Metabolic acidosis: Difference between revisions
| Line 25: | Line 25: | ||
**Normal osm gap | **Normal osm gap | ||
***[[ASA]], [[iron]], [[INH]] | ***[[ASA]], [[iron]], [[INH]] | ||
;Osm gap = measured osm - calculated osm (normal 10-15) | |||
;Calculated Osm = 2(Na)+(glucose/18)+(BUN/2.8)+(BAL/5) | |||
=== Non-gap === | === Non-gap === | ||
Revision as of 00:13, 16 February 2015
Background
- Primary acidosis if pH <7.38
- HCO3 <24 = metabolic acidosis
- Always determine if there is another acid/base process occurring
- Primary respiratory acidosis if pCO2 > pCO2expected
- Primary respiratory alkalosis if pCO2 < pCO2expected
- use Winter's formula: PCO2 (expected) = (1.5 x [HCO3–] + 8) ± 2
- In acute setting PCO2 should fall by 1 mmHg for every 1 mEq fall in HCO3
- Concurrent metabolic alkalosis if delta-delta > 28
- Delta-Delta = (AG - 12) + HCO3
Differential Diagnosis
Gap
- Lactic acidosis
- Renal failure
- Ketoacidosis
- Ingestions
- Increased osm gap
- Normal osm gap
- Osm gap = measured osm - calculated osm (normal 10-15)
- Calculated Osm = 2(Na)+(glucose/18)+(BUN/2.8)+(BAL/5)
Non-gap
- Hyperkalemia
- Resolving DKA
- Early uremic acidosis
- Early obstructive uropathy
- RTA Type IV
- Hypoaldosteronism
- K-sparing diuretics
- Hypokalemia
- RTA Type I
- RTA Type II
- Acetazolamide
- Acute diarrhea
- (May be assoc with gap if hypoperfusion -> lactic acidosis)
Treatment
- Treat source
- Correct any respiratory acidosis
- Bicarbonate
- HCO3 dose in mEq = 0.5(wt in kg) x (24 - measured HCO3)
- Each bicarb 0.5mEq/kg causes 1 meq/L rise in HCO3
- Consider for:
- Bicarb <4
- pH <7.20 AND shock/myocardial irritability
- Severe hyperchloremic acidemia
- lower threshold with non-AG acidosis (greater HCO3 loss)
- Lost bicarbonate would take days to replenish
See Also
Source
Tintinalli