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Extracellular fluid

February 16, 2024

In cell biology, extracellular fluid (ECF) denotes all body fluid outside the cells of any multicellular organism. Total body water in healthy adults is about 50–60% (range 45 to 75%) of total body weight;[1] women and the obese typically have a lower percentage than lean men.[2] Extracellular fluid makes up about one-third of body fluid, the remaining two-thirds is intracellular fluid within cells.[3] The main component of the extracellular fluid is the interstitial fluid that surrounds cells.

The distribution of the total body water in mammals between the intracellular compartment and the extracellular compartment, which is, in turn, subdivided into interstitial fluid and smaller components, such as the blood plasma, the cerebrospinal fluid and lymph

Extracellular fluid is the internal environment of all multicellular animals, and in those animals with a blood circulatory system, a proportion of this fluid is blood plasma.[4] Plasma and interstitial fluid are the two components that make up at least 97% of the ECF. Lymph makes up a small percentage of the interstitial fluid.[5] The remaining small portion of the ECF includes the transcellular fluid (about 2.5%). The ECF can also be seen as having two components – plasma and lymph as a delivery system, and interstitial fluid for water and solute exchange with the cells.[6]

The extracellular fluid, in particular the interstitial fluid, constitutes the body's internal environment that bathes all of the cells in the body. The ECF composition is therefore crucial for their normal functions, and is maintained by a number of homeostatic mechanisms involving negative feedback. Homeostasis regulates, among others, the pH, sodium, potassium, and calcium concentrations in the ECF. The volume of body fluid, blood glucose, oxygen, and carbon dioxide levels are also tightly homeostatically maintained.

The volume of extracellular fluid in a young adult male of 70 kg (154 lbs) is 20% of body weight – about fourteen liters. Eleven liters are interstitial fluid and the remaining three liters are plasma.[7]

Components edit

The main component of the extracellular fluid (ECF) is the interstitial fluid, or tissue fluid, which surrounds the cells in the body. The other major component of the ECF is the intravascular fluid of the circulatory system called blood plasma. The remaining small percentage of ECF includes the transcellular fluid. These constituents are often called "fluid compartments". The volume of extracellular fluid in a young adult male of 70 kg, is 20% of body weight – about fourteen liters.

Interstitial fluid edit

See also: Fluid compartments § Interstitial compartment, and Lymph § Development

Interstitial fluid is essentially comparable to plasma. The interstitial fluid and plasma make up about 97% of the ECF, and a small percentage of this is lymph.

Interstitial fluid is the body fluid between blood vessels and cells,[8] containing nutrients from capillaries by diffusion and holding waste products discharged by cells due to metabolism.[9][10] 11 liters of the ECF are interstitial fluid and the remaining three liters are plasma.[7] Plasma and interstitial fluid are very similar because water, ions, and small solutes are continuously exchanged between them across the walls of capillaries, through pores and capillary clefts.

Interstitial fluid consists of a water solvent containing sugars, salts, fatty acids, amino acids, coenzymes, hormones, neurotransmitters, white blood cells and cell waste-products. This solution accounts for 26% of the water in the human body. The composition of interstitial fluid depends upon the exchanges between the cells in the biological tissue and the blood.[11] This means that tissue fluid has a different composition in different tissues and in different areas of the body.

The plasma that filters through the blood capillaries into the interstitial fluid does not contain red blood cells or platelets as they are too large to pass through but can contain some white blood cells to help the immune system.

Once the extracellular fluid collects into small vessels (lymph capillaries) it is considered to be lymph, and the vessels that carry it back to the blood are called the lymphatic vessels. The lymphatic system returns protein and excess interstitial fluid to the circulation.

The ionic composition of the interstitial fluid and blood plasma vary due to the Gibbs–Donnan effect. This causes a slight difference in the concentration of cations and anions between the two fluid compartments.

Transcellular fluid edit

See also: Fluid compartments § Transcellular compartment

Transcellular fluid is formed from the transport activities of cells, and is the smallest component of extracellular fluid. These fluids are contained within epithelial lined spaces. Examples of this fluid are cerebrospinal fluid, aqueous humor in the eye, serous fluid in the serous membranes lining body cavities, perilymph and endolymph in the inner ear, and joint fluid.[2][12] Due to the varying locations of transcellular fluid, the composition changes dramatically. Some of the electrolytes present in the transcellular fluid are sodium ions, chloride ions, and bicarbonate ions.

Function edit

 
Cell membrane details between extracellular and intracellular fluid
 
Sodium–potassium pump and the diffusion between extracellular fluid and intracellular fluid

Extracellular fluid provides the medium for the exchange of substances between the ECF and the cells, and this can take place through dissolving, mixing and transporting in the fluid medium.[13] Substances in the ECF include dissolved gases, nutrients, and electrolytes, all needed to maintain life.[14] ECF also contains materials secreted from cells in soluble form, but which quickly coalesce into fibers (e.g. collagen, reticular, and elastic fibres) or precipitates out into a solid or semisolid form (e.g. proteoglycans which form the bulk of cartilage, and the components of bone). These and many other substances occur, especially in association with various proteoglycans, to form the extracellular matrix, or the "filler" substance, between the cells throughout the body.[15] These substances occur in the extracellular space, and are therefore all bathed or soaked in ECF, without being part of it.

