Hyponatremia ppt .final
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About This Presentation
hyponatremia simplified
Slide Content
Presenter: Dr Arun Karmakar
Moderator : Prof. N. Sharatkumar
Hyponatremia
Moderator : Prof. N. Sharatkumar
Hyponatremia
Introduction
Defined as a serum [Na] below 135 mmol/L.
Most common disorder of electrolytes encountered in
clinical practice, occurring in 22% of hospitalized
patients.
Defined as a serum [Na] below 135 mmol/L.
Most common disorder of electrolytes encountered in
clinical practice, occurring in 22% of hospitalized
patients.
Important clinically because:
1) acute severe hyponatremia can cause substantial
morbidity and mortality;
2) adverse outcomes are higher in hyponatremic
patients with a wide range of underlying diseases;
3) overly rapid correction of chronic hyponatremia can
cause severe neurological deficits and death.
1) acute severe hyponatremia can cause substantial
morbidity and mortality;
2) adverse outcomes are higher in hyponatremic
patients with a wide range of underlying diseases;
3) overly rapid correction of chronic hyponatremia can
cause severe neurological deficits and death.
ETIOLOGIES AND PATHOPHYSIOLOGIES OF
HYPOTONIC HYPONATREMIAS
HYPOTONIC HYPONATREMIAS
Hypovolemic Hyponatremia(↓H
2O, ↓↓Na
+
)
2O, ↓↓Na
+
)
Vomiting or
Diarrhoea
Burns
Peritonitis
Bowel lumen ileus
Loss water &
Na
+,
Cl
--
free water or hypotonic
fluid intake
Gastrointestinal and Third-Space
Sequestered Losses
Hypovolemic
hyponatremia
Vasopressin
due to volume
contraction
Diarrhoea
Burns
Peritonitis
Bowel lumen ileus
Loss water &
Na
+,
Cl
--
free water or hypotonic
fluid intake
Gastrointestinal and Third-Space
Sequestered Losses
Hypovolemic
hyponatremia
Vasopressin
due to volume
contraction
Loop diuretics
In TALH
Blocks sodium
reabsorption
interferes with the
generation of a hypertonic
medullary interstitium
Thiazide
diuretics
DCT
interfering with urinary
dilution rather than with
urinary concentration
More free water excretion,
inspite of vasopressin
Limits free water
excretion
Diuretic therapy
In TALH
Blocks sodium
reabsorption
interferes with the
generation of a hypertonic
medullary interstitium
Thiazide
diuretics
DCT
interfering with urinary
dilution rather than with
urinary concentration
More free water excretion,
inspite of vasopressin
Limits free water
excretion
Diuretic therapy
Is a syndrome described following SAH, head injury, or
neurosurgical procedures, as well in other settings.
Primary defect is salt wasting from the kidneys(?role of
BNP) with subsequent volume contraction, which
stimulates vasopressin release.
Uncommon.
Cerebral Salt Wasting
syndrome
neurosurgical procedures, as well in other settings.
Primary defect is salt wasting from the kidneys(?role of
BNP) with subsequent volume contraction, which
stimulates vasopressin release.
Uncommon.
Cerebral Salt Wasting
syndrome
Characterized by hyponatremia with ECF volume
contraction (provides the nonosmotic stimulus for
vasopressin release).
Urine [Na
+
] above 20 mmol/l, and high serum K
+
.
Mineralocorticoid (Aldosterone) Deficiency
contraction (provides the nonosmotic stimulus for
vasopressin release).
Urine [Na
+
] above 20 mmol/l, and high serum K
+
.
Mineralocorticoid (Aldosterone) Deficiency
Euvolemic Hyponatremia(↑H
2
O, ←→Na
+
)
2
O, ←→Na
+
)
A defect in osmoregulation causes vasopressin to be
inappropriately stimulated, leading to urinary concentration.
MCC of euvolumic hyponatremia
Excess vasopressin: CNS disturbances such as hemorrhage,
tumors, infections, and trauma.
Ectopic vasopressin: Small cell lung cancers, cancer of the
duodenum and pancreas, and olfactory neuroblastoma.
Idiopathic: seen in elderly(10%).
