Hyponatremia pathophysiology: Difference between revisions
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==Overview== | ==Overview== | ||
Hyponatremia is defined as serum [[sodium]] less than 135 mEq/L (mmol/L). Sodium is the major [[electrolyte]] which determines serum [[osmolality]]. [[Hyponatremia]] is water balance disorder in which the ratio between sodium and water is disturbed. Water homeostasis is regulated mainly by two organs: [[hypothalamus]] by [[ADH]] secretion, kidney by water reabsorption or excretion. ADH is secreted due to alteration in serum osmolality or intravascular volume. Mechanisms in which different disorders cause hyponatremia involve ADH (secretion or action) and kidney function ( absorption or excretion). | Hyponatremia is defined as serum [[sodium]] less than 135 mEq/L (mmol/L). Sodium is the major [[electrolyte]] which determines serum [[osmolality]]. [[Hyponatremia]] is a water balance disorder in which the ratio between sodium and water is disturbed. Water homeostasis is regulated mainly by two organs: [[hypothalamus]] by [[ADH]] secretion or thirst, kidney by water reabsorption or excretion. [[ADH]] is secreted due to alteration in serum osmolality or intravascular volume. Mechanisms in which different [[Hyponatremia causes#Causes|disorders]] cause hyponatremia involve [[ADH]] (secretion or action) and kidney function ( absorption or excretion). [[ADH]] secretion is increased by increased osmolality of serum or decreased effective intravascular volume. | ||
==Pathophysiology== | ==Pathophysiology== | ||
Sodium is the main cation in the extracellular fluid, thus the plasma concentration of sodium is determinant of [[tonicity]] and serum [[osmolality]]. | Sodium is the main cation in the extracellular fluid, thus the plasma concentration of sodium is the determinant of [[tonicity]] and serum [[osmolality]]. | ||
The osmotic gradient of solutes that do not cross cell membranes constitutes serum '''[[Tonicity]]''' <ref name="Cell physiology sourcebook">{{cite book | last = Sperelakis | first = Nick | title = Cell physiology sourcebook : essentials of membrane biophysics | publisher = Elsevier/Academic Press | location = London, UK Waltham, MA, USA | year = 2012 | isbn = 978-0-12-387738-3 }}</ref> | The osmotic gradient of solutes that do not cross cell membranes constitutes serum '''[[Tonicity]]''' which determines the distribution of water in the body.<ref name="Cell physiology sourcebook">{{cite book | last = Sperelakis | first = Nick | title = Cell physiology sourcebook : essentials of membrane biophysics | publisher = Elsevier/Academic Press | location = London, UK Waltham, MA, USA | year = 2012 | isbn = 978-0-12-387738-3 }}</ref> | ||
'''Plasma tonicity''' = (Extracellular solute + Intracellular solute) / TBW | '''Plasma tonicity''' = (Extracellular solute + Intracellular solute) / TBW | ||
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<small>'''Normal Range'''= 275–295 mosm /kg (mmol /kg)</small> <ref name="HooperAbdelhamid2015">{{cite journal|last1=Hooper|first1=Lee|last2=Abdelhamid|first2=Asmaa|last3=Ali|first3=Adam|last4=Bunn|first4=Diane K|last5=Jennings|first5=Amy|last6=John|first6=W Garry|last7=Kerry|first7=Susan|last8=Lindner|first8=Gregor|last9=Pfortmueller|first9=Carmen A|last10=Sjöstrand|first10=Fredrik|last11=Walsh|first11=Neil P|last12=Fairweather-Tait|first12=Susan J|last13=Potter|first13=John F|last14=Hunter|first14=Paul R|last15=Shepstone|first15=Lee|title=Diagnostic accuracy of calculated serum osmolarity to predict dehydration in older people: adding value to pathology laboratory reports|journal=BMJ Open|volume=5|issue=10|year=2015|pages=e008846|issn=2044-6055|doi=10.1136/bmjopen-2015-008846}}</ref> | <small>'''Normal Range'''= 275–295 mosm /kg (mmol /kg)</small> <ref name="HooperAbdelhamid2015">{{cite journal|last1=Hooper|first1=Lee|last2=Abdelhamid|first2=Asmaa|last3=Ali|first3=Adam|last4=Bunn|first4=Diane K|last5=Jennings|first5=Amy|last6=John|first6=W Garry|last7=Kerry|first7=Susan|last8=Lindner|first8=Gregor|last9=Pfortmueller|first9=Carmen A|last10=Sjöstrand|first10=Fredrik|last11=Walsh|first11=Neil P|last12=Fairweather-Tait|first12=Susan J|last13=Potter|first13=John F|last14=Hunter|first14=Paul R|last15=Shepstone|first15=Lee|title=Diagnostic accuracy of calculated serum osmolarity to predict dehydration in older people: adding value to pathology laboratory reports|journal=BMJ Open|volume=5|issue=10|year=2015|pages=e008846|issn=2044-6055|doi=10.1136/bmjopen-2015-008846}}</ref> | ||
<small> | |||
{| class="wikitable" | {| class="wikitable" | ||
! colspan="2" |Normal range | ! colspan="2" |Normal range | ||
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|- | |- | ||
|[[Sodium]] <sup>‡</sup> | |[[Sodium]] <sup>‡</sup> | ||
|135-145 mEq/L | |135-145 mEq /L | ||
| rowspan="5" | | | rowspan="5" | | ||
* [[Osmolality]] is described as measure of the [[osmoles]] (Osm) of solute per kilogram of solvent (osmol/kg or Osm/kg)<ref name="pmid14524639">{{cite journal| author=Erstad BL| title=Osmolality and osmolarity: narrowing the terminology gap. | journal=Pharmacotherapy | year= 2003 | volume= 23 | issue= 9 | pages= 1085-6 | pmid=14524639 | doi= | pmc= | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=14524639 }} </ref> | * [[Osmolality]] is described as measure of the [[osmoles]] (Osm) of solute per kilogram of solvent (osmol /kg or Osm /kg)<ref name="pmid14524639">{{cite journal| author=Erstad BL| title=Osmolality and osmolarity: narrowing the terminology gap. | journal=Pharmacotherapy | year= 2003 | volume= 23 | issue= 9 | pages= 1085-6 | pmid=14524639 | doi= | pmc= | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=14524639 }} </ref> | ||
* [[Osmolarity]] is defined as the number of [[osmoles]] of [[solute]] per liter (L) of solution (osmol/L or Osm/L) | * [[Osmolarity]] is defined as the number of [[osmoles]] of [[solute]] per liter (L) of solution (osmol /L or Osm /L) | ||
<small>(one liter of plasma equals to one kilogram of plasma thus plasma osmolarity and plasma osmolality would be the same but osmolality is independent of temperature and pressure so it's the more stable unite of measurment)</small> | <small>(one liter of plasma equals to one kilogram of plasma thus plasma osmolarity and plasma osmolality would be the same but osmolality is independent of temperature and pressure so it's the more stable unite of measurment)</small> | ||
|- | |- | ||
|[[Potassium]] <sup>‡</sup> | |[[Potassium]] <sup>‡</sup> | ||
|3.5-5.1 mEq/L | |3.5-5.1 mEq /L | ||
|- | |- | ||
|[[Blood Urea Nitrogen]] | |[[Blood Urea Nitrogen]] | ||
|7-20 mg/dL (2.5-7.1 mmol/L) | |7-20 mg /dL<br>(2.5-7.1 mmol /L) | ||
|- | |- | ||
|[[Glucose]] | |[[Glucose]] | ||
|70-100 mg/dL ( 3.9-5.5 mmol/L) | |70-100 mg /dL<br>( 3.9-5.5 mmol /L) | ||
|- | |- | ||
|[[Serum osmolality]] | |[[Serum osmolality]] | ||
|275–295 mosm /kg (mmol /kg) † | |275–295 mosm/kg<br>(mmol /kg) † | ||
|} | |} | ||
</small> | |||
<small>‡ ''Mmol and Meq are the same for univalent ions like sodium, potassium''</small> | <small>‡ ''Mmol and Meq are the same for univalent ions like sodium, potassium''</small> | ||
<small>† ''mOsmol/kg = n x mmol/L, for Na<sup>+</sup>, Cl<sup>-</sup>, Ca<sup>2+</sup>, urea, and glucose, 1 mmol/L equals 1 mOsmol/kg because n=1 , for NaCl n=2''</small> | <small>† ''mOsmol /kg = n x mmol /L, for Na<sup>+</sup>, Cl<sup>-</sup>, Ca<sup>2+</sup>, urea, and glucose, 1 mmol /L equals 1 mOsmol /kg because n=1 , for NaCl n=2''</small> | ||
Plasma water is regulated by [[sensory organs]] (baroreceptors and hypothalamus osmoreceptors), antidiuretic hormone ( [[ADH]] or [[vasopressin]], [[AVP]]), and the [[kidney]]. | Plasma water is regulated by [[sensory organs]] (baroreceptors and hypothalamus osmoreceptors), antidiuretic hormone ( [[ADH]] or [[vasopressin]], [[AVP]]), and the [[kidney]]. | ||