Oxygenation edit

One of the main roles of extracellular fluid is to facilitate the exchange of molecular oxygen from blood to tissue cells and for carbon dioxide, CO2, produced in cell mitochondria, back to the blood. Since carbon dioxide is about 20 times more soluble in water than oxygen, it can relatively easily diffuse in the aqueous fluid between cells and blood.[16]

However, hydrophobic molecular oxygen has very poor water solubility and prefers hydrophobic lipid crystalline structures.[17][18] As a result of this, plasma lipoproteins can carry significantly more O2 than in the surrounding aqueous medium.[19][20]

If hemoglobin in erythrocytes is the main transporter of oxygen in the blood, plasma lipoproteins may be its only carrier in the ECF.

The oxygen-carrying capacity of lipoproteins, reduces in ageing and inflammation. This results in changes of ECF functions, reduction of tissue O2 supply and contributes to development of tissue hypoxia. These changes in lipoproteins are caused by oxidative or inflammatory damage.[21]

Regulation edit

The internal environment is stabilised in the process of homeostasis. Complex homeostatic mechanisms operate to regulate and keep the composition of the ECF stable. Individual cells can also regulate their internal composition by various mechanisms.[22]

 
Differences in the concentrations of ions giving the membrane potential

There is a significant difference between the concentrations of sodium and potassium ions inside and outside the cell. The concentration of sodium ions is considerably higher in the extracellular fluid than in the intracellular fluid.[23] The converse is true of the potassium ion concentrations inside and outside the cell. These differences cause all cell membranes to be electrically charged, with the positive charge on the outside of the cells and the negative charge on the inside. In a resting neuron (not conducting an impulse) the membrane potential is known as the resting potential, and between the two sides of the membrane is about −70 mV.[24]

This potential is created by sodium–potassium pumps in the cell membrane, which pump sodium ions out of the cell, into the ECF, in return for potassium ions which enter the cell from the ECF. The maintenance of this difference in the concentration of ions between the inside of the cell and the outside, is critical to keep normal cell volumes stable, and also to enable some cells to generate action potentials.[25]

In several cell types voltage-gated ion channels in the cell membrane can be temporarily opened under specific circumstances for a few microseconds at a time. This allows a brief inflow of sodium ions into the cell (driven in by the sodium ion concentration gradient that exists between the outside and inside of the cell). This causes the cell membrane to temporarily depolarize (lose its electrical charge) forming the basis of action potentials.

The sodium ions in the ECF also play an important role in the movement of water from one body compartment to the other. When tears are secreted, or saliva is formed, sodium ions are pumped from the ECF into the ducts in which these fluids are formed and collected. The water content of these solutions results from the fact that water follows the sodium ions (and accompanying anions) osmotically.[26][27] The same principle applies to the formation of many other body fluids.

Calcium ions have a great propensity to bind to proteins.[28] This changes the distribution of electrical charges on the protein, with the consequence that the 3D (or tertiary) structure of the protein is altered.[29][30] The normal shape, and therefore function of very many of the extracellular proteins, as well as the extracellular portions of the cell membrane proteins, is dependent on a very precise ionized calcium concentration in the ECF. The proteins that are particularly sensitive to changes in the ECF ionized calcium concentration are several of the clotting factors in the blood plasma, which are functionless in the absence of calcium ions, but become fully functional on the addition of the correct concentration of calcium salts.[23][28] The voltage gated sodium ion channels in the cell membranes of nerves and muscle have an even greater sensitivity to changes in the ECF ionized calcium concentration.[31] Relatively small decreases in the plasma ionized calcium levels (hypocalcemia) cause these channels to leak sodium into the nerve cells or axons, making them hyper-excitable, thus causing spontaneous muscle spasms (tetany) and paraesthesia (the sensation of "pins and needles") of the extremities and round the mouth.[29][31][32] When the plasma ionized calcium rises above normal (hypercalcemia) more calcium is bound to these sodium channels having the opposite effect, causing lethargy, muscle weakness, anorexia, constipation and labile emotions.[32][33]

The tertiary structure of proteins is also affected by the pH of the bathing solution. In addition, the pH of the ECF affects the proportion of the total amount of calcium in the plasma which occurs in the free, or ionized form, as opposed to the fraction that is bound to protein and phosphate ions. A change in the pH of the ECF therefore alters the ionized calcium concentration of the ECF. Since the pH of the ECF is directly dependent on the partial pressure of carbon dioxide in the ECF, hyperventilation, which lowers the partial pressure of carbon dioxide in the ECF, produces symptoms that are almost indistinguishable from low plasma ionized calcium concentrations.[29]