SIADH (Syndrome of Inappropriate ADH Secretion)
inappropriately stimulated, leading to urinary concentration.
MCC of euvolumic hyponatremia
Excess vasopressin: CNS disturbances such as hemorrhage,
tumors, infections, and trauma.
Ectopic vasopressin: Small cell lung cancers, cancer of the
duodenum and pancreas, and olfactory neuroblastoma.
Idiopathic: seen in elderly(10%).
SIADH (Syndrome of Inappropriate ADH Secretion)
Criteria for Diagnosing SIADH
Decreased effective osmolality of the extracellular fluid.
Inappropriate urinary concentration (Uosm >100 mOsmol/kg
H2O) with normal renal function) at some level of plasma hypo-
osmolality.
Clinical euvolemia.
Elevated urinary sodium excretion (>20 mmol/L) while on
normal salt and water intake.
Absence of other potential causes of euvolemic hypo-osmolality
Normal renal function and absence of diuretic use, particularly
thiazide diuretics.
Decreased effective osmolality of the extracellular fluid.
Inappropriate urinary concentration (Uosm >100 mOsmol/kg
H2O) with normal renal function) at some level of plasma hypo-
osmolality.
Clinical euvolemia.
Elevated urinary sodium excretion (>20 mmol/L) while on
normal salt and water intake.
Absence of other potential causes of euvolemic hypo-osmolality
Normal renal function and absence of diuretic use, particularly
thiazide diuretics.
Supporting diagnostic criteria for SIADH
Serum uric acid <4 mg/dL
Blood urea nitrogen <10 mg/dL
Fractional sodium excretion >1%; fractional urea
excretion >55%
Failure to improve or worsening of hyponatremia after
0.9% saline infusion
Improvement of hyponatremia with fluid restriction
Serum uric acid <4 mg/dL
Blood urea nitrogen <10 mg/dL
Fractional sodium excretion >1%; fractional urea
excretion >55%
Failure to improve or worsening of hyponatremia after
0.9% saline infusion
Improvement of hyponatremia with fluid restriction
glucocor
ticoids
Posterior pituitary
Vasopressin
─
Severe
hypothyroidism
(myxedema coma)
↓CO
↓GFR,
↑vasopressin
Psychogenic
polydipsia
*↑Thirst perception,
*Acute psychosis
secondary to
schizophrenia, Anxiety
*Often on SSRI’s,
*CT or MRI to r/o CNS
sarcoidosis and
craniopharyngioma.
ticoids
Posterior pituitary
Vasopressin
─
Severe
hypothyroidism
(myxedema coma)
↓CO
↓GFR,
↑vasopressin
Psychogenic
polydipsia
*↑Thirst perception,
*Acute psychosis
secondary to
schizophrenia, Anxiety
*Often on SSRI’s,
*CT or MRI to r/o CNS
sarcoidosis and
craniopharyngioma.
Postoperative
hyponatremia
•Excessive infusion of free
water (5% dextrose) and
•↑Vasopressin due to pain
Exercise-Associated
Hyponatremia(EAH)
•Long-distance marathon runners.
increased risk:
•BMI below 20 kg/m
2
,
•Running time exceeding 4 hours
•Consumption of fluids every mile
↑vasopressin
hyponatremia
•Excessive infusion of free
water (5% dextrose) and
•↑Vasopressin due to pain
Exercise-Associated
Hyponatremia(EAH)
•Long-distance marathon runners.