Osmoreceptors in the [[hypothalamus]] are sensitive to the increased or decreased [[tonicity]] of serum. The primary brain osmoreceptors are located outside the [[blood-brain barrier]] in the lamina terminalis. Primary osmoreceptors are connected to brain areas responsible for ADH secretion and thirst by neuronal projections. Osmoreceptors can both stimulate and inhibit [[ADH]] secretion and thirst in response to hyper-and hypotonicity of serum, respectively <ref name="Verbalis2007">{{cite journal|last1=Verbalis|first1=J. G.|title=How Does the Brain Sense Osmolality?|journal=Journal of the American Society of Nephrology|volume=18|issue=12|year=2007|pages=3056–3059|issn=1046-6673|doi=10.1681/ASN.2007070825}}</ref> | Osmoreceptors in the [[hypothalamus]] are sensitive to the increased or decreased [[tonicity]] of serum ( magnocellular neurons). The primary brain osmoreceptors are located outside the [[blood-brain barrier]] in the lamina terminalis. Primary osmoreceptors are connected to brain areas responsible for ADH secretion and thirst by neuronal projections. Osmoreceptors can both stimulate and inhibit [[ADH]] secretion and thirst in response to hyper-and hypotonicity of serum, respectively.<ref name="Verbalis2007">{{cite journal|last1=Verbalis|first1=J. G.|title=How Does the Brain Sense Osmolality?|journal=Journal of the American Society of Nephrology|volume=18|issue=12|year=2007|pages=3056–3059|issn=1046-6673|doi=10.1681/ASN.2007070825}}</ref> | ||
'''ADH secretion from hypothalamus through posterior pituitary is increased by <ref>{{Cite journal | '''ADH secretion from hypothalamus through posterior pituitary is increased by:<ref>{{Cite journal | ||
| author = [[G. L. Robertson]] | | author = [[G. L. Robertson]] | ||
| title = Physiology of ADH secretion | | title = Physiology of ADH secretion | ||
| Line 61: | Line 61: | ||
| month = August | | month = August | ||
| pmid = 3476800 | | pmid = 3476800 | ||
}}</ref> <ref>{{Cite journal | }}</ref><ref>{{Cite journal | ||
| author = [[L. Share]] | | author = [[L. Share]] | ||
| title = Vasopressin, its bioassay and the physiological control of its release | | title = Vasopressin, its bioassay and the physiological control of its release | ||
| Line 71: | Line 71: | ||
| month = May | | month = May | ||
| pmid = 5337374 | | pmid = 5337374 | ||
}}</ref> | }}</ref>''' | ||
* ↑ [[Angiotensin II]] ( through activation of Renin-Angiotensin-Activation System) | * ↑ [[Angiotensin II]] ( through activation of Renin-Angiotensin-Activation System) | ||
* ↑ [[Sympathetic]] stimulation | * ↑ [[Sympathetic]] stimulation | ||
* ↑ Effective osmoles (Hypertonicity) | * ↑ Effective osmoles ( Hypertonicity) | ||
* ↓ [[Baroreceptors|Baroreceptor]] firing ( | * ↓ [[Baroreceptors|Baroreceptor]] firing ( ↓ effective intravascular volume) | ||
* ↓ Right atrium stretching | * ↓ Right atrium stretching | ||
[[ADH]] increases renal free water reabsorption from the [[collecting tubule]]<nowiki/>s which results in correction of plasma sodium toward the normal range. The [[vasopressin]] type 2 (V<sub>2</sub>) receptor in the basolateral membrane of the [[collecting tubule]] acts as the antidiuretic effect of [[ADH]]. Binding of ADH to [[V2 receptor]] <ref name=" | Baroreceptors are in carotid sinus, Juxtaglomerular cell, atrial pressure receptors, hepatic volume receptors, cerebrospinal fluid volume receptors. | ||
[[ADH]] increases renal free water reabsorption from the [[collecting tubule]]<nowiki/>s which results in correction of plasma sodium toward the normal range. The [[vasopressin]] type 2 (V<sub>2</sub>) receptor in the basolateral membrane of the [[collecting tubule]] acts as the antidiuretic effect of [[ADH]]. | |||
Binding of ADH to [[V2 receptor]] intensifies the action of intracellular [[cyclic adenosine monophosphate]] ( cAMP) which results in insertion of water channel ( [[Aquaporins|aquaporin]] 2) into the luminal membrane and increasing the numbers of aquaporin-2 mRNA level.<ref name="KwonHager2001">{{cite journal|last1=Kwon|first1=Tae-Hwan|last2=Hager|first2=Henrik|last3=Nejsum|first3=Lene N.|last4=Andersen|first4=Marie-Louise E.|last5=Fr[oslash]ki[aelig ]r|first5=J[oslash]rgen|last6=Nielsen|first6=S[oslash]ren|title=Physiology and pathophysiology of renal aquaporins|journal=Seminars in Nephrology|volume=21|issue=3|year=2001|pages=231–238|issn=02709295|doi=10.1053/snep.2001.21647}}</ref><ref name="HolmesLandry20032">{{cite journal|last1=Holmes|first1=Cheryl L|last2=Landry|first2=Donald W|last3=Granton|first3=John T|journal=Critical Care|volume=7|issue=6|year=2003|pages=427|issn=13648535|doi=10.1186/cc2337}}</ref><ref name="HolmesLandry2003">{{cite journal|last1=Holmes|first1=Cheryl L|last2=Landry|first2=Donald W|last3=Granton|first3=John T|journal=Critical Care|volume=7|issue=6|year=2003|pages=427|issn=13648535|doi=10.1186/cc2337}}</ref> | |||
As plasma water increases, plasma sodium concentration, [[osmolality]], and [[ADH]] secretion decrease and the collecting tubule becomes impermeable to water.[[File:Slide2.JPG|thumb|750px|center| Mechanism of action of ADH, (ɔ) Image courtesy of WikiDoc.org, by '''"[[User: Saeedeh Kowsarnia|Saeedeh Kowsarnia M.D]]"''']] | |||
Hyponatremia is defined as serum sodium less than 135 mEq/L (mmol/L). [[Hyponatremia]] is a water balance disorder which represents an imbalance in a ratio where total body water is more than total body solutes ( total body sodium and total body potassium). | Hyponatremia is defined as serum sodium less than 135 mEq/L (mmol/L). [[Hyponatremia]] is a water balance disorder which represents an imbalance in a ratio where total body water is more than total body solutes ( total body sodium and total body potassium). | ||
| Line 83: | Line 89: | ||
'''<big>Pathogenesis</big>''' | '''<big>Pathogenesis</big>''' | ||
[[Hyponatremia]] occurs when the release of [[ADH]] ([[AVP]]) is increased either physiologically appropriate due to decreased effective circulating volume, or inappropriately due to no physiologic reason. In response to the release of ADH, urine volume decreases and hyponatremia will develop especially when water intake exceeds urinary and insensible losses of water. Patients are typically classified based on their total body sodium as hypovolemic, euvolemic, and hypervolemia. | [[Hyponatremia]] occurs when the release of [[ADH]] ( [[AVP]]) is increased either physiologically appropriate due to decreased effective circulating volume, or inappropriately due to no physiologic reason. In response to the release of ADH, urine volume decreases and hyponatremia will develop especially when water intake exceeds urinary and insensible losses of water. Patients are typically classified based on their total body sodium as hypovolemic, euvolemic, and hypervolemia. | ||
'''<big>Hypovolemic hyponatremia</big>''' | '''<big>Hypovolemic hyponatremia</big>''' | ||
* '''Volume loss:''' GI loss, [[bleeding]] and [[insensible loss]] cause solute and water loss simultaneously which leads to the rise in [[ADH]] secretion. A considerable reduction in effective arterial blood volume increase release of | * '''Volume loss:''' GI loss, [[bleeding]] and [[insensible loss]] cause solute and water loss simultaneously which leads to the rise in [[ADH]] secretion. A considerable reduction in effective arterial blood volume increase release of [[ADH]] by [[baroreceptors]] rather than osmoreceptors. There is a marked release in [[ADH]] secretion by acute [[hypovolemia]] compared to the response that is caused by hypertonicity.<ref>{{Cite journal|year=1987|title=Osmoregulation and control of vasopressin secretion in healthy humans|journal=[[The American journal of physiology]]|volume=253|issue=5 Pt 2|pages=R671–R678|doi=10.1152/ajpregu.1987.253.5.R671|pmid=3318505|author=[[P. H. Baylis]]|month=November}}</ref> [[ADH]] increases free water reabsorption from collecting tubules by [[Arginine vasopressin receptor 2|V2 receptor]]<nowiki/>s and [[vascular resistance]] by V1 receptors. Replacement of losses with hypotonic fluid may cause further hyponatremia in addition to [[ADH]] effect. Hypovolemia caused by [[diarrhea]] induces sodium absorption from urine, results in low urine sodium. [[Vomiting]] caused hyponatremic hypovolemia which results in high urine sodium and low urine chloride due to bicarbonaturia and [[metabolic alkalosis]]. | ||
