Ausführlicher Leitfaden kommt bald
Wir arbeiten an einem umfassenden Bildungsleitfaden für den Plasma Osmolality Calculator. Schauen Sie bald wieder vorbei für Schritt-für-Schritt-Erklärungen, Formeln, Praxisbeispiele und Expertentipps.
Plasma osmolality is a measure of the total solute concentration in the blood, expressed in milliosmoles per kilogram of water (mOsm/kg). It reflects the concentration of all dissolved particles in plasma — primarily sodium and its accompanying anions, glucose, and urea. The body regulates plasma osmolality within the narrow physiological range of 280–295 mOsm/kg through a tightly coupled system involving antidiuretic hormone (ADH, also called vasopressin), the hypothalamic thirst centre, and renal free water regulation. Even a 1–2% deviation in osmolality triggers ADH secretion or thirst, making osmolality one of the most precisely regulated physiological variables. The calculated plasma osmolality formula is an essential clinical tool for the workup of hyponatraemia, hypernatraemia, and disorders of water balance. By comparing calculated and measured osmolality, clinicians can calculate the osmolal gap to detect unmeasured osmoles (toxic alcohols, mannitol). By excluding urea (a freely diffusible, ineffective osmole), the effective osmolality or tonicity can be calculated — this is the biologically relevant value that drives cell swelling and shrinkage, and it directly governs the clinical manifestations of sodium disorders. Understanding the distinction between osmolality (all solutes) and tonicity (effective, non-diffusible solutes) is fundamental to the diagnosis and safe treatment of sodium and water disorders.
Posm = 2×Na + Glucose/18 + BUN/2.8 (mg/dL); SI: Posm = 2×Na + Glucose + Urea (mmol/L). Effective osmolality (tonicity): Eosm = 2×Na + Glucose/18. Quick bedside estimate: Posm ≈ 2×Na + 10
- 1Obtain serum chemistry values: sodium (Na, mEq/L), glucose (mg/dL or mmol/L), and BUN or urea (mg/dL BUN or mmol/L urea).
- 2Apply the main formula: 2×Na + Glucose/18 + BUN/2.8 for mg/dL units. The factor of 2 applied to sodium accounts for the chloride and bicarbonate counterions. Dividing glucose by 18 and BUN by 2.8 converts mg/dL to the equivalent mmol/L (mOsm/kg contribution).
- 3For SI units: 2×Na (mEq/L) + Glucose (mmol/L) + Urea (mmol/L) — no conversion divisors needed since mmol/L already equals mOsm/kg for these uncharged molecules.
- 4For a rapid bedside estimate without glucose and BUN: use Posm ≈ 2×Na + 10. This shortcut is less precise but useful for immediate clinical decisions.
- 5Calculate effective osmolality (tonicity) by excluding urea: Eosm = 2×Na + Glucose/18. Urea is excluded because it diffuses freely across cell membranes and does not cause osmotic water shifts between compartments.
- 6Compare calculated to measured (laboratory) osmolality to determine the osmolal gap — a gap >10 mOsm/kg suggests unmeasured osmoles.
- 7Interpret the result: normal 280–295 mOsm/kg; low (<280) suggests hypo-osmolality; high (>295) suggests hyperosmolality. Integrate with clinical context, sodium level, and urine osmolality.
Euosmolar state — all three major solute contributors are within normal range
2×140 + 90/18 + 14/2.8 = 280 + 5 + 5 = 290 mOsm/kg. Effective osmolality = 2×140 + 90/18 = 285 mOsm/kg (urea excluded). Normal range 280–295.
Low osmolality confirms true hyponatraemia (not pseudohyponatraemia). Low BUN consistent with SIADH — suppressed urea from free water excess
2×122 + 85/18 + 8/2.8 = 244 + 4.7 + 2.9 = 251.6 ≈ 252 mOsm/kg. Effective osmolality = 2×122 + 4.7 = 248.7. Measured lab osmolality should match closely — if much higher, pseudohyponatraemia or unmeasured osmoles present.
Effective osmolality >320 mOsm/kg meets diagnostic criteria for HHS; severely impaired consciousness expected
2×148 + 900/18 + 42/2.8 = 296 + 50 + 15 = 361 mOsm/kg total. Effective (excluding urea) = 296 + 50 = 346 mOsm/kg. The HHS diagnostic threshold is effective osmolality >320 mOsm/kg with glucose >600 mg/dL and minimal ketosis.
Hypernatraemia with calculated hyperosmolality; free water deficit should be calculated to guide replacement rate
2×158 + 95/18 + 22/2.8 = 316 + 5.3 + 7.9 = 329.2 ≈ 330 mOsm/kg. This level of hypernatraemia (Na 158) is consistent with central or nephrogenic diabetes insipidus with inadequate free water intake. Rapid correction risks cerebral oedema — aim for <10 mEq/L Na reduction per day.