increased risk:
•BMI below 20 kg/m
2
,
•Running time exceeding 4 hours
•Consumption of fluids every mile
↑vasopressin
Drugs that enhance vasopressin releaseDrugs that cause hyponatremia by
unknown mechanisms
Clofibrate
Carbamazepine
Vincristine
Nicotine
Narcotics
SSRI
ifosfamide
Haloperidol
Amitryptyline
Fluoxetine
Fluphenazine
IVIG
Methylmethamphetamine (MDMA)
Vasopressin analogues Drugs that potentiate renal action of
vasopressin
Desmopressin
Oxytocin
Cyclophosphamide
NSAIDs
Acetaminophen
Drugs Causing Hyponatremia
unknown mechanisms
Clofibrate
Carbamazepine
Vincristine
Nicotine
Narcotics
SSRI
ifosfamide
Haloperidol
Amitryptyline
Fluoxetine
Fluphenazine
IVIG
Methylmethamphetamine (MDMA)
Vasopressin analogues Drugs that potentiate renal action of
vasopressin
Desmopressin
Oxytocin
Cyclophosphamide
NSAIDs
Acetaminophen
Drugs Causing Hyponatremia
Hypervolemic Hyponatremia (↑↑H
2
O, ↑Na
+
)
2
O, ↑Na
+
)
Congestive Heart
Failure
↓MAP, ↓CO
Reduced effective
intravascular volume
↑vasopressin
(non osmotic baroreceptor
stimulation)
↑Norepinephrine
↓GFR
RAAS
↑Thirst
Failure
↓MAP, ↓CO
Reduced effective
intravascular volume
↑vasopressin
(non osmotic baroreceptor
stimulation)
↑Norepinephrine
↓GFR
RAAS
↑Thirst
↑extracellular volume (ascites, edema).
↑ plasma volume (splanchnic venous dilation)
↑plasma renin,
↑ norepinephrine,
↑ vasopressin
↓GFR, ↑free water retention
Dilutional hyponatremia
Cirrhosis
In pts of advanced cirrhosis
↑ plasma volume (splanchnic venous dilation)
↑plasma renin,
↑ norepinephrine,
↑ vasopressin
↓GFR, ↑free water retention
Dilutional hyponatremia
Cirrhosis
In pts of advanced cirrhosis
Advanced Chronic kidney disease
•Urine output is relatively fixed and water intake in
excess of urine output and insensible losses will cause
hyponatremia.
•Edema usually develops when the Na
+
ingested exceeds
the kidneys capacity to excrete.
•Urine output is relatively fixed and water intake in
excess of urine output and insensible losses will cause
hyponatremia.
•Edema usually develops when the Na
+
ingested exceeds
the kidneys capacity to excrete.
Clinical Manifestations of Hyponatremia
Acute Hyponatremia – <48 hours
chronic hyponatremia - > 48 hours
chronic hyponatremia - > 48 hours
STEP 1 – Serum Osmolality
Serum Osmolality: lab value or calculation – in
mosm/kg
=(2 x Na+) + (glucose/18) + (BUN/2.8)
Hypertonic - >295
hyperglycemia, mannitol, glycerol
Isotonic - 280-295
pseudo-hyponatremia from elevated lipids or protein
Hypotonic - <280
excess fluid intake, low solute intake, renal disease, SIADH,
hypothyroidism, adrenal insufficiency, CHF, cirrhosis, etc.
Serum Osmolality: lab value or calculation – in
mosm/kg
=(2 x Na+) + (glucose/18) + (BUN/2.8)
Hypertonic - >295
hyperglycemia, mannitol, glycerol
Isotonic - 280-295
pseudo-hyponatremia from elevated lipids or protein
Hypotonic - <280
excess fluid intake, low solute intake, renal disease, SIADH,
hypothyroidism, adrenal insufficiency, CHF, cirrhosis, etc.