The extracellular fluid is constantly "stirred" by the circulatory system, which ensures that the watery environment which bathes the body's cells is virtually identical throughout the body. This means that nutrients can be secreted into the ECF in one place (e.g. the gut, liver, or fat cells) and will, within about a minute, be evenly distributed throughout the body. Hormones are similarly rapidly and evenly spread to every cell in the body, regardless of where they are secreted into the blood. Oxygen taken up by the lungs from the alveolar air is also evenly distributed at the correct partial pressure to all the cells of the body. Waste products are also uniformly spread to the whole of the ECF, and are removed from this general circulation at specific points (or organs), once again ensuring that there is generally no localized accumulation of unwanted compounds or excesses of otherwise essential substances (e.g. sodium ions, or any of the other constituents of the ECF). The only significant exception to this general principle is the plasma in the veins, where the concentrations of dissolved substances in individual veins differ, to varying degrees, from those in the rest of the ECF. However, this plasma is confined within the waterproof walls of the venous tubes, and therefore does not affect the interstitial fluid in which the body's cells live. When the blood from all the veins in the body mixes in the heart and lungs, the differing compositions cancel out (e.g. acidic blood from active muscles is neutralized by the alkaline blood homeostatically produced by the kidneys). From the left atrium onward, to every organ in the body, the normal, homeostatically regulated values of all of the ECF's components are therefore restored.

Interaction between the blood plasma, interstitial fluid and lymph edit

Further information: Starling equation and Microcirculation § Capillary exchange
 
Formation of interstitial fluid from blood
 
Diagram showing the formation of lymph from interstitial fluid (labeled here as "tissue fluid"). The tissue fluid is entering the blind ends of lymph capillaries (shown as deep green arrows).

The arterial blood plasma, interstitial fluid and lymph interact at the level of the blood capillaries. The capillaries are permeable and water can move freely in and out. At the arteriolar end of the capillary the blood pressure is greater than the hydrostatic pressure in the tissues.[34][23] Water will therefore seep out of the capillary into the interstitial fluid. The pores through which this water moves are large enough to allow all the smaller molecules (up to the size of small proteins such as insulin) to move freely through the capillary wall as well. This means that their concentrations across the capillary wall equalize, and therefore have no osmotic effect (because the osmotic pressure caused by these small molecules and ions – called the crystalloid osmotic pressure to distinguish it from the osmotic effect of the larger molecules that cannot move across the capillary membrane – is the same on both sides of capillary wall).[34][23]

The movement of water out of the capillary at the arteriolar end causes the concentration of the substances that cannot cross the capillary wall to increase as the blood moves to the venular end of the capillary. The most important substances that are confined to the capillary tube are plasma albumin, the plasma globulins and fibrinogen. They, and particularly the plasma albumin, because of its molecular abundance in the plasma, are responsible for the so-called "oncotic" or "colloid" osmotic pressure which draws water back into the capillary, especially at the venular end.[34]

The net effect of all of these processes is that water moves out of and back into the capillary, while the crystalloid substances in the capillary and interstitial fluids equilibrate. Since the capillary fluid is constantly and rapidly renewed by the flow of the blood, its composition dominates the equilibrium concentration that is achieved in the capillary bed. This ensures that the watery environment of the body's cells is always close to their ideal environment (set by the body's homeostats).

A small proportion of the solution that leaks out of the capillaries is not drawn back into the capillary by the colloid osmotic forces. This amounts to between 2-4 liters per day for the body as a whole. This water is collected by the lymphatic system and is ultimately discharged into the left subclavian vein, where it mixes with the venous blood coming from the left arm, on its way to the heart.[23] The lymph flows through lymph capillaries to lymph nodes where bacteria and tissue debris are removed from the lymph, while various types of white blood cells (mainly lymphocytes) are added to the fluid. In addition the lymph which drains the small intestine contains fat droplets called chylomicrons after the ingestion of a fatty meal.[28] This lymph is called chyle which has a milky appearance, and imparts the name lacteals (referring to the milky appearance of their contents) to the lymph vessels of the small intestine.[35]

Extracellular fluid may be mechanically guided in this circulation by the vesicles between other structures. Collectively this forms the interstitium, which may be considered a newly identified biological structure in the body.[36] However, there is some debate over whether the interstitium is an organ.[37]

Electrolytic constituents edit

Main cations:[38]

Main anions:[38]

[39]

