Rosen & Barkin's 5-Minute Emergency Medicine Consult (27 page)

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Authors: Jeffrey J. Schaider,Adam Z. Barkin,Roger M. Barkin,Philip Shayne,Richard E. Wolfe,Stephen R. Hayden,Peter Rosen

Tags: #Medical, #Emergency Medicine

BOOK: Rosen & Barkin's 5-Minute Emergency Medicine Consult
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DIAGNOSIS
SIGNS AND SYMPTOMS
  • Nonspecific findings
  • Vital signs:
    • Tachypnea or Kussmaul respirations with metabolic acidosis
    • Hypoventilation with respiratory acidosis
    • Tachycardia
  • Somnolence
  • Confusion
  • Altered mental status (CO
    2
    narcosis)
  • Myocardial conduction and contraction disturbances (dysrhythmias)
ESSENTIAL WORKUP
  • Electrolytes, BUN, creatinine, and glucose:
    • Decreased bicarbonate with metabolic acidosis
    • Hyperkalemia and hypercalcemia with severe metabolic acidosis
  • Arterial blood gases:
    • pH
    • CO
      2
      retention in respiratory acidosis
    • CO level

Check the degree of compensation by calculating the expected values and comparing them to the observed laboratory values as follows:

  • Respiratory acidosis:
    • Acute: Expected HCO
      3

      increased by 1 mEq/L for every 10 mm Hg increase in PaCO
      2
    • Chronic: Expected HCO
      3

      increased by 4 mEq/L for every 10 mm Hg increase in PaCO
      2
  • Calculate anion gap: Na
    +
    – (HCO
    3

    + Cl

    ):
    • Correct anion gap for hypoalbuminemia:
      • For every 1 g/dL decrease in albumin (from 4 g/dL), add 2.5 points to calculated anion gap.
    • Do not correct sodium concentration when calculating the anion gap in the setting of marked hyperglycemia because hyperglycemia affects the concentration of chloride and bicarbonate, as well as sodium.
    • Normal range = 5 – 12 ± 3 mEq/L
    • Anion gap >25 mEq/L is seen only with:
      • Lactic acidosis
      • Ketoacidosis
      • Toxin-associated acidosis
  • Calculate the degree of compensation:
    • Expected PaCO
      2
      = 1.5[HCO
      3

      ] + 8
    • If PaCO
      2
      inappropriately high, patient has a concomitant respiratory acidosis and/or inadequate compensation.
  • Evaluate the delta gap (ΔGap):
    • For every 1-point increase in anion gap, HCO
      3

      should decrease by ∼1 mEq/L in simple acid–base disorder.
    • As the volumes of distribution of the unmeasured anions and serum HCO
      3

      are not in unity, a ΔGap > 6 signifies a mixed acid–base disorder
  • Evaluate ΔGap by comparing the change in the anion gap (ΔAG) with the change in the HCO
    3

    (ΔHCO
    3

    ) from normal:
    • If ΔAG > ΔHCO
      3

      , then patient has a concomitant metabolic alkalosis.
    • If ΔHCO
      3

      > ΔAG, then patient has concomitant nonanion gap acidosis.
DIAGNOSIS TESTS & NTERPRETATION
Lab
  • ABG: See interpretation above.
  • VBG:
    • Obvious benefit is less patient discomfort and ease in acquiring sample
    • pH varies by <0.04 units when compared to arterial sampling.
    • Correlation between venous pCO
      2
      lacking
    • Limited role in screening for hypercapnia. pCO
      2
      >45 mm Hg is sensitive (but not specific) for detection of arterial pCO
      2
      > 50 mm Hg in hemodynamically stable patients
    • Useful in simple acid–base disorders
  • Urinalysis for glucose and ketones
  • Measure serum osmolality:
    • Calculated serum osmolality = 2 Na + glucose/18 + BUN/2.8
  • Osmolar gap = difference between calculated and measured osmolality:
    • Normal = <10
    • Elevated osmolar gap may indicate toxic alcohol as etiology of acidosis.
    • Absence of an osmolar gap should never be used to rule out toxic ingestions:
      • Osmolar gap imprecisely defined
      • Delayed presentations may have normal gap
      • Large variance in gap among normal patients
  • Toxicology screen:
    • Methanol, ethylene glycol, ethanol, and isopropyl alcohol if increased osmolality gap
    • Aspirin or iron levels for suspected ingestion
  • Co-oximetry for CO exposure
  • Serum ketones or β-hydroxybutyrate level
  • Serum lactate
Imaging