Hyponatraemia workup — distinguishing hypo-osmolar from iso-osmolar and hyperosmolar hyponatraemia to identify SIADH, pseudohyponatraemia, and translocational states, where accurate plasma osmolality analysis through the Plasma Osmolality supports evidence-based decision-making and quantitative rigor in professional workflows
Hyperosmolar hyperglycaemic state (HHS) diagnosis and treatment monitoring — effective osmolality drives consciousness level and correction rate decisions, where accurate plasma osmolality analysis through the Plasma Osmolality supports evidence-based decision-making and quantitative rigor in professional workflows
Osmolal gap calculation as a toxicology screen for toxic alcohol ingestion in emergency presentations, where accurate plasma osmolality analysis through the Plasma Osmolality supports evidence-based decision-making and quantitative rigor in professional workflows
Safe hyponatraemia correction rate monitoring to prevent osmotic demyelination syndrome, where accurate plasma osmolality analysis through the Plasma Osmolality supports evidence-based decision-making and quantitative rigor in professional workflows across diverse organizational contexts and analytical requirements
Polyuria evaluation — comparing plasma osmolality to urine osmolality to differentiate diabetes insipidus from primary polydipsia
Corrected sodium in hyperglycaemia
In hyperglycaemia, glucose draws water into the extracellular space by osmosis, diluting sodium. The measured sodium is factitiously low. Corrected sodium = measured Na + 1.6 × (Glucose − 100) / 100 (mg/dL), or more precisely +2.4 mEq/L per 100 mg/dL glucose above 100 mg/dL using newer corrections. Effective osmolality is more clinically useful than corrected sodium in guiding HHS management.
Urea as an ineffective osmole in uraemia
Patients with renal failure and severe uraemia may have markedly elevated total plasma osmolality due to urea, but effective osmolality (and therefore the driving force for cell volume change) is not proportionally increased. Urea equilibrates across all biological membranes and does not contribute to sustained osmotic gradients. Rapidly dialysing away urea, however, can create a transient osmotic disequilibrium syndrome if plasma osmolality drops too quickly.
Hyponatraemia with normal or high osmolality
True hyponatraemia is always associated with low plasma osmolality. When hyponatraemia coexists with normal or high osmolality, the cause is either: (1) pseudohyponatraemia from lipid or protein displacement (osmolality normal); or (2) the presence of another osmole such as glucose, mannitol, or contrast drawing water out of cells and diluting sodium (osmolality elevated). This is called translocational hyponatraemia — sodium is low but the patient is actually hyperosmolar.
Osmotic demyelination syndrome risk in hyponatraemia correction
Plasma osmolality calculation is essential for monitoring the safe rate of hyponatraemia correction. Overly rapid correction (raising sodium >8–10 mEq/L per 24 hours) risks osmotic demyelination syndrome (previously called central pontine myelinolysis), a devastating neurological complication. Daily serum sodium monitoring and calculated osmolality changes guide the treating team in maintaining safe correction rates.
Beer potomania and reset osmostat
Beer potomania is a syndrome of severe hyponatraemia caused by very high water intake (from beer) with minimal solute intake. The kidneys cannot concentrate urine further than the minimum urine osmolality (~50 mOsm/kg) when solute delivery is insufficient. A reset osmostat is a variant of SIADH where the hypothalamus resets its osmolality set-point to a lower level, maintaining a stable but low plasma osmolality that may not respond to standard water restriction.
| Posm (mOsm/kg) | Classification | Common Causes | Key Investigation |
|---|---|---|---|
| < 275 | Hypo-osmolality | SIADH, hypothyroidism, adrenal insufficiency, heart failure, excess IV fluids | Urine osmolality, urine Na, TFTs, cortisol |
| 275–280 | Low-normal | Mild fluid excess, early SIADH | Repeat with clinical context |
| 280–295 | Normal | Euosmolar state | No action if asymptomatic |
| 295–310 | Mildly elevated | Mild hypernatraemia, early dehydration, moderate hyperglycaemia | Assess fluid status and intake |
| 310–330 | Moderately elevated | Significant hypernatraemia, DI, HHS | Free water deficit calculation; urine Osm |
| > 330 | Critically elevated | Severe HHS, severe hypernatraemia, toxic alcohol poisoning | Urgent management; ICU consideration |
What is the difference between osmolality and tonicity?
Osmolality measures all dissolved solutes regardless of whether they cross cell membranes. Tonicity (effective osmolality) measures only solutes that are effectively excluded from cells — primarily sodium and glucose. Urea diffuses freely across cell membranes and therefore does not cause osmotic water shifts between intracellular and extracellular compartments. This is why uraemia (high urea) causes a high measured and calculated osmolality but does not cause cell dehydration or shrinkage — urea equilibrates across membranes and is an ineffective osmole.
Why does the formula multiply sodium by 2?