See also edit

References edit

  1. ^ Chumlea, W. Cameron; Guo, Shumei S.; Zeller, Christine M.; Reo, Nicholas V.; Siervogel, Roger M. (1999-07-01). "Total body water data for white adults 18 to 64 years of age: The Fels Longitudinal Study". Kidney International. 56 (1): 244–252. doi:10.1046/j.1523-1755.1999.00532.x. ISSN 0085-2538. PMID 10411699.
  2. ^ a b "Fluid Physiology: 2.1 Fluid Compartments". www.anaesthesiamcq.com. Retrieved 2019-11-28.
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  8. ^ Wiig, Helge; Swartz, Melody A. (2012). "Interstitial Fluid and Lymph Formation and Transport: Physiological Regulation and Roles in Inflammation and Cancer". Physiological Reviews. American Physiological Society. 92 (3): 1005–1060. doi:10.1152/physrev.00037.2011. ISSN 0031-9333. PMID 22811424. S2CID 11394172.
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  16. ^ Arthurs, G.J.; Sudhakar, M (December 2005). "Carbon dioxide transport". Continuing Education in Anaesthesia, Critical Care & Pain. 5 (6): 207–210. doi:10.1093/bjaceaccp/mki050.
  17. ^ Bačič, G.; Walczak, T.; Demsar, F.; Swartz, H. M. (October 1988). "Electron spin resonance imaging of tissues with lipid-rich areas". Magnetic Resonance in Medicine. 8 (2): 209–219. doi:10.1002/mrm.1910080211. PMID 2850439. S2CID 41810978.
  18. ^ Windrem, David A.; Plachy, William Z. (August 1980). "The diffusion-solubility of oxygen in lipid bilayers". Biochimica et Biophysica Acta (BBA) - Biomembranes. 600 (3): 655–665. doi:10.1016/0005-2736(80)90469-1. PMID 6250601.
  19. ^ Petyaev, I. M.; Vuylsteke, A.; Bethune, D. W.; Hunt, J. V. (1998-01-01). "Plasma Oxygen during Cardiopulmonary Bypass: A Comparison of Blood Oxygen Levels with Oxygen Present in Plasma Lipid". Clinical Science. 94 (1): 35–41. doi:10.1042/cs0940035. ISSN 0143-5221. PMID 9505864.
  20. ^ Jackson, M. J. (1998-01-01). "Plasma Oxygen during Cardiopulmonary Bypass". Clinical Science. 94 (1): 1. doi:10.1042/cs0940001. ISSN 0143-5221. PMID 9505858.
  21. ^ Petyaev, Ivan M.; Hunt, James V. (April 1997). "Micellar acceleration of oxygen-dependent reactions and its potential use in the study of human low density lipoprotein". Biochimica et Biophysica Acta (BBA) - Lipids and Lipid Metabolism. 1345 (3): 293–305. doi:10.1016/S0005-2760(97)00005-2. PMID 9150249.
  22. ^ Pocock G, Richards CD (2006). Human physiology : the basis of medicine (3rd ed.). Oxford: Oxford University Press. p. 3. ISBN 978-0-19-856878-0.
  23. ^ a b c d e Tortora G (1987). Principles of anatomy and physiology (5th ed.). New York: Harper & Row, International. pp. 40, 49–50, 61, 268–274, 449–453, 456, 494–496, 530–552, 693–700. ISBN 978-0-06-046669-5.
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  29. ^ a b c Macefield G, Burke D (February 1991). "Paraesthesiae and tetany induced by voluntary hyperventilation. Increased excitability of human cutaneous and motor axons". Brain. 114 ( Pt 1B) (1): 527–40. doi:10.1093/brain/114.1.527. PMID 2004255.
  30. ^ Stryer L (1995). Biochemistry (Fourth ed.). New York: W.H. Freeman and Company. pp. 347, 348. ISBN 978-0-7167-2009-6.
  31. ^ a b Armstrong CM, Cota G (March 1999). "Calcium block of Na+ channels and its effect on closing rate". Proceedings of the National Academy of Sciences of the United States of America. 96 (7): 4154–7. Bibcode:1999PNAS...96.4154A. doi:10.1073/pnas.96.7.4154. PMC 22436. PMID 10097179.
  32. ^ a b Harrison TR. Principles of Internal Medicine (third ed.). New York: McGraw-Hill Book Company. pp. 170, 571–579.
  33. ^ Waters M (2009). "Hypercalcemia". InnovAiT. 2 (12): 698–701. doi:10.1093/innovait/inp143.
  34. ^ a b c Hall J (2011). Guyton and Hall textbook of medical physiology (12th ed.). Philadelphia, Pa.: Saunders/Elsevier. pp. 177–181. ISBN 978-1-4160-4574-8.
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  36. ^ Rettner R (27 March 2018). "Meet Your Interstitium, a Newfound "Organ"". Scientific American. Retrieved 28 March 2018.
  37. ^ "Is the Interstitium Really a New Organ?". The Scientist.
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  39. ^ Guyton & Hall Textbook of Medical Physiology (page 5)

