas in the brain, and higher nervous centers.
  • Efferent Impulses:
    • Efferent impulses from respiratory centers travel over phrenic and intercostal nerves to control muscle contractions.

Question for Respiration
Try yourself:
What is the main muscle involved in respiration?
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Brain Control of Respiration

  • Brain Stem Respiratory Centers:
    • Brain stem components, particularly the pons and medulla, play a crucial role in respiratory regulation.
    • Pons contains respiratory centers—pneumotaxic and apneustic—that influence breathing rate and rhythm.
    • Medulla houses inspiratory and expiratory centers, acting as pacemakers for the respiratory cycle.
  • Interaction between Pneumotaxic and Apneustic Centers:
    • Pneumotaxic center inhibits apneustic center, leading to the cessation of the inspiratory phase.
    • Apneustic center facilitates the medullary inspiratory center during normal respiration.
    • Vagus afferents and pneumotaxic center modulate the role of the apneustic center.

Chemoreceptors

  • Chemoreceptor Network:
    • Chemoreceptors are sensors in the carotid and aortic bodies responsible for monitoring blood's chemical composition.
    • Stimulated by changes in partial pressures of carbon dioxide, oxygen, and pH.
  • Types of Hypoxia and Chemoreceptor Activity:
    • Four types of hypoxia affect chemoreceptor activity, except silent anemic hypoxia.
    • Hypoxic chemoreflex becomes significant when the partial pressure of oxygen drops to around 66 mm Hg.
  • Excitatory Locus for Carbon Dioxide:
    • The main stimulator for carbon dioxide is in the medulla's central chemoreceptor (C1).
    • Superficial cells near the fourth ventricle are chemosensitive, sensing changes in cerebrospinal fluid.
  • Chemoreceptor System as a Backup Mechanism:
    • Chemoreceptor system acts as a reserve mechanism supporting the higher nervous system.
    • Chemoreceptors in arterial blood serve as error correctors, particularly those in the brain sensitive to cerebrospinal fluid composition.
    • They don't regulate ventilation during acute episodes but contribute significantly over minutes and hours.

Hypoxia and Its Types

Definition: Hypoxia occurs when the partial pressure of oxygen is below normal, while anoxia is the absence of oxygen.

Types of Hypoxia

  • Ambient Hypoxia:
    • Low oxygen levels in the environment affecting the entire body.
    • Found in high altitudes, enclosed spaces, or with certain anesthetic agents.
    • Diseases causing reduced breathing lead to arterial hypoxia.
  • Anaemic Hypoxia:
    • Caused by insufficient functional hemoglobin.
    • Seen after bleeding, in venous anemias, and when hemoglobin binds with carbon monoxide.
  • Stagnant Hypoxia:
    • Result of general or local circulation failure.
  • Histotoxic Hypoxia:
    • Tissues unable to use oxygen in normal processes (e.g., cyanide poisoning).

High Altitude Stress

  • Animals at high altitudes face significant respiratory challenges.
  • Economic impact on domestic animals, and physiological responses to hypoxia can be studied.

High Altitude Risks for Cattle

  • Cattle at high altitudes may develop conditions like risket disease.
  • Chronic hypertension in the pulmonary circuit leads to right ventricular hypertrophy and congestive failure.
  • Survival may require returning to lower altitudes.

Response to Low Oxygen

  • Lower arterial oxygen pressure stimulates carotid and aortic bodies (chemoreceptors).
  • Increased chemoreceptor output, heightened phrenic nerve discharge, and boosted ventilation.
  • Hypoxia-induced ventilation response initially causes a rapid drop in alveolar CO2 pressure, leading to temporary inhibition of ventilation.
  • Overall, a balance between hypoxic stimulus and hypocapnic inhibition results in a relatively minor increase in ventilation.

Question for Respiration
Try yourself:
What is the main function of the pneumotaxic center?
View Solution

Bird Respiration Simplified

Unique Features of Avian Respiration

  • Small lungs attached to ribs, limiting expansion.
  • Presence of large, poorly vascularized air sacs.
  • Active contraction during both inhalation and exhalation.
  • Unidirectional air flow through primary, secondary, and tertiary bronchi.
  • Gaseous exchange occurs in air capillaries branching off tertiary bronchi.

Respiratory System Overview

  • Begins with external nares leading to nasal cavities.
  • Trachea divides into two primary bronchi with the syrinx (vocal organ) at the division.
  • Syringeal muscles control vocal sounds by manipulating membranes in the trachea and bronchi.
  • Primary bronchi connect to lungs, further branching into secondary and tertiary bronchi.
  • Air sacs outside the lungs function as airways with limited gas exchange.
  • Pneumatic bones of birds are not connected to air sacs.