STEP 2 –Volume Status
2
nd
assess volume status (extracellular fluid volume)
Hypotonic hyponatremia has 3 main etiologies:
Hypovolemic – both water and Na decreased (H20 < Na)
Consider obvious losses from diarrhea, vomiting,
dehydration, malnutrition, etc
Euvolemic – water increased and Na stable
Consider SIADH, thyroid disease, primary polydipsia
Hypervolemic – water increased and Na increased (H2O > Na)
Consider obvious CHF, cirrhosis, renal failure
2
nd
assess volume status (extracellular fluid volume)
Hypotonic hyponatremia has 3 main etiologies:
Hypovolemic – both water and Na decreased (H20 < Na)
Consider obvious losses from diarrhea, vomiting,
dehydration, malnutrition, etc
Euvolemic – water increased and Na stable
Consider SIADH, thyroid disease, primary polydipsia
Hypervolemic – water increased and Na increased (H2O > Na)
Consider obvious CHF, cirrhosis, renal failure
STEP 3 – Urine Studies
For euvolemic hyponatremia, check urine osmolality
Urine osmolality <100 - excess water intake
Primary polydipsia, tap water enemas, post-TURP
Urine osmolality >100 - impaired renal concentration
SIADH, hypothyroidism, cortisol deficiency
Check urine sodium & calculate FeNa %
Low urine sodium (<20) and low FeNa (<1%) implies the
kidneys are appropriately reabsorbing sodium
High urine sodium (>20) and high FeNa (>1%) implies the
kidneys are not functioning properly
For euvolemic hyponatremia, check urine osmolality
Urine osmolality <100 - excess water intake
Primary polydipsia, tap water enemas, post-TURP
Urine osmolality >100 - impaired renal concentration
SIADH, hypothyroidism, cortisol deficiency
Check urine sodium & calculate FeNa %
Low urine sodium (<20) and low FeNa (<1%) implies the
kidneys are appropriately reabsorbing sodium
High urine sodium (>20) and high FeNa (>1%) implies the
kidneys are not functioning properly
Treatment
When considering the treatment of patients with
hyponatremia, five issues must be addressed:
•Risk of osmotic demyelination
•Appropriate rate of correction to minimize this risk
•
•Optimal method of raising the plasma sodium
concentration
•Estimation of the sodium deficit if sodium is to be
given
•Management of the patient in whom overly rapid
correction has occurred
When considering the treatment of patients with
hyponatremia, five issues must be addressed:
•Risk of osmotic demyelination
•Appropriate rate of correction to minimize this risk
•
•Optimal method of raising the plasma sodium
concentration
•Estimation of the sodium deficit if sodium is to be
given
•Management of the patient in whom overly rapid
correction has occurred
General principles of treatment
.Primarily determined by the severity of symptoms and
the cause of the hyponatremia
•Symptomatic hyponatremia (seizures, or coma)
olikely to occur with an acute case and marked
reduction in the plasma sodium concentration
oAggressive therapy is required.
oChronic but significant hyponatremia
where less severe neurologic symptoms occur
fatigue, nausea, dizziness, gait disturbances,
confusion, lethargy, and muscle cramps
These symptoms typically do not mandate
aggressive therapy
.Primarily determined by the severity of symptoms and
the cause of the hyponatremia
•Symptomatic hyponatremia (seizures, or coma)
olikely to occur with an acute case and marked
reduction in the plasma sodium concentration
oAggressive therapy is required.
oChronic but significant hyponatremia
where less severe neurologic symptoms occur
fatigue, nausea, dizziness, gait disturbances,
confusion, lethargy, and muscle cramps
These symptoms typically do not mandate
aggressive therapy
Methods of Sodium Correction
•Water restriction
•primary therapy for hyponatremia in edematous states,
SIADH, primary polydipsia, and advanced renal failure.
•Sodium chloride administration
•usually as isotonic saline or increased dietary salt
given to patients with true volume depletion, adrenal
insufficiency, and in some cases of SIADH.
•contraindicated in edematous patients (eg, heart
failure, cirrhosis, renal failure) since it will lead to
exacerbation of the edema
• Hypertonic saline is generally recommended only for
patients with symptomatic or severe hyponatremia.
•Water restriction
•primary therapy for hyponatremia in edematous states,
SIADH, primary polydipsia, and advanced renal failure.
•Sodium chloride administration
•usually as isotonic saline or increased dietary salt
given to patients with true volume depletion, adrenal
insufficiency, and in some cases of SIADH.
•contraindicated in edematous patients (eg, heart
failure, cirrhosis, renal failure) since it will lead to
exacerbation of the edema
• Hypertonic saline is generally recommended only for
patients with symptomatic or severe hyponatremia.
•The increase in plasma Na
+
concentration can be highly
unpredictable during treatment with hypertonic saline due
to rapid changes in the underlying physiology.
•Patient should be monitored carefully for changes in
neurologic and pulmonary status, and serum electrolytes
should be checked frequently, every 2 - 4 hours.
+
concentration can be highly
unpredictable during treatment with hypertonic saline due
to rapid changes in the underlying physiology.
•Patient should be monitored carefully for changes in
neurologic and pulmonary status, and serum electrolytes
should be checked frequently, every 2 - 4 hours.