External links edit

  • Britannica.com
  • Biology-online.org

February 16, 2024
extracellular, fluid, cell, biology, extracellular, fluid, denotes, body, fluid, outside, cells, multicellular, organism, total, body, water, healthy, adults, about, range, total, body, weight, women, obese, typically, have, lower, percentage, than, lean, make. In cell biology extracellular fluid ECF denotes all body fluid outside the cells of any multicellular organism Total body water in healthy adults is about 50 60 range 45 to 75 of total body weight 1 women and the obese typically have a lower percentage than lean men 2 Extracellular fluid makes up about one third of body fluid the remaining two thirds is intracellular fluid within cells 3 The main component of the extracellular fluid is the interstitial fluid that surrounds cells The distribution of the total body water in mammals between the intracellular compartment and the extracellular compartment which is in turn subdivided into interstitial fluid and smaller components such as the blood plasma the cerebrospinal fluid and lymphExtracellular fluid is the internal environment of all multicellular animals and in those animals with a blood circulatory system a proportion of this fluid is blood plasma 4 Plasma and interstitial fluid are the two components that make up at least 97 of the ECF Lymph makes up a small percentage of the interstitial fluid 5 The remaining small portion of the ECF includes the transcellular fluid about 2 5 The ECF can also be seen as having two components plasma and lymph as a delivery system and interstitial fluid for water and solute exchange with the cells 6 The extracellular fluid in particular the interstitial fluid constitutes the body s internal environment that bathes all of the cells in the body The ECF composition is therefore crucial for their normal functions and is maintained by a number of homeostatic mechanisms involving negative feedback Homeostasis regulates among others the pH sodium potassium and calcium concentrations in the ECF The volume of body fluid blood glucose oxygen and carbon dioxide levels are also tightly homeostatically maintained The volume of extracellular fluid in a young adult male of 70 kg 154 lbs is 20 of body weight about fourteen liters Eleven liters are interstitial fluid and the remaining three liters are plasma 7 Contents 1 Components 1 1 Interstitial fluid 1 2 Transcellular fluid 2 Function 3 Oxygenation 4 Regulation 5 Interaction between the blood plasma interstitial fluid and lymph 6 Electrolytic constituents 7 See also 8 References 9 External linksComponents editThe main component of the extracellular fluid ECF is the interstitial fluid or tissue fluid which surrounds the cells in the body The other major component of the ECF is the intravascular fluid of the circulatory system called blood plasma The remaining small percentage of ECF includes the transcellular fluid These constituents are often called fluid compartments The volume of extracellular fluid in a young adult male of 70 kg is 20 of body weight about fourteen liters Interstitial fluid edit See also Fluid compartments Interstitial compartment and Lymph Development Interstitial fluid is essentially comparable to plasma The interstitial fluid and plasma make up about 97 of the ECF and a small percentage of this is lymph Interstitial fluid is the body fluid between blood vessels and cells 8 containing nutrients from capillaries by diffusion and holding waste products discharged by cells due to metabolism 9 10 11 liters of the ECF are interstitial fluid and the remaining three liters are plasma 7 Plasma and interstitial fluid are very similar because water ions and small solutes are continuously exchanged between them across the walls of capillaries through pores and capillary clefts Interstitial fluid consists of a water solvent containing sugars salts fatty acids amino acids coenzymes hormones neurotransmitters white blood cells and cell waste products This solution accounts for 26 of the water in the human body The composition of interstitial fluid depends upon the exchanges between the cells in the biological tissue and the blood 11 This means that tissue fluid has a different composition in different tissues and in different areas of the body The plasma that filters through the blood capillaries into the interstitial fluid does not contain red blood cells or platelets as they are too large to pass through but can contain some white blood cells to help the immune system Once the extracellular fluid collects into small vessels lymph capillaries it is considered to be lymph and the vessels that carry it back to the blood are called the lymphatic vessels The lymphatic system returns protein and excess interstitial fluid to the circulation The ionic composition of the interstitial fluid and blood plasma vary due to the Gibbs Donnan effect This causes a slight difference in the concentration of cations and anions between the two fluid compartments Transcellular fluid edit See also Fluid compartments Transcellular compartment Transcellular fluid is formed from the transport activities of cells and is the smallest component of extracellular fluid These fluids are contained within epithelial lined spaces Examples of this fluid are cerebrospinal fluid aqueous humor in the eye serous fluid in the serous membranes lining body cavities perilymph and endolymph in the inner ear and joint fluid 2 12 Due to the varying locations of transcellular fluid the composition changes dramatically Some of the electrolytes present in the transcellular fluid are sodium ions chloride ions and bicarbonate ions Function edit nbsp Cell membrane details between extracellular and intracellular fluid nbsp Sodium potassium pump and the diffusion between extracellular fluid and intracellular fluidExtracellular fluid provides the medium for the exchange of substances between the ECF