Ventilation and Lung Function

  • Lungs compressed during inhalation, expanded during exhalation by sternum and rib movements.
  • Air sacs are filled during inhalation, emptying the lungs.

Respiratory Characteristics

  • Avian lung lacks structures similar to the mammalian diaphragm.
  • Respiratory rates vary, from about 5 per minute in the ostrich to over 100 in small birds.
  • Resting and flight tidal volumes differ, with increased rates during flight.

Gas Exchange and Regulation

  • Gaseous exchange in avian lungs governed by diffusion, similar to mammals.
  • Respiratory center in the medulla regulates respiration, sensitive to factors like pH and blood temperature.
  • Pulmonary receptors in the lungs play a crucial role in carbon dioxide regulation.
  • Other receptors in the upper respiratory tract respond to external stimuli, influencing respiration.

Question for Respiration
Try yourself:
Which of the following is a unique feature of avian respiration?
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The document Respiration | Animal Husbandry & Veterinary Science Optional for UPSC is a part of the UPSC Course Animal Husbandry & Veterinary Science Optional for UPSC.
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FAQs on Respiration - Animal Husbandry & Veterinary Science Optional for UPSC

1. What is the mechanism of respiration?
Ans. The mechanism of respiration involves the inhalation of oxygen and the exhalation of carbon dioxide. During inhalation, the diaphragm contracts and the rib cage expands, creating a negative pressure in the lungs, which allows air to enter. Oxygen from the inhaled air is transferred to the bloodstream through the alveoli in the lungs. In the bloodstream, oxygen binds to red blood cells and is transported to the body's tissues. At the same time, carbon dioxide, a waste product, is released from the tissues into the bloodstream and transported back to the lungs. During exhalation, the diaphragm relaxes and the rib cage returns to its resting position, expelling carbon dioxide from the lungs.
2. How are gases transported and exchanged in the respiratory system?
Ans. Gases are transported and exchanged in the respiratory system through the process of diffusion. In the alveoli of the lungs, oxygen from the inhaled air diffuses across the thin walls of the alveoli into the surrounding capillaries. This oxygen then binds to hemoglobin in red blood cells and is transported to the body's tissues. At the same time, carbon dioxide, which is produced as a waste product by the body's cells, diffuses from the tissues into the capillaries. It is then carried back to the lungs, where it diffuses from the capillaries into the alveoli and is exhaled.
3. What is hypoxia and what are its types?
Ans. Hypoxia is a condition characterized by a deficiency of oxygen in the body's tissues. It can be caused by various factors, including high altitudes, lung diseases, heart problems, and exposure to certain toxins. There are four types of hypoxia: 1. Hypoxic hypoxia: This type of hypoxia occurs when there is a reduced supply of oxygen to the lungs, such as in high-altitude environments or when there is a problem with the respiratory system. 2. Anemic hypoxia: Anemic hypoxia occurs when there is a decrease in the amount of oxygen-carrying capacity of the blood, usually due to a decrease in the number of red blood cells or a decrease in the amount of hemoglobin. 3. Circulatory hypoxia: Circulatory hypoxia occurs when there is a problem with the circulation of blood, preventing the delivery of oxygen to the tissues. This can be caused by heart failure, shock, or other circulatory problems. 4. Histotoxic hypoxia: Histotoxic hypoxia occurs when the body's cells are unable to use the oxygen that is delivered to them due to the presence of toxins or drugs that interfere with cellular respiration.
4. How does respiration in birds differ from respiration in humans?
Ans. Respiration in birds differs from respiration in humans in several ways: 1. Birds have a more efficient respiratory system compared to humans. They have rigid lungs and air sacs that allow for a continuous flow of oxygenated air through their lungs, resulting in a higher oxygen uptake. 2. Birds have a higher metabolic rate than humans, which requires more oxygen for energy production. Their respiratory system is adapted to meet this high demand for oxygen. 3. Unlike humans, birds do not have a diaphragm. Instead, they rely on the movement of their intercostal muscles and the expansion of their rib cage to facilitate respiration. 4. Birds have a unique air sac system that allows them to store and circulate air throughout their body. This system helps to maintain a constant supply of oxygen even during strenuous activities like flying.
5. What are some frequently asked questions about respiration on the UPSC exam?
Ans. Some frequently asked questions about respiration on the UPSC exam may include: 1. Explain the process of gas exchange in the alveoli. 2. Describe the role of hemoglobin in transporting oxygen in the bloodstream. 3. What are the factors that affect lung capacity? 4. Discuss the respiratory adaptations in organisms living at high altitudes. 5. Explain the mechanism of breathing in humans, including the role of the diaphragm and intercostal muscles.
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