* '''Third spacing of fluid:''' Causes decreased intravascular volume which increases [[ADH]] secretion and water reabsorption. Decreased vascular volume induces the activity of the [[renin-angiotensin-aldosterone system]]. [[Aldosterone]] increases water and sodium absorption by the kidney. As a net result of [[ADH]] and aldosterone actions, water is absorbed more than sodium which causes [[hyponatremia]]. | * '''Third spacing of fluid:''' Causes decreased intravascular volume which increases [[ADH]] secretion and water reabsorption. Decreased vascular volume induces the activity of the [[renin-angiotensin-aldosterone system]]. [[Aldosterone]] increases water and sodium absorption by the kidney. As a net result of [[ADH]] and aldosterone actions, water is absorbed more than sodium which causes [[hyponatremia]]. | ||
* ''' | * '''Diuretics:''' [[Thiazides]] increase water reabsorption and water permeability of medullary part of collecting tubules which is independent of [[ADH]] action. Excretion of sodium and potassium to the urine causes further hyponatremia.<ref>{{Cite journal | ||
| author = [[K. R. Cesar]] & [[A. J. Magaldi]] | | author = [[K. R. Cesar]] & [[A. J. Magaldi]] | ||
| Line 110: | Line 116: | ||
| pmid = 10564239 | | pmid = 10564239 | ||
}}</ref> | }}</ref> In contrast, [[loop diuretics]] decrease the action of [[ADH]] on [[Medullary collecting duct|medullary]] part of collecting tubules by impairing medullary gradient.<ref>{{Cite journal | ||
| author = [[V. L. Szatalowicz]], [[P. D. Miller]], [[J. W. Lacher]], [[J. A. Gordon]] & [[R. W. Schrier]] | | author = [[V. L. Szatalowicz]], [[P. D. Miller]], [[J. W. Lacher]], [[J. A. Gordon]] & [[R. W. Schrier]] | ||
| Line 130: | Line 136: | ||
| pmid = 7053922 | | pmid = 7053922 | ||
}}</ref> | }}</ref> | ||
* '''Renal loss:''' Inappropriately loss of sodium in urine causes hypovolemia and [[ADH]] secretion. | * '''Renal loss:''' Inappropriately loss of sodium in urine causes hypovolemia and [[ADH]] secretion. | ||
** '''Salt-wasting nephropathy:''' Renal tubular dysfunction causes [[hyponatremia]] especially when sodium intake is reduced. The causes include Interstitial nephropathies, reflux nephropathies, recovery phase of [[ATN]], [[medullary cystic disease]] and post-obstructive uropathies. | ** '''Salt-wasting nephropathy:''' Renal tubular dysfunction causes [[hyponatremia]] especially when sodium intake is reduced. The causes include Interstitial nephropathies, reflux nephropathies, recovery phase of [[ATN]], [[medullary cystic disease]] and post-obstructive uropathies. | ||
** '''Bicarbonaturia:''' [[Renal tubular acidosis]] and [[metabolic alkalosis]] cause loss of [[Bicarbonates|bicarbonate]] and sodium in urine to balance charges in urine. | ** '''Bicarbonaturia:''' [[Renal tubular acidosis]] and [[metabolic alkalosis]] cause loss of [[Bicarbonates|bicarbonate]] and sodium in urine to balance charges in urine. | ||
** '''Cerebral salt-wasting syndrome:''' [[Subarachnoid hemorrhage]], [[ischemic stroke]], spontaneous [[intracerebral hemorrhage]] (ICH), [[craniotomy]], [[encephalitis]], [[meningitis]] and [[head trauma]] are considered the most common etiologies. The pathophysiology of [[Cerebral salt wasting syndrome|CSW]] syndrome is not completely understood. Decreased [[sympathetic]] activity to the kidneys and Increased [[brain natriuretic peptide]] are the most accepted hypothesis. Renin-aldosterone is decreased due to reduced sympathetic stimulation<ref name="KimJoo2009">{{cite journal|last1=Kim|first1=Dong Ki|last2=Joo|first2=Kwon Wook|title=Hyponatremia in Patients with Neurologic Disorders|journal=Electrolytes & Blood Pressure|volume=7|issue=2|year=2009|pages=51|issn=1738-5997|doi=10.5049/EBP.2009.7.2.51}}</ref> | ** '''Cerebral salt-wasting syndrome:''' [[Subarachnoid hemorrhage]], [[ischemic stroke]], spontaneous [[intracerebral hemorrhage]] (ICH), [[craniotomy]], [[encephalitis]], [[meningitis]] and [[head trauma]] are considered the most common etiologies. The pathophysiology of [[Cerebral salt wasting syndrome|CSW]] syndrome is not completely understood. Decreased [[sympathetic]] activity to the kidneys and Increased [[brain natriuretic peptide]] are the most accepted hypothesis. Renin-aldosterone is decreased due to reduced sympathetic stimulation.<ref name="KimJoo2009">{{cite journal|last1=Kim|first1=Dong Ki|last2=Joo|first2=Kwon Wook|title=Hyponatremia in Patients with Neurologic Disorders|journal=Electrolytes & Blood Pressure|volume=7|issue=2|year=2009|pages=51|issn=1738-5997|doi=10.5049/EBP.2009.7.2.51}}</ref> Increased [[natriuretic peptides]] causes sodium loss by kidney (natriuresis ) through increasing [[GFR]] and preventing sodium reabsorption in the [[collecting duct]].<ref name="DamarajuRajshekhar1997">{{cite journal|last1=Damaraju|first1=Sriram Chandra|last2=Rajshekhar|first2=Vedantam|last3=Chandy|first3=Mathew J.|title=Validation Study of a Central Venous Pressure-based Protocol for the Management of Neurosurgical Patients with Hyponatremia and Natriuresis|journal=Neurosurgery|volume=40|issue=2|year=1997|pages=312–317|issn=0148-396X|doi=10.1097/00006123-199702000-00015}}</ref> [[Natriuretic peptides]] inhibit [[aldosterone]] and [[ADH]] action. Reducing sympathetic outflow by [[natriuretic peptides]] decreases [[aldosterone]] secretion which lowers sodium level further.<ref>{{cite journal|doi=10.3275/7290}}</ref> | ||
** '''Osmotic diuresis:''' Urinary excretion of osmotically active solutes causes [[volume depletion]] and [[hyponatremia]]. [[Glucosuria]] and [[ketonuria]] in [[DKA]] and [[HHS]] obligate sodium and water loss even in the presence of [[hypovolemia]]. | ** '''Osmotic diuresis:''' Urinary excretion of osmotically active solutes causes [[volume depletion]] and [[hyponatremia]]. [[Glucosuria]] and [[ketonuria]] in [[DKA]] and [[HHS]] obligate sodium and water loss even in the presence of [[hypovolemia]]. | ||
** '''Mineralocorticoid deficiency:''' [[Adrenal]] insufficiency ( primary, [[Aldosterone deficiency I|aldosterone deficiency]]) leads to renal sodium loss and volume depletion, causing the release of [[ADH]] due to [[hypovolemia]]. Patients typically present with [[hypovolemia]], [[hyponatremia]], [[hyperkalemia]], decreased bicarbonate and increased urine sodium and inappropriate renal response in the setting of [[volume depletion]]. | ** '''Mineralocorticoid deficiency:''' [[Adrenal]] insufficiency ( primary, [[Aldosterone deficiency I|aldosterone deficiency]]) leads to renal sodium loss and volume depletion, causing the release of [[ADH]] due to [[hypovolemia]]. Patients typically present with [[hypovolemia]], [[hyponatremia]], [[hyperkalemia]], decreased bicarbonate and increased urine sodium and inappropriate renal response in the setting of [[volume depletion]]. | ||
'''<big>Hypervolemic hyponatremia</big>''' | '''<big>Hypervolemic hyponatremia</big>''' | ||
* '''Renal disease:''' Chronic or [[acute renal failure]] results in reduced functional [[nephron]] mass, decreased [[glomerular filtration rate]] (GFR) and therefore decreased capacity for water excretion. [[Nephrotic syndrome]] causes reduced effective circulatory volume | * '''Renal disease:''' Chronic or [[acute renal failure]] results in reduced functional [[nephron]] mass, decreased [[glomerular filtration rate]] (GFR) and therefore decreased capacity for water excretion. [[Nephrotic syndrome]] causes reduced effective circulatory volume due hypoproteinemia which results in increased [[ADH]] effect. | ||