Goal:
Urgent correction by 1-2 mmol/hr upto 4-6 mmol/L, to
prevent brain herniation and neurological damage from
cerebral ischemia.
Upper limit for correction,10-12 mmol/L in any 24hour
period; 18 mmol/L in any 48-hour period.
Treatment of symptomatic acute hyponatremia
Urgent correction by 1-2 mmol/hr upto 4-6 mmol/L, to
prevent brain herniation and neurological damage from
cerebral ischemia.
Upper limit for correction,10-12 mmol/L in any 24hour
period; 18 mmol/L in any 48-hour period.
Treatment of symptomatic acute hyponatremia
how much fluids to give?
Total body water = weight x 0.6 for men / 0.5 for woman
•One liter of NS contains: 154 mmol/L of Na+ Cl−
•One liter of 3% saline contains:513 mmol/L of Na+ Cl−
Total body water = weight x 0.6 for men / 0.5 for woman
•One liter of NS contains: 154 mmol/L of Na+ Cl−
•One liter of 3% saline contains:513 mmol/L of Na+ Cl−
Example: An 60-kg man is having seizure .His s.Na is 110
mmol /L.
Means of correction:
Given the acuity, the patient should be given hypertonic saline,
which has 513 mmol of Na per liter.
{513 - 110} /{60 x 0.6 +1}= 10 mmol/L
One liter of this fluid would increase Na by 10 mmol/L.
Dose of hypertonic saline at 200 mL/hr until symptoms
improve. Maximum 1 litre of 3% NS should be given in 24
hour.
mmol /L.
Means of correction:
Given the acuity, the patient should be given hypertonic saline,
which has 513 mmol of Na per liter.
{513 - 110} /{60 x 0.6 +1}= 10 mmol/L
One liter of this fluid would increase Na by 10 mmol/L.
Dose of hypertonic saline at 200 mL/hr until symptoms
improve. Maximum 1 litre of 3% NS should be given in 24
hour.
Goal:
Minimum correction of serum [Na] by 4-8 mmol/L per
day, with a lower goal of 4-6 mmol/L per day if the risk of
ODS is high.
Limits not to exceed:
• 8-10 mmol/L in any 24-hour period.
Treatment of chronic hyponatremia(Avoiding
ODS)
Minimum correction of serum [Na] by 4-8 mmol/L per
day, with a lower goal of 4-6 mmol/L per day if the risk of
ODS is high.
Limits not to exceed:
• 8-10 mmol/L in any 24-hour period.
Treatment of chronic hyponatremia(Avoiding
ODS)
Treatment of hypovolemic hyponatremia
Diuretic related- Discontinuation of thiazides and
correction of volume deficits.
Mineralocorticoid deficiency- Volume repletion with
isotonic saline, Fludrocortisone chronically for
mineralocorticoid replacement.
Diuretic related- Discontinuation of thiazides and
correction of volume deficits.
Mineralocorticoid deficiency- Volume repletion with
isotonic saline, Fludrocortisone chronically for
mineralocorticoid replacement.
SIADH - For most cases of mild-to moderate SIADH, fluid
restriction represents the cheapest and least toxic therapy. (fluid
restriction 500 mL/d below the 24-hour urine volume.
Failure to water restriction
- Vaptans
- Democlocycline 150- 300 mg PO tid or qid
-Fludrocortisone 0.05-0.2 mg bid
Treatment of euvolemic hyponatremia
restriction represents the cheapest and least toxic therapy. (fluid
restriction 500 mL/d below the 24-hour urine volume.
Failure to water restriction
- Vaptans
- Democlocycline 150- 300 mg PO tid or qid
-Fludrocortisone 0.05-0.2 mg bid
Treatment of euvolemic hyponatremia
Glucocorticoid Deficiency-glucocorticoid replacement
at either maintenance or stress doses, depending on
the degree of intercurrent illness.
Severe Hypothyroidism-thyroid hormone replacement at
standard weight-based doses; several days may be needed
to normalize the serum [Na].
at either maintenance or stress doses, depending on
the degree of intercurrent illness.
Severe Hypothyroidism-thyroid hormone replacement at
standard weight-based doses; several days may be needed
to normalize the serum [Na].