and the cells and this can take place through dissolving mixing and transporting in the fluid medium 13 Substances in the ECF include dissolved gases nutrients and electrolytes all needed to maintain life 14 ECF also contains materials secreted from cells in soluble form but which quickly coalesce into fibers e g collagen reticular and elastic fibres or precipitates out into a solid or semisolid form e g proteoglycans which form the bulk of cartilage and the components of bone These and many other substances occur especially in association with various proteoglycans to form the extracellular matrix or the filler substance between the cells throughout the body 15 These substances occur in the extracellular space and are therefore all bathed or soaked in ECF without being part of it Oxygenation editOne of the main roles of extracellular fluid is to facilitate the exchange of molecular oxygen from blood to tissue cells and for carbon dioxide CO2 produced in cell mitochondria back to the blood Since carbon dioxide is about 20 times more soluble in water than oxygen it can relatively easily diffuse in the aqueous fluid between cells and blood 16 However hydrophobic molecular oxygen has very poor water solubility and prefers hydrophobic lipid crystalline structures 17 18 As a result of this plasma lipoproteins can carry significantly more O2 than in the surrounding aqueous medium 19 20 If hemoglobin in erythrocytes is the main transporter of oxygen in the blood plasma lipoproteins may be its only carrier in the ECF The oxygen carrying capacity of lipoproteins reduces in ageing and inflammation This results in changes of ECF functions reduction of tissue O2 supply and contributes to development of tissue hypoxia These changes in lipoproteins are caused by oxidative or inflammatory damage 21 Regulation editThe internal environment is stabilised in the process of homeostasis Complex homeostatic mechanisms operate to regulate and keep the composition of the ECF stable Individual cells can also regulate their internal composition by various mechanisms 22 nbsp Differences in the concentrations of ions giving the membrane potentialThere is a significant difference between the concentrations of sodium and potassium ions inside and outside the cell The concentration of sodium ions is considerably higher in the extracellular fluid than in the intracellular fluid 23 The converse is true of the potassium ion concentrations inside and outside the cell These differences cause all cell membranes to be electrically charged with the positive charge on the outside of the cells and the negative charge on the inside In a resting neuron not conducting an impulse the membrane potential is known as the resting potential and between the two sides of the membrane is about 70 mV 24 This potential is created by sodium potassium pumps in the cell membrane which pump sodium ions out of the cell into the ECF in return for potassium ions which enter the cell from the ECF The maintenance of this difference in the concentration of ions between the inside of the cell and the outside is critical to keep normal cell volumes stable and also to enable some cells to generate action potentials 25 In several cell types voltage gated ion channels in the cell membrane can be temporarily opened under specific circumstances for a few microseconds at a time This allows a brief inflow of sodium ions into the cell driven in by the sodium ion concentration gradient that exists between the outside and inside of the cell This causes the cell membrane to temporarily depolarize lose its electrical charge forming the basis of action potentials The sodium ions in the ECF also play an important role in the movement of water from one body compartment to the other When tears are secreted or saliva is formed sodium ions are pumped from the ECF into the ducts in which these fluids are formed and collected The water content of these solutions results from the fact that water follows the sodium ions and accompanying anions osmotically 26 27 The same principle applies to the formation of many other body fluids Calcium ions have a great propensity to bind to proteins 28 This changes the distribution of electrical charges on the protein with the consequence that the 3D or tertiary structure of the protein is altered 29 30 The normal shape and therefore function of very many of the extracellular proteins as well as the extracellular portions of the cell membrane proteins is dependent on a very precise ionized calcium concentration in the ECF The proteins that are particularly sensitive to changes in the ECF ionized calcium concentration are several of the clotting factors in the blood plasma which are functionless in the absence of calcium ions but become fully functional on the addition of the correct concentration of calcium salts 23 28 The voltage gated sodium ion channels in the cell membranes of nerves and muscle have an even greater sensitivity to changes in the ECF ionized calcium concentration 31 Relatively small decreases in the plasma ionized calcium levels hypocalcemia cause these channels to leak sodium into the nerve cells or axons making them hyper excitable thus causing spontaneous muscle spasms tetany and paraesthesia the sensation of pins and needles of the extremities and round the mouth 29 31 32 When the plasma ionized calcium rises above normal hypercalcemia more calcium is bound to these sodium channels having the opposite effect causing lethargy muscle weakness anorexia constipation and labile emotions 32 33 The tertiary structure of proteins is also affected by the pH of the bathing solution In addition the pH of the ECF affects the proportion of the total amount of calcium in the plasma which occurs in the free or ionized form as opposed to the fraction that is bound to protein and phosphate ions A change in the pH of the ECF therefore alters the ionized