* '''Clinical disorders:''' In [[Congestive heart failure]] ( [[CHF]]) and [[cirrhosis]], the reduction in effective arterial blood volume, resulting in persistent [[ADH]] activity despite hypoosmolar plasma. The ability to excrete water is also limited when the posterior [[pituitary]] continues to secrete [[ADH]] despite a low serum [[osmolality]] and plasma sodium concentration. Decreased effective arterial blood volume is sensed as [[hypovolemia]] which is the stronger stimulant of [[ADH]] secretion than osmolality of plasma. [[ADH]] is secreted without an osmotic stimulus if circulation is inadequate. Inpatients with [[cirrhosis]] decreased effective circulating volume is a result of arterial [[vasodilation]] of the [[splanchnic]] circulation, which is due to the increased [[Endothelial cell|endothelial]] release of [[nitric oxide]]. | * '''Clinical disorders:''' In [[Congestive heart failure]] ( [[CHF]]) and [[cirrhosis]], the reduction in effective arterial blood volume, resulting in persistent [[ADH]] activity despite hypoosmolar plasma. The ability to excrete water is also limited when the posterior [[pituitary]] continues to secrete [[ADH]] despite a low serum [[osmolality]] and plasma sodium concentration. Decreased effective arterial blood volume is sensed as [[hypovolemia]] which is the stronger stimulant of [[ADH]] secretion than osmolality of plasma. [[ADH]] is secreted without an osmotic stimulus if circulation is inadequate. Inpatients with [[cirrhosis]] decreased effective circulating volume is a result of arterial [[vasodilation]] of the [[splanchnic]] circulation, which is due to the increased [[Endothelial cell|endothelial]] release of [[nitric oxide]]. Moreover, large volume paracentesis in cases of refractory ascites can lead to more reduction of effective arterial volume, leading to postparacentesis circulatory dysfunction (PPCD) which worsens the renal failure and hyponatremia. <ref name="pmid33156095">{{cite journal| author=Alukal JJ, John S, Thuluvath PJ| title=Hyponatremia in Cirrhosis: An Update. | journal=Am J Gastroenterol | year= 2020 | volume= 115 | issue= 11 | pages= 1775-1785 | pmid=33156095 | doi=10.14309/ajg.0000000000000786 | pmc= | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=33156095 }} </ref> | ||
'''<big>Euvolemic hyponatremia</big>''' | |||
* '''Syndrome of inappropriate antidiuresis:''' The most common cause of hyponatremia (euvolemic) due to either an increased level of [[ADH]] or gain-of-function mutation of the [[V2 receptor]] of [[ADH]]. Inappropriate secretion or action of [[ADH]] in the absence of osmotic or hemodynamic stimulus is called [[Syndrome of inappropriate antidiuretic hormone|SIAD]] ( syndrome of inappropriate diuresis). Nephrogenic [[SIADH|SIAD]] has the same presentation but ADH level is normal. Nearly 10% of SIAD is nephrogenic. Recently, hyponatremia has been found associated with COVID-19 infection <ref name="pmid33435405">{{cite journal| author=Gheorghe G, Ilie M, Bungau S, Stoian AMP, Bacalbasa N, Diaconu CC| title=Is There a Relationship between COVID-19 and Hyponatremia? | journal=Medicina (Kaunas) | year= 2021 | volume= 57 | issue= 1 | pages= | pmid=33435405 | doi=10.3390/medicina57010055 | pmc=7827825 | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=33435405 }} </ref> . Interleukin-6 (IL-6), which has been showed to be involved in the pathophysiology of COVID-19 and is released by monocytes and macrophages plays an important role in development of hyponatremia; it induces the non-osmotic release of vasopressin <ref name="pmid32451971">{{cite journal| author=Berni A, Malandrino D, Parenti G, Maggi M, Poggesi L, Peri A| title=Hyponatremia, IL-6, and SARS-CoV-2 (COVID-19) infection: may all fit together? | journal=J Endocrinol Invest | year= 2020 | volume= 43 | issue= 8 | pages= 1137-1139 | pmid=32451971 | doi=10.1007/s40618-020-01301-w | pmc=7246958 | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=32451971 }} </ref>. This along with the cytokine cascade cause numerous renal pathological changes, such as acute kidney injury (AKI), tubular necrosis, dysfunction of the kidney proximal tubule, glomerulopathy and electrolyte abnormalities.Also, renal cells expressing the receptors of the virus (ACE2), may explain the damage to kidney and subsequent electrolyte imbalances. Approximately 60% of patients with COVID-19 and watery diarrhea have moderate hyponatremia as well. <ref name="pmid33435405">{{cite journal| author=Gheorghe G, Ilie M, Bungau S, Stoian AMP, Bacalbasa N, Diaconu CC| title=Is There a Relationship between COVID-19 and Hyponatremia? | journal=Medicina (Kaunas) | year= 2021 | volume= 57 | issue= 1 | pages= | pmid=33435405 | doi=10.3390/medicina57010055 | pmc=7827825 | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=33435405 }} </ref> | |||
<small> | |||
{| class="wikitable" | {| class="wikitable" | ||
!Diagnostic criteria of [[SIAD]] <ref>{{Cite journal | !Diagnostic criteria of [[SIAD]] <ref>{{Cite journal | ||
| Line 171: | Line 177: | ||
|- | |- | ||
| | | | ||
* | * Serum sodium <135 mEq/L | ||
* [[Plasma osmolality]] <275 mOsm/kg , <small>( NL=275–295 mOsm/kg)</small> | * [[Plasma osmolality]] <275 mOsm/kg , <small>( NL=275–295 mOsm/kg)</small> | ||
* [[ | * [[Urine]] concentration U<sub>Osm</sub> >100mOsm/kg , <small>(NL=500-800 mOsm/kg )</small> | ||
* [[Urine sodium]] >30 (20-40) mmol/L, with normal salt and water intake, <small>(NL=20 mEq/L)<sup>†</sup></small> | * [[Urine sodium]] >30 (20-40) mmol/L, with normal salt and water intake, <small>(NL=20 mEq/L)<sup>†</sup></small> | ||
| Line 183: | Line 189: | ||
* No recent use of [[diuretics]] | * No recent use of [[diuretics]] | ||
'''Supplemental criteria''' | '''Supplemental criteria''' | ||
* Serum [[uric acid]] < 0.24 mmol/l < | * Serum [[uric acid]] < 0.24 mmol/l <sup><big>‡</big></sup> (< 4 mg/dl), <small>(NL= 2.4-6.0 mg/dL (female), 3.4-7.0 mg/dL (male) )</small> | ||
* Serum [[urea]] < 3.6 mmol/l (< 21.6 mg/dl), <small>(NL= 2.5 to 7.1 mmol/L, 7 to 20 mg/dL)</small> | * Serum [[urea]] < 3.6 mmol/l (< 21.6 mg/dl), <small>(NL= 2.5 to 7.1 mmol/L, 7 to 20 mg/dL)</small> | ||
* Failure to correct [[hyponatremia]] after 0.9% saline infusion | * Failure to correct [[hyponatremia]] after 0.9% saline infusion | ||
| Line 192: | Line 198: | ||
|} | |} | ||
</small> | |||
<small>† Mmol and Meq are the same for univalent ions like sodium, potassium</small> | |||
‡ <small>mg/dl = molecular weight (MW) x mmol/l, for example MW for glucose and uric acid is 180 and 168 respectively</small> | |||
* '''Excess water intake:''' In exercise-associated hyponatremia, increased level of [[ADH]] due to [[hypovolemia]] and excess free water intake cause [[hyponatremia]]. In primary polydipsia, there is an increase in thirst, especially in psychotic patients. The osmotic threshold for [[thirst]] is lower than the threshold for [[ADH]] release. | |||
* '''Hormonal:''' [[Glucocorticoids]] have an inhibitory effect on [[ADH]] release by the [[Posterior pituitary gland|posterior pituitary]] so [[cortisol]] deficiency induces [[ADH]] secretion. [[Thyroid hormones|Thyroid hormone]] deficiency especially [[primary hypothyroidism]] causes [[hyponatremia]] and the mechanism is not well-understood. in patients who present with [[hypothyroidism]], there is an elevation to [[ADH]] level and reduction in [[GFR]] which means decreased ability to excrete diluted urine.<ref>{{Cite journal | |||
| author = [[R. W. Schrier]] & [[D. G. Bichet]] | |||
| title = Osmotic and nonosmotic control of vasopressin release and the pathogenesis of impaired water excretion in adrenal, thyroid, and edematous disorders | |||
| journal = [[The Journal of laboratory and clinical medicine]] | |||
| volume = 98 | |||
| issue = 1 | |||
| pages = 1–15 | |||
| year = 1981 | |||
| month = July | |||
| pmid = 7019365 | |||
}}</ref><ref>{{Cite journal | |||
| author = [[P. H. Schmitz]], [[P. H. de Meijer]] & [[A. E. Meinders]] | | author = [[P. H. Schmitz]], [[P. H. de Meijer]] & [[A. E. Meinders]] | ||
| Line 219: | Line 244: | ||
| pmid = 11246114 | | pmid = 11246114 | ||
}}</ref> | }}</ref> Secondary [[adrenal insufficiency]] ([[hypopituitarism]]), presents with features of [[Syndrome of inappropriate antidiuretic hormone|SIAD]] ( euvolemic hyponatremia). | ||
* '''Medications:''' Mechanisms in which medications can cause hyponatremia are; Interfering with urinary dilution ([[Thiazide diuretic|thiazide]] diuretics and [[nonsteroidal anti-inflammatory drugs]] ([[NSAIDs]])), increasing [[ADH]] secretion, persisting [[ADH]] <nowiki/>effect and reset osmostat. | |||
