Rosen & Barkin's 5-Minute Emergency Medicine Consult (42 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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MEDICATION
  • D
    50
    W: 1 ampule of 50% dextrose (25 g) IVP
  • Lorazepam (benzodiazepine): 2 mg IV and titrate to effect
  • Narcan: 2 mg IVP
  • Ondansetron: 4–8 mg IVP
  • Prochlorperazine: 5–10 mg IVP slowly (not >5 mg/min)
  • Promethazine: 12.5–25 mg IVP
  • Thiamine: 100 mg IVP
FOLLOW-UP
DISPOSITION
Admission Criteria
  • Persistent metabolic acidosis
  • Persistent signs of hypovolemia
  • Persistent nausea and vomiting
  • Abdominal pain of uncertain etiology
  • Comorbid illness requiring admission for treatment
  • Need for monitored bed due to electrolyte abnormalities requiring continued treatment
Discharge Criteria
  • Many patients can be managed in observation unit over 12–24 hr.
  • Tolerating oral fluids well
  • Resolution of metabolic abnormalities
  • No other associated illnesses requiring additional therapy
  • Most will warrant at least observation
FOLLOW-UP RECOMMENDATIONS

Counseling regarding alcohol cessation

PEARLS AND PITFALLS
  • Aggressive volume repletion with dextrose containing fluid is key.
  • Volume resuscitate with NS as necessary
  • Thiamine repletion
  • Monitor electrolytes before and after treatment.
  • Unrecognized increased osmolal gap
  • Inadequate monitoring of glucose levels
  • Failure to recognize initial electrolyte abnormalities and electrolyte shifts caused by treatment.
  • Must be placed on monitor:
    • Cases of sudden death in AKA:
      • Possible alcoholic cardiomyopathy
      • Dysrhythmias
      • Electrolyte derangements
ADDITIONAL READING
  • Cartwright MM, Hajja W, Al-Khatib S, et al. Toxigenic and metabolic causes of ketosis and ketoacidotic syndromes.
    Crit Care Clin
    . 2012;28(4): 601–631.
  • Diltoer M, Troubleyn J, Lauwers R, et al. Ketosis and cardiac failure: Common signs of a single condition.
    Eur J Emerg Med
    . 2004;11(3):172–175.
  • McGuire L, Cruickshank A, Munro P. Alcoholic ketoacidosis.
    Emerg Med J
    . 2006;23:417–420.
  • Yanagawa Y, Kiyozumi T, Hatanaka K, et al. Reversible blindness associated with alcoholic ketoacidosis.
    Am J Opthalmology
    . 2004;137(4):775–777.
  • Yanagawa Y, Sakamoto T, Okada Y. Six cases of sudden cardiac arrest in alcoholic ketoacidosis.
    Intern Med.
    2008;47(2):113–117.
See Also (Topic, Algorithm, Electronic Media Element)
  • Acidosis
  • Diabetic Ketoacidosis
CODES
ICD9

276.2 Acidosis

ICD10

E87.2 Acidosis

ALKALOSIS
Matthew T. Robinson
BASICS
DESCRIPTION
  • Respiratory alkalosis:
    • Elevated serum pH secondary to alveolar hyperventilation and decreased PaCO
      2
    • Hyperventilation occurs through stimulation of 2 receptor types:
      • Central receptors—located in the brainstem and respond to decreased CSF pH
      • Chest receptors—located in aortic arch and respond to hypoxemia
    • Increased alveolar ventilation secondary to:
      • Disorders causing acidosis
      • Hypoxemia
        or
      • Nonphysiologic stimulation of those receptors by CNS or chest disorders
    • Rarely life threatening with pH typically <7.50
  • Metabolic alkalosis:
    • Primary increase in serum HCO
      3

      secondary to loss of H
      +
      or gain of HCO
      3

    • Pathogenesis requires an initial process that generates the metabolic alkalosis with a secondary or overlapping process maintaining the alkalosis.
  • Generation occurs through 1 of the following mechanisms:
    • Gain of alkali through ingestion or infusion
    • Loss of H
      +
      through the GI tract or kidneys
    • Shift of hydrogen ions into the intracellular space
    • Contraction of extracellular fluid (ECF) volume with loss of HCO
      3