calcium concentration of the ECF Since the pH of the ECF is directly dependent on the partial pressure of carbon dioxide in the ECF hyperventilation which lowers the partial pressure of carbon dioxide in the ECF produces symptoms that are almost indistinguishable from low plasma ionized calcium concentrations 29 The extracellular fluid is constantly stirred by the circulatory system which ensures that the watery environment which bathes the body s cells is virtually identical throughout the body This means that nutrients can be secreted into the ECF in one place e g the gut liver or fat cells and will within about a minute be evenly distributed throughout the body Hormones are similarly rapidly and evenly spread to every cell in the body regardless of where they are secreted into the blood Oxygen taken up by the lungs from the alveolar air is also evenly distributed at the correct partial pressure to all the cells of the body Waste products are also uniformly spread to the whole of the ECF and are removed from this general circulation at specific points or organs once again ensuring that there is generally no localized accumulation of unwanted compounds or excesses of otherwise essential substances e g sodium ions or any of the other constituents of the ECF The only significant exception to this general principle is the plasma in the veins where the concentrations of dissolved substances in individual veins differ to varying degrees from those in the rest of the ECF However this plasma is confined within the waterproof walls of the venous tubes and therefore does not affect the interstitial fluid in which the body s cells live When the blood from all the veins in the body mixes in the heart and lungs the differing compositions cancel out e g acidic blood from active muscles is neutralized by the alkaline blood homeostatically produced by the kidneys From the left atrium onward to every organ in the body the normal homeostatically regulated values of all of the ECF s components are therefore restored Interaction between the blood plasma interstitial fluid and lymph editFurther information Starling equation and Microcirculation Capillary exchange nbsp Formation of interstitial fluid from blood nbsp Diagram showing the formation of lymph from interstitial fluid labeled here as tissue fluid The tissue fluid is entering the blind ends of lymph capillaries shown as deep green arrows The arterial blood plasma interstitial fluid and lymph interact at the level of the blood capillaries The capillaries are permeable and water can move freely in and out At the arteriolar end of the capillary the blood pressure is greater than the hydrostatic pressure in the tissues 34 23 Water will therefore seep out of the capillary into the interstitial fluid The pores through which this water moves are large enough to allow all the smaller molecules up to the size of small proteins such as insulin to move freely through the capillary wall as well This means that their concentrations across the capillary wall equalize and therefore have no osmotic effect because the osmotic pressure caused by these small molecules and ions called the crystalloid osmotic pressure to distinguish it from the osmotic effect of the larger molecules that cannot move across the capillary membrane is the same on both sides of capillary wall 34 23 The movement of water out of the capillary at the arteriolar end causes the concentration of the substances that cannot cross the capillary wall to increase as the blood moves to the venular end of the capillary The most important substances that are confined to the capillary tube are plasma albumin the plasma globulins and fibrinogen They and particularly the plasma albumin because of its molecular abundance in the plasma are responsible for the so called oncotic or colloid osmotic pressure which draws water back into the capillary especially at the venular end 34 The net effect of all of these processes is that water moves out of and back into the capillary while the crystalloid substances in the capillary and interstitial fluids equilibrate Since the capillary fluid is constantly and rapidly renewed by the flow of the blood its composition dominates the equilibrium concentration that is achieved in the capillary bed This ensures that the watery environment of the body s cells is always close to their ideal environment set by the body s homeostats A small proportion of the solution that leaks out of the capillaries is not drawn back into the capillary by the colloid osmotic forces This amounts to between 2 4 liters per day for the body as a whole This water is collected by the lymphatic system and is ultimately discharged into the left subclavian vein where it mixes with the venous blood coming from the left arm on its way to the heart 23 The lymph flows through lymph capillaries to lymph nodes where bacteria and tissue debris are removed from the lymph while various types of white blood cells mainly lymphocytes are added to the fluid In addition the lymph which drains the small intestine contains fat droplets called chylomicrons after the ingestion of a fatty meal 28 This lymph is called chyle which has a milky appearance and imparts the name lacteals referring to the milky appearance of their contents to the lymph vessels of the small intestine 35 Extracellular fluid may be mechanically guided in this circulation by the vesicles between other structures Collectively this forms the interstitium which may be considered a newly identified biological structure in the body 36 However there is some debate over whether the interstitium is an organ 37 Electrolytic constituents editMain cations 38 Sodium Na 136 146 mM Potassium K 3 8 5 0 mM Calcium Ca2 1 0 1 4 mMMain anions 38 Chloride Cl 103 112 mM Bicarbonate HCO3 22 28 mM Phosphate HPO42 0 8 1 4 mM 39 See also editEffective circulating volume ECV Fluid compartmentsReferences