'''''To review the drugs click [[Hyponatremia causes#Drugs which cause hyponatremia|here]].''''' | |||
* '''Reset osmostat:''' There is a downward resetting for [[ADH]] secretion by osmoreceptors, therefore, a lower level of plasma sodium concentration is required to completely suppress [[ADH]] release and water intake ( thirst). [[Pregnancy]] and drugs are the most common etiologies. In [[pregnancy]], secretion of [[human chorionic gonadotropin]] is the main cause of resetting [[osmostat]]. | |||
'''<big>Puedohyponatremia</big>''' | |||
* '''Hyperlipidemia, hyperproteinemia:''' Considerable elevations of either lipids or proteins in serum causes serum sodium to be measured lower than the actual total amount. [[Plasma osmolality]] is normal because the total number of [[solutes]] are the same but since the larger portion of plasma is occupied by excess lipids or protein, the measured serum sodium is lower especially with older techniques like flame photometry. Obstructive jaundice causes elevation of total serum cholesterol and high levels of lipoprotein X which causes the artefactual lower measurement of serum sodium concentration. | |||
* '''Blood sampling:''' Phlebotomy from a vein which is being infused with hypotonic medications cause serum sodium to be measured lower than the actual amount. | |||
* '''Hyperglycemia:''' Elevation of serum glucose causes hyponatremia by osmotic water movement from cells into the blood, which results in a relative decrease in serum sodium concentration. Calculation of [[Hyponatremia pathophysiology#Pathophysiology|serum osmolality]] and corrected serum sodium in hyperglycemia help to determine the actual cause of hyponatremia. For each 100-mg/dL increase in glucose concentration above 100 mg/dL, the sodium concentration should be increased by approximately 1.6 to 2 mmol/L. If the corrected serum sodium is within the normal range, hyponatremia can be explained by hyperglycemia. Lower or higher level of corrected serum sodium means hypotonic hyponatremia or hypernatremia, respectively.<br> | |||
* '''Administration of mannitol or hypertonic radiocontrast''' can also result in nonhypotonic hyponatremia. <ref name="pmid28174217">{{cite journal| author=Hoorn EJ, Zietse R| title=Diagnosis and Treatment of Hyponatremia: Compilation of the Guidelines. | journal=J Am Soc Nephrol | year= 2017 | volume= 28 | issue= 5 | pages= 1340-1349 | pmid=28174217 | doi=10.1681/ASN.2016101139 | pmc=5407738 | url=https://www.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&tool=sumsearch.org/cite&retmode=ref&cmd=prlinks&id=28174217 }} </ref> | |||
Hyponatremia represents an excess of water relative to total body sodium, resulting from impaired water excretion by the kidneys or the depletion of sodium in excess of water. | |||
Hypotonic (dilutional) hyponatremia is classified by the extracellular volume status into hypo-, eu- and hyper-volemic hyponatremia. | Hypotonic (dilutional) hyponatremia is classified by the extracellular volume status into hypo-, eu- and hyper-volemic hyponatremia. | ||
| Line 261: | Line 269: | ||
<tr><td>[[Hyponatremia causes|Hypertonic hyponatremia]]</td><td>Hyponatremia with high osmolality (hypertonic hyponatremia) is defined as hyponatremia with a serum [[osmolality]] greater than 295 mOsm/kg.</td></tr> | <tr><td>[[Hyponatremia causes|Hypertonic hyponatremia]]</td><td>Hyponatremia with high osmolality (hypertonic hyponatremia) is defined as hyponatremia with a serum [[osmolality]] greater than 295 mOsm/kg.</td></tr> | ||
<tr><td>[[Hyponatremia causes|Isotonic hyponatremia]]</td><td>Hyponatremia with normal osmolality (Isotonic hyponatremia) is defined as hyponatremia with a serum [[osmolality]] ranging between 280-295 mOsm/kg.</td></tr> | <tr><td>[[Hyponatremia causes|Isotonic hyponatremia]]</td><td>Hyponatremia with normal osmolality (Isotonic hyponatremia) is defined as hyponatremia with a serum [[osmolality]] ranging between 280-295 mOsm/kg.</td></tr> | ||
<th> Hyponatremia based on ECF volume</th> | <th> Hyponatremia based on ECF volume</th><td></td> | ||
<tr><td>Hypovolemic hyponatremia</td><td>Hyponatremia plus decreased extracellular cellular fluid volume. Usually diagnosed by history and physical examinationshowing water depletion plus spot urine sodium <20 to 30 mmol/L, unless kidney is the source of sodium loss.</td></tr> | <tr><td>Hypovolemic hyponatremia</td><td>Hyponatremia plus decreased extracellular cellular fluid volume. Usually diagnosed by history and physical examinationshowing water depletion plus spot urine sodium <20 to 30 mmol/L, unless kidney is the source of sodium loss.</td></tr> | ||
<tr><td>Euvolemic hyponatremia</td><td>Hyponatremia plus normal extracellular cellular fluid volume. Majority of cases are of this type. Usually diagnosed by spot urine sodium ≥ 20 to 30 mmol/L, unless secondarily sodium depleted. </td></tr> | <tr><td>Euvolemic hyponatremia</td><td>Hyponatremia plus normal extracellular cellular fluid volume. Majority of cases are of this type. Usually diagnosed by spot urine sodium ≥ 20 to 30 mmol/L, unless secondarily sodium depleted. </td></tr> | ||
| Line 268: | Line 276: | ||
==Genetics== | ==Genetics== | ||
* '''Nephrogenic SIAD''' (syndrome of inappropriate antidiuresis) '''<ref name="PowlsonChallis2016">{{cite journal|last1=Powlson|first1=Andrew S.|last2=Challis|first2=Benjamin G.|last3=Halsall|first3=David J.|last4=Schoenmakers|first4=Erik|last5=Gurnell|first5=Mark|title=Nephrogenic syndrome of inappropriate antidiuresis secondary to an activating mutation in the arginine vasopressin receptor AVPR2|journal=Clinical Endocrinology|volume=85|issue=2|year=2016|pages=306–312|issn=03000664|doi=10.1111/cen.13011}}</ref> | * '''Nephrogenic SIAD''' (syndrome of inappropriate antidiuresis)''':<ref name="PowlsonChallis2016">{{cite journal|last1=Powlson|first1=Andrew S.|last2=Challis|first2=Benjamin G.|last3=Halsall|first3=David J.|last4=Schoenmakers|first4=Erik|last5=Gurnell|first5=Mark|title=Nephrogenic syndrome of inappropriate antidiuresis secondary to an activating mutation in the arginine vasopressin receptor AVPR2|journal=Clinical Endocrinology|volume=85|issue=2|year=2016|pages=306–312|issn=03000664|doi=10.1111/cen.13011}}</ref>''' Gain-of-function mutations of the V2 vasopressin receptor gene (AVPR2) causes hyponatremia. | ||
* [[Pseudohypoaldosteronism]] | * [[Pseudohypoaldosteronism]] | ||
* Aldosterone Biosynthetic Defects | * Aldosterone Biosynthetic Defects | ||
Latest revision as of 15:39, 24 October 2021
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Hyponatremia Microchapters |
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Diagnosis |
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Treatment |
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Case Studies |
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Hyponatremia pathophysiology On the Web |
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American Roentgen Ray Society Images of Hyponatremia pathophysiology |
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Risk calculators and risk factors for Hyponatremia pathophysiology |
Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Saeedeh Kowsarnia M.D.[2]
Overview
Hyponatremia is defined as serum sodium less than 135 mEq/L (mmol/L). Sodium is the major electrolyte which determines serum osmolality. Hyponatremia is a water balance disorder in which the ratio between sodium and water is disturbed. Water homeostasis is regulated mainly by two organs: hypothalamus by ADH secretion or thirst, kidney by water reabsorption or excretion. ADH is secreted due to alteration in serum osmolality or intravascular volume. Mechanisms in which different disorders cause hyponatremia involve ADH (secretion or action) and kidney function ( absorption or excretion). ADH secretion is increased by increased osmolality of serum or decreased effective intravascular volume.
