Haldane effect

The Haldane effect is a property of hemoglobin describes the ability of hemoglobin (Hb) to carry increased amounts of carbon dioxide (CO₂) in the deoxygenated state as opposed to the oxygenated state. The Haldane effects thus promotes uptake of CO₂ by Hb in peripheral tissues where it releases oxygen to the tissue, and conversely promotes release of CO₂ from Hb in the lungs where oxygen from inspired air again binds to Hb.

Haldane effect is a result of a difference in the acidity of the oxygenated and deoxygenated (reduced) forms of Hb, so that the less acidic deoxygenated form favours direct binding of CO₂ to Hb amino acid residues to form carbamino compounds (the more significant component), as well as the binding of H⁺ ions formed during the dissociation carbonic acid (to which CO₂ is converted by erythrocyte carbonic anhydrase) (and vice versa).

The Haldane effect approximately doubles the transport (binding and release) capacity of blood for CO₂. It is far more important in promoting CO₂ transport than the related Bohr effect is in promoting O₂ transport.^[1]

It was first described by John Scott Haldane.

Mechanism

Carbon dioxide is carried in blood in three forms: as dissolved gas, as dissociated carbonic acid (HCO⁻
₃), or bound to proteins in the form of carbamino compounds. The vast majority of CO₂ is conveyed as HCO⁻
₃, with only minor contribution from the other two forms, however, this does not reflect the significance of these forms to the loading and unloading of CO₂: of the total venous-arterial difference, ~60% is attributable to HCO⁻
₃, 30% to carbamino compounds, and 10% to dissolved CO₂.^[2]

Carbaminohemoglobin

Carbon dioxide binding to amino groups results in the formation of carbamino (-NH-COOH) compounds. Amino groups are available for binding at the N-terminals and at side-chains of arginine and lysine residues of hemoglobin. When carbon dioxide binds to these residues, carbaminohemoglobin is formed.^[3] The capacity of Hb to bind CO₂ in the form of carbamino groups is inversely proportional to the state of oxygenation of hemoglobin.^[4]

Almost all blood carbamino carriage of CO₂ is performed by Hb, and deoxygenated Hb has a 3.5-fold greater capacity for carbamino carriage than oxygenated Hb. In contrast, carbamino carriage by plasma proteins is rather insignificant and is also not favoured due to the absence of carbonic anhydrase in plasma.^[5]

Ion buffering

Buffering capacity of haemoglobin

Deoxygenated Hb is less acidic than oxygenated Hb, and therefore has a higher affinity for H⁺ ions (i.e. a better proton acceptor).^[2]

The imidazole group of histidine residues is virtually the sole amino acid residue capable of acting as a pH buffer within the physiological pH range, and accounts for the majority of Hb buffering power, with each Hb tetramer containing 38 histidine residues (buffering power of plasma proteins is far less and also almost entirely accounted by histidine residues). The hemes are attached to the globulins at imidazole groups of histidine residues, and the imidazoles' dissociation constant is highly dependent upon the (de)oxygenation state of Hb. Deoxygenation causes imidazole groups to become more basic, and - conversely - the acid form of imidazole groups weakens the binding of to O₂ Hb.^[5]

Ionic dissociation of CO₂ buffering

When dissolved in water, CO₂ is subject to the following dynamic chemical equilibrium:

CO₂ + H₂O ⇌ H
₂CO
₃ ⇌ H⁺ + HCO⁻
₃

CO₂ is normally slow to combine with water to form carbonic acid whereas carbonic acid immediately dissociates into H⁺ and HCO⁻
₃. However, erythrocytes contain the enzyme carbonic anhydrase which catalyses the formation of carbonic acid.^[2] HCO⁻
₃ is actively transported out of the cell in exchange for Cl^- anions to maintain electroneutrality of the cell (chloride shift), whereas H⁺ is retained within the cell and binds to deoxygenated Hb. In accordance with Le Chatelier's principle, clearance of the right-side products of the above chemical equilibrium will permits further formation of these products. In fact, the maximum catalytic rate of carbonic anhydrase is so rapid that its effectively limited by the speed with which buffers clear H⁺ from the vicinity of the enzyme.^[5]

Upon oxygenation of Hb in the lungs, its acidity increases, releasing H⁺ which recombines with HCO⁻
₃ to restitute gaseous CO₂ which can diffuse from the blood into the alveoli.^[1]

CO₂ also increases the osmolar content of the erythrocyte so that erythrocytes in deoxygenated blood are in fact somewhat greater in volume.^[2]

Clinical significance

In patients with lung disease, lungs may not be able to increase alveolar ventilation in the face of increased amounts of dissolved CO₂.^{[citation needed]}