Heart Failure-for patients with mild to moderate
symptoms, begin with fluid restriction (1 L/d total) and, if
signs of volume overload are present, administer loop
diuretics.
If the serum [Na] does not correct to the desired level, lift the
fluid restriction and start either conivaptan or tolvaptan.
Treatment of hypovolemic hyponatremia
symptoms, begin with fluid restriction (1 L/d total) and, if
signs of volume overload are present, administer loop
diuretics.
If the serum [Na] does not correct to the desired level, lift the
fluid restriction and start either conivaptan or tolvaptan.
Treatment of hypovolemic hyponatremia
Cirrhosis-Severe daily fluid restriction,
Vaptans an alternative choice if fluid restriction has failed to maintain
a serum [Na] 130 mmol/L; however, tolvaptan use should be
restricted to cases where the potential clinical benefit outweighs the
risk of worsened liver function, such as in patients with end-stage
liver disease and severe hyponatremia who are awaiting imminent
liver transplantation.
Cirrhosis-Severe daily fluid restriction,
Vaptans an alternative choice if fluid restriction has failed to maintain
a serum [Na] 130 mmol/L; however, tolvaptan use should be
restricted to cases where the potential clinical benefit outweighs the
risk of worsened liver function, such as in patients with end-stage
liver disease and severe hyponatremia who are awaiting imminent
liver transplantation.
CKD-Restricting fluid intake. Aquaretics (vaptans)
can be employed{not be expected to cause a
clinically significant aquaresis with severe renal
impairment (ie, serum creatinine >2.5 mg/dL)}.
can be employed{not be expected to cause a
clinically significant aquaresis with severe renal
impairment (ie, serum creatinine >2.5 mg/dL)}.
Role of VAPTANS
Vaptans have long been anticipated as a more effective
method to treat hyponatremia by virtue of their unique effect
to selectively increase solute-free water excretion by the
kidneys.
Although not C/I with decreased renal function, these
agents generally will not be effective if S.Cr is >2.5mg%.
Vaptans have long been anticipated as a more effective
method to treat hyponatremia by virtue of their unique effect
to selectively increase solute-free water excretion by the
kidneys.
Although not C/I with decreased renal function, these
agents generally will not be effective if S.Cr is >2.5mg%.
Conivaptan Tolvaptan Lixivaptan
Receptor V1a/V2 antagonist V2 antagonist V2 antagonist
Route i.v Oral Oral
Urine volume↑ ↑ ↑
Urine
osmolality
↓ ↓ ↓
Sodium
excretion/d
↔ ↔ ↔ at low dose,
↑at high dose
Status FDA approved FDA & EMA approved Phase 3
completed
Dosage 20mg over 30min f/b cont
inf 20-40mg/d
15mg on D1, then titrate to
30-60mg/d
-
Duration of
treatment
Max 4days (interaction with
CYP3A4)
≤30days(risk of hepatic
injury)
-
Side effectsHeadache, thirst,
hypokalemia
Drymouth, thirst, dizziness,
hypotension
-
Indications Euvolumic and
hypervolumic hyponatremia
Euvolumic and hypervolumic
hyponatremia
-
Receptor V1a/V2 antagonist V2 antagonist V2 antagonist
Route i.v Oral Oral
Urine volume↑ ↑ ↑
Urine
osmolality
↓ ↓ ↓
Sodium
excretion/d
↔ ↔ ↔ at low dose,
↑at high dose
Status FDA approved FDA & EMA approved Phase 3
completed
Dosage 20mg over 30min f/b cont
inf 20-40mg/d
15mg on D1, then titrate to
30-60mg/d
-
Duration of
treatment
Max 4days (interaction with
CYP3A4)
≤30days(risk of hepatic
injury)
-
Side effectsHeadache, thirst,
hypokalemia
Drymouth, thirst, dizziness,
hypotension
-
Indications Euvolumic and
hypervolumic hyponatremia
Euvolumic and hypervolumic
hyponatremia
-
Osmotic demyelination syndrome
ODS occurs if chronic hyponatremia is corrected too
rapidly.