Pathophysiology
Sodium is the main cation in the extracellular fluid, thus the plasma concentration of sodium is the determinant of tonicity and serum osmolality.
The osmotic gradient of solutes that do not cross cell membranes constitutes serum Tonicity which determines the distribution of water in the body.[1]
Plasma tonicity = (Extracellular solute + Intracellular solute) / TBW
Serum or plasma osmolality measures different solutes in plasma. It helps to evaluate the etiology of hyponatremia and screen other solutes in the serum.
Serum Osmolality = (2 x (Na + K)) + (BUN (mg/dL) / 2.8) + (glucose (mg/dL) / 18) + (Ethanol (mg/dL) /3.7) [2]
Normal Range= 275–295 mosm /kg (mmol /kg) [3]
| Normal range | Osmolality versus Osmolarity | |
|---|---|---|
| Sodium ‡ | 135-145 mEq /L |
(one liter of plasma equals to one kilogram of plasma thus plasma osmolarity and plasma osmolality would be the same but osmolality is independent of temperature and pressure so it's the more stable unite of measurment) |
| Potassium ‡ | 3.5-5.1 mEq /L | |
| Blood Urea Nitrogen | 7-20 mg /dL (2.5-7.1 mmol /L) | |
| Glucose | 70-100 mg /dL ( 3.9-5.5 mmol /L) | |
| Serum osmolality | 275–295 mosm/kg (mmol /kg) † | |
‡ Mmol and Meq are the same for univalent ions like sodium, potassium
† mOsmol /kg = n x mmol /L, for Na+, Cl-, Ca2+, urea, and glucose, 1 mmol /L equals 1 mOsmol /kg because n=1 , for NaCl n=2
Plasma water is regulated by sensory organs (baroreceptors and hypothalamus osmoreceptors), antidiuretic hormone ( ADH or vasopressin, AVP), and the kidney.
Osmoreceptors in the hypothalamus are sensitive to the increased or decreased tonicity of serum ( magnocellular neurons). The primary brain osmoreceptors are located outside the blood-brain barrier in the lamina terminalis. Primary osmoreceptors are connected to brain areas responsible for ADH secretion and thirst by neuronal projections. Osmoreceptors can both stimulate and inhibit ADH secretion and thirst in response to hyper-and hypotonicity of serum, respectively.[5]
ADH secretion from hypothalamus through posterior pituitary is increased by:[6][7]
- ↑ Angiotensin II ( through activation of Renin-Angiotensin-Activation System)
- ↑ Sympathetic stimulation
- ↑ Effective osmoles ( Hypertonicity)
- ↓ Baroreceptor firing ( ↓ effective intravascular volume)
- ↓ Right atrium stretching
Baroreceptors are in carotid sinus, Juxtaglomerular cell, atrial pressure receptors, hepatic volume receptors, cerebrospinal fluid volume receptors.
ADH increases renal free water reabsorption from the collecting tubules which results in correction of plasma sodium toward the normal range. The vasopressin type 2 (V2) receptor in the basolateral membrane of the collecting tubule acts as the antidiuretic effect of ADH.
Binding of ADH to V2 receptor intensifies the action of intracellular cyclic adenosine monophosphate ( cAMP) which results in insertion of water channel ( aquaporin 2) into the luminal membrane and increasing the numbers of aquaporin-2 mRNA level.[8][9][10]
As plasma water increases, plasma sodium concentration, osmolality, and ADH secretion decrease and the collecting tubule becomes impermeable to water.
Hyponatremia is defined as serum sodium less than 135 mEq/L (mmol/L). Hyponatremia is a water balance disorder which represents an imbalance in a ratio where total body water is more than total body solutes ( total body sodium and total body potassium).
Pathogenesis
Hyponatremia occurs when the release of ADH ( AVP) is increased either physiologically appropriate due to decreased effective circulating volume, or inappropriately due to no physiologic reason. In response to the release of ADH, urine volume decreases and hyponatremia will develop especially when water intake exceeds urinary and insensible losses of water. Patients are typically classified based on their total body sodium as hypovolemic, euvolemic, and hypervolemia.
Hypovolemic hyponatremia
- Volume loss: GI loss, bleeding and insensible loss cause solute and water loss simultaneously which leads to the rise in ADH secretion. A considerable reduction in effective arterial blood volume increase release of ADH by baroreceptors rather than osmoreceptors. There is a marked release in ADH secretion by acute hypovolemia compared to the response that is caused by hypertonicity.[11] ADH increases free water reabsorption from collecting tubules by V2 receptors and vascular resistance by V1 receptors. Replacement of losses with hypotonic fluid may cause further hyponatremia in addition to ADH effect. Hypovolemia caused by diarrhea induces sodium absorption from urine, results in low urine sodium. Vomiting caused hyponatremic hypovolemia which results in high urine sodium and low urine chloride due to bicarbonaturia and metabolic alkalosis.
- Third spacing of fluid: Causes decreased intravascular volume which increases ADH secretion and water reabsorption. Decreased vascular volume induces the activity of the renin-angiotensin-aldosterone system. Aldosterone increases water and sodium absorption by the kidney. As a net result of ADH and aldosterone actions, water is absorbed more than sodium which causes hyponatremia.
- Diuretics: Thiazides increase water reabsorption and water permeability of medullary part of collecting tubules which is independent of ADH action. Excretion of sodium and potassium to the urine causes further hyponatremia.[12] In contrast, loop diuretics decrease the action of ADH on medullary part of collecting tubules by impairing medullary gradient.[13]
- Renal loss: Inappropriately loss of sodium in urine causes hypovolemia and ADH secretion.
- Salt-wasting nephropathy: Renal tubular dysfunction causes hyponatremia especially when sodium intake is reduced. The causes include Interstitial nephropathies, reflux nephropathies, recovery phase of ATN, medullary cystic disease and post-obstructive uropathies.
- Bicarbonaturia: Renal tubular acidosis and metabolic alkalosis cause loss of bicarbonate and sodium in urine to balance charges in urine.