This partially explains the observation that some patients with emphysema might have an increase in P_aCO₂ (partial pressure of arterial dissolved carbon dioxide) following administration of supplemental oxygen even if content of CO₂ stays equal.^[6]

References

^ ^a ^b Hall, John E.; Hall, Michael E. (2021). Guyton and Hall Textbook of Medical Physiology (14th ed.). Philadelphia, PA: Elsevier. p. 529. ISBN 978-0-323-59712-8.
^ ^a ^b ^c ^d West, John B.; Luks, Andrew (2016). West's Respiratory Physiology: The Essentials (10th ed.). Philadelphia: Wolters Kluwer. pp. 93–95. ISBN 978-1-4963-1011-8.
^ Lumb, AB (2000). Nunn's Applied Respiratory Physiology (5th ed.). Butterworth Heinemann. pp. 227–229. ISBN 0-7506-3107-4.
^ Teboul, Jean-Louis; Scheeren, Thomas (2017-01-01). "Understanding the Haldane effect". Intensive Care Medicine. 43 (1): 91–93. doi:10.1007/s00134-016-4261-3. ISSN 1432-1238. PMID 26868920. S2CID 31191748.
^ ^a ^b ^c Lumb, Andrew B.; Thomas, Caroline R. (2021). Nunn and Lumb's Applied Respiratory Physiology (9th ed.). Elsevier. pp. 124–127. ISBN 978-0-7020-7933-7.
^ Hanson, CW; Marshall BE; Frasch HF; Marshall C (January 1996). "Causes of hypercarbia with oxygen therapy in patients with chronic obstructive pulmonary disease". Critical Care Medicine. 24 (1): 23–28. doi:10.1097/00003246-199601000-00007. PMID 8565533.

External links

Nosek, Thomas M. "Section 4/4ch5/s4ch5_31". Essentials of Human Physiology. Archived from the original on 2015-12-09.

[:023-1] Hall, John E.; Hall, Michael E. (2021). Guyton and Hall Textbook of Medical Physiology (14th ed.). Philadelphia, PA: Elsevier. p. 529. ISBN 978-0-323-59712-8.

[:02-2] West, John B.; Luks, Andrew (2016). West's Respiratory Physiology: The Essentials (10th ed.). Philadelphia: Wolters Kluwer. pp. 93–95. ISBN 978-1-4963-1011-8.

[Nunn-3] Lumb, AB (2000). Nunn's Applied Respiratory Physiology (5th ed.). Butterworth Heinemann. pp. 227–229. ISBN 0-7506-3107-4.

[4] Teboul, Jean-Louis; Scheeren, Thomas (2017-01-01). "Understanding the Haldane effect". Intensive Care Medicine. 43 (1): 91–93. doi:10.1007/s00134-016-4261-3. ISSN 1432-1238. PMID 26868920. S2CID 31191748.

[:0-5] Lumb, Andrew B.; Thomas, Caroline R. (2021). Nunn and Lumb's Applied Respiratory Physiology (9th ed.). Elsevier. pp. 124–127. ISBN 978-0-7020-7933-7.

[Hanson-6] Hanson, CW; Marshall BE; Frasch HF; Marshall C (January 1996). "Causes of hypercarbia with oxygen therapy in patients with chronic obstructive pulmonary disease". Critical Care Medicine. 24 (1): 23–28. doi:10.1097/00003246-199601000-00007. PMID 8565533.

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v t e Respiratory physiology
Respiration	breath inhalation exhalation obligate nasal breathing respiratory rate respirometer pulmonary surfactant compliance elastic recoil hysteresivity airway resistance bronchial hyperresponsiveness constriction dilatation mechanical ventilation
Control	pons pneumotaxic center apneustic center medulla dorsal respiratory group ventral respiratory group chemoreceptors central peripheral pulmonary stretch receptor Hering–Breuer reflex
Lung volumes	VC FRC Vt dead space CC PEF calculations respiratory minute volume FEV1/FVC ratio Lung function tests spirometry body plethysmography peak flow meter nitrogen washout
Circulation	pulmonary circulation hypoxic pulmonary vasoconstriction pulmonary shunt
Interactions	ventilation (V) Perfusion (Q) Ventilation/perfusion ratio V/Q scan zones of the lung gas exchange pulmonary gas pressures alveolar gas equation alveolar–arterial gradient hemoglobin oxygen–hemoglobin dissociation curve (Oxygen saturation 2,3-BPG Bohr effect Haldane effect) carbonic anhydrase (chloride shift) oxyhemoglobin respiratory quotient arterial blood gas diffusion capacity (DLCO)
Insufficiency	high altitude death zone oxygen toxicity hypoxia