Present in a stereotypical biphasic pattern (initially
improve neurologically with correction of hyponatremia,
but then, one to several days later, new, progressive, and
sometimes permanent neurological deficits emerge).
rapidly.
Present in a stereotypical biphasic pattern (initially
improve neurologically with correction of hyponatremia,
but then, one to several days later, new, progressive, and
sometimes permanent neurological deficits emerge).
• Patients can present para- or quadraparesis, dysphagia,
dysarthria, diplopia, a "locked-in syndrome," and/or loss of
consciousness.
• Most commonly affected area is pons.
•Other regions of the brain affected in ODS: (in order of
frequency) cerebellum, lateral geniculate body, thalamus,
putamen, and cerebral cortex or subcortex.
dysarthria, diplopia, a "locked-in syndrome," and/or loss of
consciousness.
• Most commonly affected area is pons.
•Other regions of the brain affected in ODS: (in order of
frequency) cerebellum, lateral geniculate body, thalamus,
putamen, and cerebral cortex or subcortex.
•As these lesions may not appear until 2 weeks after development, a diagnosis
of myelinolysis should not be excluded if the imaging is initially normal.
of myelinolysis should not be excluded if the imaging is initially normal.
Starting serum [Na] ≥120 mmol/L: Intervention unnecessary.
Starting serum [Na] <120 mmol/L:
Withhold the next dose of vaptan if the correction is >8
mmol/L;
Consider therapeutic re-lowering of serum [Na] if
correction exceeds therapeutic limits;
Consider administration of high-dose glucocorticoids (eg,
dexamethasone, 4 mg every 6 hrs) for 24-48hrs following
the excessive correction.
Managing excessive correction of chronic hyponatremia
Starting serum [Na] <120 mmol/L:
Withhold the next dose of vaptan if the correction is >8
mmol/L;
Consider therapeutic re-lowering of serum [Na] if
correction exceeds therapeutic limits;
Consider administration of high-dose glucocorticoids (eg,
dexamethasone, 4 mg every 6 hrs) for 24-48hrs following
the excessive correction.
Managing excessive correction of chronic hyponatremia
Re-lowering serum [Na]:
Administer desmopressin to prevent further water losses:
2-4 mg every 8 hours parenterally;
Replace water orally or as 5% dextrose in water
intravenously: 3 mL/kg/h;
Recheck serum [Na] hourly and continue therapy infusion
until serum [Na] is reduced to goal
Administer desmopressin to prevent further water losses:
2-4 mg every 8 hours parenterally;
Replace water orally or as 5% dextrose in water
intravenously: 3 mL/kg/h;
Recheck serum [Na] hourly and continue therapy infusion
until serum [Na] is reduced to goal
Hypotonic hyponatremia/true
hyponatremia
Pseudohyponatremia/osmotic related
Access renal
status
Primary renal diseaseImpaired renal
function
Access volume
status
Normal
Edema – CHF, cirrhosis, nephrotic syndrome
Volume depletion
Ur, Na
+
<20 = diarrhoea,
vomiting, burns, pancreatitis
Ur, Na
+
>20 = diuretics, salt
losing nephropathy
Normal volume
Adrenal & thyroid
function
Adrenal & thyroid insufficiency
Normal
Access Urine
osmolality(Able to
dilute urine)
>100 mOsmol/kg H2O
Dilute urine Psychogenic polydipsia
NO
YES
Access serum osmolality
low
Normal/high
SIADH
Approach to a case of hyponatremia
hyponatremia
Pseudohyponatremia/osmotic related
Access renal
status
Primary renal diseaseImpaired renal
function
Access volume
status
Normal
Edema – CHF, cirrhosis, nephrotic syndrome
Volume depletion
Ur, Na
+
<20 = diarrhoea,
vomiting, burns, pancreatitis
Ur, Na
+
>20 = diuretics, salt
losing nephropathy
Normal volume
Adrenal & thyroid
function
Adrenal & thyroid insufficiency
Normal
Access Urine
osmolality(Able to
dilute urine)
>100 mOsmol/kg H2O
Dilute urine Psychogenic polydipsia
NO
YES
Access serum osmolality
low
Normal/high
SIADH
Approach to a case of hyponatremia
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