- Cerebral salt-wasting syndrome: Subarachnoid hemorrhage, ischemic stroke, spontaneous intracerebral hemorrhage (ICH), craniotomy, encephalitis, meningitis and head trauma are considered the most common etiologies. The pathophysiology of CSW syndrome is not completely understood. Decreased sympathetic activity to the kidneys and Increased brain natriuretic peptide are the most accepted hypothesis. Renin-aldosterone is decreased due to reduced sympathetic stimulation.[14] Increased natriuretic peptides causes sodium loss by kidney (natriuresis ) through increasing GFR and preventing sodium reabsorption in the collecting duct.[15] Natriuretic peptides inhibit aldosterone and ADH action. Reducing sympathetic outflow by natriuretic peptides decreases aldosterone secretion which lowers sodium level further.[16]
- Osmotic diuresis: Urinary excretion of osmotically active solutes causes volume depletion and hyponatremia. Glucosuria and ketonuria in DKA and HHS obligate sodium and water loss even in the presence of hypovolemia.
- Mineralocorticoid deficiency: Adrenal insufficiency ( primary, aldosterone deficiency) leads to renal sodium loss and volume depletion, causing the release of ADH due to hypovolemia. Patients typically present with hypovolemia, hyponatremia, hyperkalemia, decreased bicarbonate and increased urine sodium and inappropriate renal response in the setting of volume depletion.
Hypervolemic hyponatremia
- Renal disease: Chronic or acute renal failure results in reduced functional nephron mass, decreased glomerular filtration rate (GFR) and therefore decreased capacity for water excretion. Nephrotic syndrome causes reduced effective circulatory volume due hypoproteinemia which results in increased ADH effect.
- Clinical disorders: In Congestive heart failure ( CHF) and cirrhosis, the reduction in effective arterial blood volume, resulting in persistent ADH activity despite hypoosmolar plasma. The ability to excrete water is also limited when the posterior pituitary continues to secrete ADH despite a low serum osmolality and plasma sodium concentration. Decreased effective arterial blood volume is sensed as hypovolemia which is the stronger stimulant of ADH secretion than osmolality of plasma. ADH is secreted without an osmotic stimulus if circulation is inadequate. Inpatients with cirrhosis decreased effective circulating volume is a result of arterial vasodilation of the splanchnic circulation, which is due to the increased endothelial release of nitric oxide. Moreover, large volume paracentesis in cases of refractory ascites can lead to more reduction of effective arterial volume, leading to postparacentesis circulatory dysfunction (PPCD) which worsens the renal failure and hyponatremia. [17]
Euvolemic hyponatremia
- Syndrome of inappropriate antidiuresis: The most common cause of hyponatremia (euvolemic) due to either an increased level of ADH or gain-of-function mutation of the V2 receptor of ADH. Inappropriate secretion or action of ADH in the absence of osmotic or hemodynamic stimulus is called SIAD ( syndrome of inappropriate diuresis). Nephrogenic SIAD has the same presentation but ADH level is normal. Nearly 10% of SIAD is nephrogenic. Recently, hyponatremia has been found associated with COVID-19 infection [18] . Interleukin-6 (IL-6), which has been showed to be involved in the pathophysiology of COVID-19 and is released by monocytes and macrophages plays an important role in development of hyponatremia; it induces the non-osmotic release of vasopressin [19]. This along with the cytokine cascade cause numerous renal pathological changes, such as acute kidney injury (AKI), tubular necrosis, dysfunction of the kidney proximal tubule, glomerulopathy and electrolyte abnormalities.Also, renal cells expressing the receptors of the virus (ACE2), may explain the damage to kidney and subsequent electrolyte imbalances. Approximately 60% of patients with COVID-19 and watery diarrhea have moderate hyponatremia as well. [18]
| Diagnostic criteria of SIAD [20] [21] |
|---|
Supplemental criteria
|
† Mmol and Meq are the same for univalent ions like sodium, potassium
‡ mg/dl = molecular weight (MW) x mmol/l, for example MW for glucose and uric acid is 180 and 168 respectively
- Excess water intake: In exercise-associated hyponatremia, increased level of ADH due to hypovolemia and excess free water intake cause hyponatremia. In primary polydipsia, there is an increase in thirst, especially in psychotic patients. The osmotic threshold for thirst is lower than the threshold for ADH release.
- Hormonal: Glucocorticoids have an inhibitory effect on ADH release by the posterior pituitary so cortisol deficiency induces ADH secretion. Thyroid hormone deficiency especially primary hypothyroidism causes hyponatremia and the mechanism is not well-understood. in patients who present with hypothyroidism, there is an elevation to ADH level and reduction in GFR which means decreased ability to excrete diluted urine.[22][23] Secondary adrenal insufficiency (hypopituitarism), presents with features of SIAD ( euvolemic hyponatremia).
- Medications: Mechanisms in which medications can cause hyponatremia are; Interfering with urinary dilution (thiazide diuretics and nonsteroidal anti-inflammatory drugs (NSAIDs)), increasing ADH secretion, persisting ADH effect and reset osmostat.
To review the drugs click here.
- Reset osmostat: There is a downward resetting for ADH secretion by osmoreceptors, therefore, a lower level of plasma sodium concentration is required to completely suppress ADH release and water intake ( thirst). Pregnancy and drugs are the most common etiologies. In pregnancy, secretion of human chorionic gonadotropin is the main cause of resetting osmostat.
Puedohyponatremia
- Hyperlipidemia, hyperproteinemia: Considerable elevations of either lipids or proteins in serum causes serum sodium to be measured lower than the actual total amount. Plasma osmolality is normal because the total number of solutes are the same but since the larger portion of plasma is occupied by excess lipids or protein, the measured serum sodium is lower especially with older techniques like flame photometry. Obstructive jaundice causes elevation of total serum cholesterol and high levels of lipoprotein X which causes the artefactual lower measurement of serum sodium concentration.
- Blood sampling: Phlebotomy from a vein which is being infused with hypotonic medications cause serum sodium to be measured lower than the actual amount.
- Hyperglycemia: Elevation of serum glucose causes hyponatremia by osmotic water movement from cells into the blood, which results in a relative decrease in serum sodium concentration. Calculation of serum osmolality and corrected serum sodium in hyperglycemia help to determine the actual cause of hyponatremia. For each 100-mg/dL increase in glucose concentration above 100 mg/dL, the sodium concentration should be increased by approximately 1.6 to 2 mmol/L. If the corrected serum sodium is within the normal range, hyponatremia can be explained by hyperglycemia. Lower or higher level of corrected serum sodium means hypotonic hyponatremia or hypernatremia, respectively.
- Administration of mannitol or hypertonic radiocontrast can also result in nonhypotonic hyponatremia. [24]
Hyponatremia represents an excess of water relative to total body sodium, resulting from impaired water excretion by the kidneys or the depletion of sodium in excess of water.
Hypotonic (dilutional) hyponatremia is classified by the extracellular volume status into hypo-, eu- and hyper-volemic hyponatremia.
| Term | Definitions[25][26][27] |
|---|---|
| Hyponatremia | Hyponatremia is defined as a serum sodium concentration < 135 mEq/L. |
| Hypotonic hyponatremia | Hyponatremia with low osmolality (hypotonic hyponatremia) is defined as hyponatremia with a serum osmolality below 280 mOsm/kg. |
| Hypertonic hyponatremia | Hyponatremia with high osmolality (hypertonic hyponatremia) is defined as hyponatremia with a serum osmolality greater than 295 mOsm/kg. |
| Isotonic hyponatremia | Hyponatremia with normal osmolality (Isotonic hyponatremia) is defined as hyponatremia with a serum osmolality ranging between 280-295 mOsm/kg. |
| Hyponatremia based on ECF volume | |
| Hypovolemic hyponatremia | Hyponatremia plus decreased extracellular cellular fluid volume. Usually diagnosed by history and physical examinationshowing water depletion plus spot urine sodium <20 to 30 mmol/L, unless kidney is the source of sodium loss. |
| Euvolemic hyponatremia | Hyponatremia plus normal extracellular cellular fluid volume. Majority of cases are of this type. Usually diagnosed by spot urine sodium ≥ 20 to 30 mmol/L, unless secondarily sodium depleted. |
| Hypervolemia hyponatremia | Hyponatremia plus increased extracellular cellular fluid volume. Usually diagnosed by history and physical examinationshowing water retention plus spot urine sodium <20 to 30 mmol/L |
Genetics
- Nephrogenic SIAD (syndrome of inappropriate antidiuresis):[28] Gain-of-function mutations of the V2 vasopressin receptor gene (AVPR2) causes hyponatremia.
- Pseudohypoaldosteronism
- Aldosterone Biosynthetic Defects
- Gittleman syndrome
- Bartter syndrome
Associated Conditions
References
- ↑ Sperelakis, Nick (2012). Cell physiology sourcebook : essentials of membrane biophysics. London, UK Waltham, MA, USA: Elsevier/Academic Press. ISBN 978-0-12-387738-3.