CXR:

  • May identify cardiomyopathy or CHF
  • Underlying pneumonia
Diagnostic Procedures/Surgery

ECG:

  • May identify regional wall motion abnormalities or valvular dysfunction
  • Evaluate for conduction disturbances
DIFFERENTIAL DIAGNOSIS
  • Anion gap acidosis:
    • Mnemonic
      A CATPILES MUD
  • Increased osmolar gap:
    • Mnemonic
      ME DIE
TREATMENT
INITIAL STABILIZATION/THERAPY

Airway, breathing, and circulation (ABCs):

  • Early intubation for severe metabolic acidosis with progressive/potential weakening of respiratory compensation
  • Naloxone, D
    50
    W (or Accu-Chek), and thiamine if mental status altered
ED TREATMENT/PROCEDURES
  • Respiratory acidosis:
    • Treat underlying disorder
    • Provide ventilatory support for worsening hypercapnia
    • Identify and correct aggravating factors (pneumonia) in chronic hypercapnia.
  • Metabolic acidosis:
    • Identify if concurrent osmolar gap.
    • Treat underlying disorder:
      • Diabetic ketoacidosis
      • Lactic acidosis
      • Alcohol ketoacidosis
      • Ingestion
    • Correct electrolyte abnormalities.
  • IV fluids:
    • Rehydrate with 0.9% normal saline if patient hypovolemic.
    • Consider hemodialysis
MEDICATION
  • Dextrose: D
    50
    W 1 amp (50 mL or 25 g); (peds: D
    25
    W 4 mL/kg) IV
  • Naloxone (Narcan): 2 mg (peds: 0.1 mg/kg) IV or IM initial dose
  • Thiamine (vitamin B
    1
    ): 100 mg (peds: 50 mg) IV or IM
FOLLOW-UP
DISPOSITION
Admission Criteria

Consider ICU admission if:

  • pH <7.1
  • Altered mental status
  • Respiratory acidosis
  • Hemodynamic instability
  • Dysrhythmias
  • Electrolyte abnormalities
Discharge Criteria

Resolving or resolved anion gap metabolic acidosis

PEARLS AND PITFALLS
  • Failure to appreciate acidosis in mixed acid–base disorders
  • Failure to appreciate inadequate respiratory compensation for metabolic acidosis and need for ventilatory support
  • Clues to the presence of a mixed acid–base disorder are normal pH with abnormal PCO
    2
    or HCO
    3

    , when the HCO
    3

    and PCO
    2
    move in opposite directions, or when the pH changes in the direction opposite that expected from a known primary disorder.
ADDITIONAL READING
  • Ayers C, Dixon P. Simple Acid-Base Tutorial.
    J Parenter Enteral Nutr.
    2012;36(1):18–23.
  • Kellum JA. Determinants of plasma acid-base balance.
    Crit Care Clin
    . 2005;21(2):329–346.
  • Robinson MT, Heffner AC. Acid base disorders. In: Adams J ed.
    Emergency Medicine
    . Philadelphia, PA: Elsevier; 2012.
  • Whittier WL, Rutecki GW. Primer on clinical acid-base problem solving.
    Dis Mon
    . 2004;50:122.
See Also (Topic, Algorithm, Electronic Media Element)

Alkalosis

CODES
ICD9

276.2 Acidosis

ICD10

E87.2 Acidosis

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