Sodium is the dominant extracellular cation. To maintain electroneutrality, each sodium ion is accompanied by an anion — predominantly chloride and bicarbonate. Although these anions contribute separately to osmolality, the factor of 2 applied to sodium provides a practical approximation that accounts for sodium plus its associated anions in one step. This is an approximation: the true value depends on the specific anion composition of the plasma.
What does a low plasma osmolality mean?
A low calculated osmolality (<280 mOsm/kg) reflects hyponatraemia as the primary driver, since sodium (×2) is the dominant term. The clinical causes of hypo-osmolality include SIADH, hypothyroidism, adrenal insufficiency, cardiac failure with free water excess, and excess hypotonic fluid administration. Hypo-osmolality causes cellular swelling — neurons in the brain are particularly vulnerable, causing symptoms ranging from headache and nausea to seizures and coma.
What is SIADH and how does plasma osmolality help diagnose it?
Syndrome of Inappropriate ADH secretion (SIADH) causes free water retention with dilutional hyponatraemia and hypo-osmolality. The diagnostic criteria require: plasma osmolality <280 mOsm/kg AND urine osmolality >100 mOsm/kg (inappropriately concentrated urine despite plasma hypo-osmolality) AND urine sodium >30 mEq/L in a euvolaemic patient without thyroid or adrenal disease. Plasma osmolality calculation is the first step in confirming that hyponatraemia is truly hypotonic rather than pseudohyponatraemia.
How is plasma osmolality used in hyperosmolar hyperglycaemic state (HHS)?
HHS is defined partly by effective osmolality >320 mOsm/kg, calculated by excluding urea: Eosm = 2×Na + Glucose/18. Consciousness level in HHS correlates with effective osmolality, not total osmolality, because urea equilibrates across the blood-brain barrier. An effective osmolality above 320–330 mOsm/kg causes severe neurological impairment. Treatment targets gradual reduction of effective osmolality at <3–4 mOsm/kg/hour to avoid cerebral oedema.
What is pseudohyponatraemia?
Pseudohyponatraemia is an artefactual lowering of measured serum sodium caused by severe hyperlipidaemia or hyperproteinaemia (e.g., multiple myeloma). Excess lipid or protein displaces water in the plasma sample, reducing sodium concentration per unit plasma volume while plasma osmolality remains normal. The measured (laboratory) osmolality is normal while calculated osmolality (based on the falsely low sodium) appears low, creating an apparent large negative osmolal gap. Modern direct ISE (ion-selective electrode) methods are less prone to this artefact.
How does the bedside formula Posm ≈ 2×Na + 10 work?
This rapid approximation assumes glucose and BUN are approximately 5 mOsm/kg each (corresponding to glucose ~90 mg/dL and BUN ~14 mg/dL), contributing a combined 10 mOsm/kg. It is useful for quick mental arithmetic but becomes inaccurate when glucose or BUN are significantly abnormal (e.g., diabetic hyperglycaemia, renal failure with high urea, or hypoglycaemia). Always use the full formula when chemistry values are available.
What urine osmolality values are clinically important?
Urine osmolality provides crucial context alongside plasma osmolality: urine osmolality <100 mOsm/kg in the setting of hyponatraemia suggests psychogenic polydipsia or beer potomania (dilute urine appropriately). Urine >100 mOsm/kg in hyponatraemia suggests SIADH or other causes of inappropriate ADH. In hypernatraemia, urine >800 mOsm/kg indicates appropriate renal water conservation (extrarenal losses); urine <300 mOsm/kg suggests central or nephrogenic diabetes insipidus.
Profi-Tipp
In a patient with hyponatraemia, always check urine osmolality and urine sodium alongside plasma osmolality. The pair of plasma hypo-osmolality plus inappropriately concentrated urine (>100 mOsm/kg) in a euvolaemic patient is pathognomonic of SIADH. Urine that is maximally dilute (<100 mOsm/kg) in the same patient points to primary polydipsia or beer potomania — managed with fluid restriction alone rather than salt or vasopressin antagonists.
Wussten Sie?
The hypothalamus can detect a change in plasma osmolality of as little as 1 mOsm/kg — equivalent to adding roughly 2 tablespoons of salt to the entire blood volume. This exquisite sensitivity is why ADH secretion and thirst are so precisely calibrated: the body aims to keep plasma osmolality within a range of just 2–3% of its set-point at all times.
Referenzen
- ›Spasovski G et al. — Clinical practice guideline on diagnosis and treatment of hyponatraemia (Eur J Endocrinol 2014)
- ›Verbalis JG et al. — Diagnosis, evaluation and treatment of hyponatremia (Am J Med 2013)
- ›KDIGO 2012 AKI Guidelines — Fluid and electrolyte management
- ›Rose BD, Post TW — Clinical Physiology of Acid-Base and Electrolyte Disorders, 5th ed.
- ›NHS Clinical Knowledge Summary — Hyponatraemia