- ↑ Purssell, Roy A.; Pudek, Morris; Brubacher, Jeffrey; Abu-Laban, Riyad B. (2001). "Derivation and validation of a formula to calculate the contribution of ethanol to the osmolal gap". Annals of Emergency Medicine. 38 (6): 653–659. doi:10.1067/mem.2001.119455. ISSN 0196-0644.
- ↑ Hooper, Lee; Abdelhamid, Asmaa; Ali, Adam; Bunn, Diane K; Jennings, Amy; John, W Garry; Kerry, Susan; Lindner, Gregor; Pfortmueller, Carmen A; Sjöstrand, Fredrik; Walsh, Neil P; Fairweather-Tait, Susan J; Potter, John F; Hunter, Paul R; Shepstone, Lee (2015). "Diagnostic accuracy of calculated serum osmolarity to predict dehydration in older people: adding value to pathology laboratory reports". BMJ Open. 5 (10): e008846. doi:10.1136/bmjopen-2015-008846. ISSN 2044-6055.
- ↑ Erstad BL (2003). "Osmolality and osmolarity: narrowing the terminology gap". Pharmacotherapy. 23 (9): 1085–6. PMID 14524639.
- ↑ Verbalis, J. G. (2007). "How Does the Brain Sense Osmolality?". Journal of the American Society of Nephrology. 18 (12): 3056–3059. doi:10.1681/ASN.2007070825. ISSN 1046-6673.
- ↑ G. L. Robertson (1987). "Physiology of ADH secretion". Kidney international. Supplement. 21: S20–S26. PMID 3476800. Unknown parameter
|month=ignored (help) - ↑ L. Share (1967). "Vasopressin, its bioassay and the physiological control of its release". The American journal of medicine. 42 (5): 701–712. PMID 5337374. Unknown parameter
|month=ignored (help) - ↑ Kwon, Tae-Hwan; Hager, Henrik; Nejsum, Lene N.; Andersen, Marie-Louise E.; Fr[oslash]ki[aelig ]r, J[oslash]rgen; Nielsen, S[oslash]ren (2001). "Physiology and pathophysiology of renal aquaporins". Seminars in Nephrology. 21 (3): 231–238. doi:10.1053/snep.2001.21647. ISSN 0270-9295.
- ↑ Holmes, Cheryl L; Landry, Donald W; Granton, John T (2003). Critical Care. 7 (6): 427. doi:10.1186/cc2337. ISSN 1364-8535. Missing or empty
|title=(help) - ↑ Holmes, Cheryl L; Landry, Donald W; Granton, John T (2003). Critical Care. 7 (6): 427. doi:10.1186/cc2337. ISSN 1364-8535. Missing or empty
|title=(help) - ↑ P. H. Baylis (1987). "Osmoregulation and control of vasopressin secretion in healthy humans". The American journal of physiology. 253 (5 Pt 2): R671–R678. doi:10.1152/ajpregu.1987.253.5.R671. PMID 3318505. Unknown parameter
|month=ignored (help) - ↑ K. R. Cesar & A. J. Magaldi (1999). "Thiazide induces water absorption in the inner medullary collecting duct of normal and Brattleboro rats". The American journal of physiology. 277 (5 Pt 2): F756–F760. PMID 10564239. Unknown parameter
|month=ignored (help) - ↑ V. L. Szatalowicz, P. D. Miller, J. W. Lacher, J. A. Gordon & R. W. Schrier (1982). "Comparative effect of diuretics on renal water excretion in hyponatraemic oedematous disorders". Clinical science (London, England : 1979). 62 (2): 235–238. PMID 7053922. Unknown parameter
|month=ignored (help) - ↑ Kim, Dong Ki; Joo, Kwon Wook (2009). "Hyponatremia in Patients with Neurologic Disorders". Electrolytes & Blood Pressure. 7 (2): 51. doi:10.5049/EBP.2009.7.2.51. ISSN 1738-5997.
- ↑ Damaraju, Sriram Chandra; Rajshekhar, Vedantam; Chandy, Mathew J. (1997). "Validation Study of a Central Venous Pressure-based Protocol for the Management of Neurosurgical Patients with Hyponatremia and Natriuresis". Neurosurgery. 40 (2): 312–317. doi:10.1097/00006123-199702000-00015. ISSN 0148-396X.
- ↑ . doi:10.3275/7290. Missing or empty
|title=(help) - ↑ Alukal JJ, John S, Thuluvath PJ (2020). "Hyponatremia in Cirrhosis: An Update". Am J Gastroenterol. 115 (11): 1775–1785. doi:10.14309/ajg.0000000000000786. PMID 33156095 Check
|pmid=value (help). - ↑ 18.0 18.1 Gheorghe G, Ilie M, Bungau S, Stoian AMP, Bacalbasa N, Diaconu CC (2021). "Is There a Relationship between COVID-19 and Hyponatremia?". Medicina (Kaunas). 57 (1). doi:10.3390/medicina57010055. PMC 7827825 Check
|pmc=value (help). PMID 33435405 Check|pmid=value (help). - ↑ Berni A, Malandrino D, Parenti G, Maggi M, Poggesi L, Peri A (2020). "Hyponatremia, IL-6, and SARS-CoV-2 (COVID-19) infection: may all fit together?". J Endocrinol Invest. 43 (8): 1137–1139. doi:10.1007/s40618-020-01301-w. PMC 7246958 Check
|pmc=value (help). PMID 32451971 Check|pmid=value (help). - ↑ Natasa Janicic & Joseph G. Verbalis (2003). "Evaluation and management of hypo-osmolality in hospitalized patients". Endocrinology and metabolism clinics of North America. 32 (2): 459–481. PMID 12800541. Unknown parameter
|month=ignored (help) - ↑ W. B. Schwartz, W. Bennett, S. Curelop & F. C. Bartter (2001). "A syndrome of renal sodium loss and hyponatremia probably resulting from inappropriate secretion of antidiuretic hormone. 1957". Journal of the American Society of Nephrology : JASN. 12 (12): 2860–2870. PMID 11729259. Unknown parameter
|month=ignored (help) - ↑ R. W. Schrier & D. G. Bichet (1981). "Osmotic and nonosmotic control of vasopressin release and the pathogenesis of impaired water excretion in adrenal, thyroid, and edematous disorders". The Journal of laboratory and clinical medicine. 98 (1): 1–15. PMID 7019365. Unknown parameter
|month=ignored (help) - ↑ P. H. Schmitz, P. H. de Meijer & A. E. Meinders (2001). "Hyponatremia due to hypothyroidism: a pure renal mechanism". The Netherlands journal of medicine. 58 (3): 143–149. PMID 11246114. Unknown parameter
|month=ignored (help) - ↑ Hoorn EJ, Zietse R (2017). "Diagnosis and Treatment of Hyponatremia: Compilation of the Guidelines". J Am Soc Nephrol. 28 (5): 1340–1349. doi:10.1681/ASN.2016101139. PMC 5407738. PMID 28174217.
- ↑ Laczi, F. (2008). "[Etiology, diagnostics and therapy of hyponatremias]". Orv Hetil. 149 (29): 1347–54. doi:10.1556/OH.2008.28409. PMID 18617466. Unknown parameter
|month=ignored (help) - ↑ Douglas, I. (2006). "Hyponatremia: why it matters, how it presents, how we can manage it". Cleve Clin J Med. 73 Suppl 3: S4–12. PMID 16970147. Unknown parameter
|month=ignored (help) - ↑ Verbalis, JG.; Goldsmith, SR.; Greenberg, A.; Korzelius, C.; Schrier, RW.; Sterns, RH.; Thompson, CJ. (2013). "Diagnosis, evaluation, and treatment of hyponatremia: expert panel recommendations". Am J Med. 126 (10 Suppl 1): S1–42. doi:10.1016/j.amjmed.2013.07.006. PMID 24074529. Unknown parameter
|month=ignored (help) - ↑ Powlson, Andrew S.; Challis, Benjamin G.; Halsall, David J.; Schoenmakers, Erik; Gurnell, Mark (2016). "Nephrogenic syndrome of inappropriate antidiuresis secondary to an activating mutation in the arginine vasopressin receptor AVPR2". Clinical Endocrinology. 85 (2): 306–312. doi:10.1111/cen.13011. ISSN 0300-0664.