|Serum osmotic gap|
|Na+ = 140||Cl− = 100||BUN = 20||/|
|Glu = 150|
|K+ = 4||CO2 = 22||PCr = 1.0||\|
|ARTERIAL BLOOD GAS:|
|HCO3− = 24||paCO2 = 40||paO2 = 95||pH = 7.40|
|pACO2 = 36||pAO2 = 105||A-a g = 10|
|Ca = 9.5||Mg2+ = 2.0||PO4 = 1|
|CK = 55||BE = −0.36||AG = 16|
|PMO = 300||PCO = 295||POG = 5||BUN:Cr = 20|
|UNa+ = 80||UCl− = 100||UAG = 5||FENa = 0.95|
|UK+ = 25||USG = 1.01||UCr = 60||UO = 800|
|PROTEIN/GI/LIVER FUNCTION TESTS:|
|LDH = 100||TP = 7.6||AST = 25||TBIL = 0.7|
|ALP = 71||Alb = 4.0||ALT = 40||BC = 0.5|
|AST/ALT = 0.6||BU = 0.2|
|AF alb = 3.0||SAAG = 1.0||SOG = 60|
|CSF alb = 30||CSF glu = 60||CSF/S alb = 7.5||CSF/S glu = 0.4|
There are a variety of ions and molecules dissolved in the serum. The major constitutionals of clinical importance are sodium ions, glucose, and blood urea nitrogen (BUN), plus ethyl alcohol in a person who has been drinking. As part of a laboratory blood test, a vial of blood is tested for the amount of these four ions and molecules that are present in the blood. From this measurement, the clinician can calculate the plasma osmolality of a patients blood. A second vial is also sent to the laboratory. This vial is put in an instrument that measures the freezing point depression of all the solutes in the plasma. This measurement gives the true plasma osmolality. The calculated osmolality is then subtracted from the measured osmolality to provide the osmol gap, or the difference between these two values. If this gap falls within an acceptable range,(<10) then it is assumed that sodium, glucose, BUN are indeed the major dissolved ions and molecules in the serum. If, however, the calculated gap is above an acceptable range, then it is an indication that there is something else dissolved in the serum that is producing an osmol gap, which can be a major clue in determining what is ailing the patient.
Explanation of units
Since laboratories measure serum solutes in terms of freezing point depression, the reported units are properly units of osmolality. When a measure of serum solutes is calculated, it is often done in units of osmolarity. While it is possible to convert between osmolality and osmolarity, thereby deriving a more mathematically correct osmol gap calculation, in actual clinical practice this is not done. This is because the difference in absolute value of these two measurements that can be attributed to the difference in units will be negligible in a clinical setting. For this reason, the terms are often used interchangeably, though some object to equating the terms. Because the calculated osmol gap can therefore be a conflation of both terms (depending on how it is derived), neither term (osmolal gap nor osmolar gap) may be semantically correct. To avoid ambiguity, the terms "osmolal" and "osmolar" can be used when the units of molality or molarity are consistent throughout the calculation. When this is not the case, the term "osmol gap" can be used when units are mixed to provide a clinical estimate.
The osmol gap is typically calculated as:
- OG = measured serum osmolality − calculated osmolality
Calculated osmolality = 2 x [Na mmol/L] + [glucose mmol/L] + [urea mmol/L] + 1.25 x [Ethanol mmol/L]
In non-SI laboratory units: Calculated osmolality = 2 x [Na mmol/L] + [glucose mg/dL] / 18 + [BUN mg/dL] / 2.8 + [Ethanol/3.7] (note: the values 18, 2.8 and 3.7 convert mg/dL into mmol/L)
A normal osmol gap is < 10 mOsm/kg .
The molecular weight of ethanol is 46, but empiric data shows that it does not act as an ideal osmole in solution and the appropriate divisor is 3.7
Osmol gaps are used as a screening tool to identify toxins.
Causes of an elevated osmol gap are numerous. Generally there are 4 main causes:
All four are osmotically active substances found in humans. Accordingly, intoxications as listed below are reasons for an increased osmolar gap.
- ethanol intoxication
- methanol ingestion
- ethylene glycol ingestion
- acetone ingestion (not a true alcohol)
- isopropyl alcohol ingestion
- propylene glycol toxicity (as with intravenous infusions where it is used as an excipient, e.g. lorazepam)
- Hypergammaglobinemia (M. Waldenström)
- "Osmolality Gap - Calculation and Interpretation". Retrieved 2009-03-04.
- Lynd LD, Richardson KJ, Purssell RA, et al. (2008). "An evaluation of the osmole gap as a screening test for toxic alcohol poisoning". BMC Emerg Med. 8: 5. doi:10.1186/1471-227X-8-5. PMC . PMID 18442409.
- Converting between osmolality and osmolarity.
- Erstad BL (September 2003). "Osmolality and osmolarity: narrowing the terminology gap". Pharmacotherapy. 23 (9): 1085–6. doi:10.1592/phco.23.10.1085.32751. PMID 14524639.
- Purssell RA, Pudek M, Brubacher J, Abu-Laban RB (December 2001). "Derivation and validation of a formula to calculate the contribution of ethanol to the osmolal gap". Ann Emerg Med. 38 (6): 653–9. doi:10.1067/mem.2001.119455. PMID 11719745.
- Plasma osmolality
- Kapur G, Valentini RP, Imam AA, Jain A, Mattoo TK (June 2007). "Serum osmolal gap in patients with idiopathic nephrotic syndrome and severe edema". Pediatrics. 119 (6): e1404–7. doi:10.1542/peds.2006-2554. PMID 17485452.
- Krahn J, Khajuria A (April 2006). "Osmolality gaps: diagnostic accuracy and long-term variability". Clin. Chem. 52 (4): 737–9. doi:10.1373/clinchem.2005.057695. PMID 16455871.
- Ammar KA, Heckerling PS (January 1996). "Ethylene glycol poisoning with a normal anion gap caused by concurrent ethanol ingestion: importance of the osmolal gap". Am. J. Kidney Dis. 27 (1): 130–3. doi:10.1016/S0272-6386(96)90040-2. PMID 8546127.