edit Chumlea W Cameron Guo Shumei S Zeller Christine M Reo Nicholas V Siervogel Roger M 1999 07 01 Total body water data for white adults 18 to 64 years of age The Fels Longitudinal Study Kidney International 56 1 244 252 doi 10 1046 j 1523 1755 1999 00532 x ISSN 0085 2538 PMID 10411699 a b Fluid Physiology 2 1 Fluid Compartments www anaesthesiamcq com Retrieved 2019 11 28 Tortora G 1987 Principles of anatomy and physiology 5th ed New York NY Harper and Row p 693 ISBN 978 0 06 350729 6 Hillis D 2012 Principles of life Sunderland MA Sinauer Associates p 589 ISBN 978 1 4292 5721 3 Pocock G Richards CD 2006 Human physiology the basis of medicine 3rd ed Oxford Oxford University Press p 548 ISBN 978 0 19 856878 0 Canavan A Arant BS October 2009 Diagnosis and management of dehydration in children PDF American Family Physician 80 7 692 6 PMID 19817339 a b Hall J 2011 Guyton and Hall textbook of medical physiology 12th ed Philadelphia Pa Saunders Elsevier pp 286 287 ISBN 978 1 4160 4574 8 Wiig Helge Swartz Melody A 2012 Interstitial Fluid and Lymph Formation and Transport Physiological Regulation and Roles in Inflammation and Cancer Physiological Reviews American Physiological Society 92 3 1005 1060 doi 10 1152 physrev 00037 2011 ISSN 0031 9333 PMID 22811424 S2CID 11394172 Definition of interstitial fluid www cancer gov 2011 02 02 Retrieved 2022 03 08 Interstitial Fluid What is the Role of Interstitial Fluid Diabetes Community Support Education Recipes amp Resources 2019 07 22 Retrieved 2019 07 22 Widmaier Eric P Hershel Raff Kevin T Strang and Arthur J Vander Body Fluid Compartments Vander s Human Physiology The Mechanisms of Body Function 14th ed New York McGraw Hill 2016 400 401 Print Constanzo LS 2014 Physiology 5th ed Elsevier Saunders p 264 ISBN 9781455708475 Tortora G 1987 Principles of anatomy and physiology 5th ed Harper international ed New York Harper amp Row pp 61 62 ISBN 978 0 06 046669 5 Tortora G 1987 Principles of anatomy and physiology 5th ed Harper international ed New York Harper amp Row p 17 ISBN 978 0 06 046669 5 Voet D Voet J Pratt C 2016 Fundamentals of Biochemistry Life at the Molecular Level Hoboken New Jersey John Wiley amp Sons p 235 ISBN 978 1 118 91840 1 Arthurs G J Sudhakar M December 2005 Carbon dioxide transport Continuing Education in Anaesthesia Critical Care amp Pain 5 6 207 210 doi 10 1093 bjaceaccp mki050 Bacic G Walczak T Demsar F Swartz H M October 1988 Electron spin resonance imaging of tissues with lipid rich areas Magnetic Resonance in Medicine 8 2 209 219 doi 10 1002 mrm 1910080211 PMID 2850439 S2CID 41810978 Windrem David A Plachy William Z August 1980 The diffusion solubility of oxygen in lipid bilayers Biochimica et Biophysica Acta BBA Biomembranes 600 3 655 665 doi 10 1016 0005 2736 80 90469 1 PMID 6250601 Petyaev I M Vuylsteke A Bethune D W Hunt J V 1998 01 01 Plasma Oxygen during Cardiopulmonary Bypass A Comparison of Blood Oxygen Levels with Oxygen Present in Plasma Lipid Clinical Science 94 1 35 41 doi 10 1042 cs0940035 ISSN 0143 5221 PMID 9505864 Jackson M J 1998 01 01 Plasma Oxygen during Cardiopulmonary Bypass Clinical Science 94 1 1 doi 10 1042 cs0940001 ISSN 0143 5221 PMID 9505858 Petyaev Ivan M Hunt James V April 1997 Micellar acceleration of oxygen dependent reactions and its potential use in the study of human low density lipoprotein Biochimica et Biophysica Acta BBA Lipids and Lipid Metabolism 1345 3 293 305 doi 10 1016 S0005 2760 97 00005 2 PMID 9150249 Pocock G Richards CD 2006 Human physiology the basis of medicine 3rd ed Oxford Oxford University Press p 3 ISBN 978 0 19 856878 0 a b c d e Tortora G 1987 Principles of anatomy and physiology 5th ed New York Harper amp Row International pp 40 49 50 61 268 274 449 453 456 494 496 530 552 693 700 ISBN 978 0 06 046669 5 Tortora G 1987 Principles of Anatomy and Physiology Harper amp Row p 269 ISBN 978 0 06 046669 5 Tortora G 2011 Principles of anatomy and physiology 13th ed Hoboken N J Wiley pp 73 74 ISBN 978 0 470 64608 3 Tortora G Anagnostakos N 1987 Principles of anatomy and physiology 5th ed New York NY Harper and Row pp 34 621 693 694 ISBN 978 0 06 350729 6 Data pcwww liv ac uk a b c Stryer L 1995 Biochemistry Fourth ed New York W H Freeman and Company pp 255 256 347 348 697 698 ISBN 0 7167 2009 4 a b c Macefield G Burke D February 1991 Paraesthesiae and tetany induced by voluntary hyperventilation Increased excitability of human cutaneous and motor axons Brain 114 Pt 1B 1 527 40 doi 10 1093 brain 114 1 527 PMID 2004255 Stryer L 1995 Biochemistry Fourth ed New York W H Freeman and Company pp 347 348 ISBN 978 0 7167 2009 6 a b Armstrong CM Cota G March 1999 Calcium block of Na channels and its effect on closing rate Proceedings of the National Academy of Sciences of the United States of America 96 7 4154 7 Bibcode 1999PNAS 96 4154A doi 10 1073 pnas 96 7 4154 PMC 22436 PMID 10097179 a b Harrison TR Principles of Internal Medicine third ed New York McGraw Hill Book Company pp 170 571 579 Waters M 2009 Hypercalcemia InnovAiT 2 12 698 701 doi 10 1093 innovait inp143 a b c Hall J 2011 Guyton and Hall textbook of medical physiology 12th ed Philadelphia Pa Saunders Elsevier pp 177 181 ISBN 978 1 4160 4574 8 Williams PL Warwick R Dyson M Bannister LH 1989 Gray s Anatomy Thirty seventh ed Edinburgh Churchill Livingstone p 821 ISBN 0443 041776 Rettner R 27 March 2018 Meet Your Interstitium a Newfound Organ Scientific American Retrieved 28 March 2018 Is the Interstitium Really a New Organ The Scientist a b Diem K Lentner C 1970 Blood Inorganic substances in Scientific Tables Seventh ed Basle Switzerland CIBA GEIGY Ltd pp 561 568 Guyton amp Hall Textbook of Medical Physiology page 5 External links editBritannica com Biology online org Retrieved from https en wikipedia org w index php title Extracellular fluid amp oldid 1187655514, wikipedia, wiki, book, books, library,

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