      -poor fluids
  • Renal maintenance is required to sustain a metabolic alkalosis secondary to the kidney’s enormous ability to excrete HCO
    3

    . This occurs through the following:
    • Decreased GFR (renal failure, ECF depletion)
    • Elevated tubular reabsorption of HCO
      3

      secondary to hypochloremia, hyperaldosteronism, hypokalemia, ECF depletion
  • Mortality 45% if pH >7.55 and 80% if pH >7.65
ETIOLOGY
  • Respiratory alkalosis:
    • CNS:
      • Hyperventilation syndrome
      • Pain
      • Anxiety/psychosis
      • Fever
      • Cerebrovascular accident (CVA)
      • CNS infection (meningitis, encephalitis)
      • CNS mass lesion (tumor, trauma)
    • Hypoxemia:
      • Altitude
      • Anemia
      • Shunt
    • Medications/drugs:
      • Progesterone
      • Methylxanthines
      • Salicylates
      • Catecholamines
      • Nicotine
    • Endocrine:
      • Hyperthyroidism
      • Pregnancy
    • Chest stimulation:
      • Pulmonary embolism
      • Pneumonia
      • Pneumothorax
    • Other:
      • Sepsis
      • Hepatic failure
      • Heat exhaustion
  • Metabolic alkalosis:
    • GI loss of H
      +
      :
      • Vomiting
      • Nasogastric (NG) suctioning
      • Bulimia
      • Antacid therapy
      • Chloride-losing diarrhea (villous adenoma)
    • Renal loss:
      • Diuretics (loop and thiazide)
      • Post (chronic) hypercapnia
      • Mineralocorticoid excess
      • Hyperaldosteronism
      • Drug/medication (carbenicillin)
      • Glucocorticoid excess (Cushing disease)
      • Gitelman syndrome
      • Hypercalcemia
      • Milk–alkali syndrome
      • Low chloride intake
      • Bartter syndrome
    • Intracellular H
      +
      shift:
      • Hypokalemia
      • Refeeding
    • Contraction alkalosis:
      • Diuretics
      • Sweat loss in CF
      • Gastric losses
    • HCO
      3

      retention:
      • NaHCO
        3
        infusion
      • Blood transfusions
DIAGNOSIS
SIGNS AND SYMPTOMS
  • Signs and symptoms secondary to:
    • Arteriolar vasoconstriction
    • Hypocalcemia secondary to decreased ionized calcium from increased calcium binding to albumin
    • Associated hypokalemia
    • Underlying cause
  • Weakness
  • Seizures
  • Altered mental status
  • Tetany
  • Chvostek sign
  • Trousseau sign
  • Arrhythmias
  • Myalgias
  • Carpal–pedal spasm
  • Perioral tingling/numbness
  • Hypoxemia
  • Dehydration
ESSENTIAL WORKUP
  • Electrolytes:
    • Elevated HCO
      3

      with metabolic alkalosis
    • Evaluate for hypokalemia and hypocalcemia.
  • BUN/creatinine:
    • Evaluate for renal failure or dehydration.
  • Blood gas (arterial/venous):
    • pH
    • PCO
      2
      decreased in respiratory alkalosis
    • PO
      2
      for hypoxemia
    • Venous versus arterial blood gas
      • pH—good correlation within 0.03–0.04 units
      • pCO2—good correlation, although VBG may not correlate with severe shock
      • HCO3—good correlation
      • Base excess—good correlation
  • Calculate compensation to identify mixed acid–base disorders:
    • Acute respiratory alkalosis:
      • HCO
        3

        decreases secondary to intracellular shift and buffering within 10–20 min.
      • Expected HCO
        3

        decreased by 2 mEq/dL for each 10 mm Hg decrease in PCO
        2
        .
    • Chronic respiratory alkalosis:
      • HCO
        3

        decreased secondary to renal secretion of HCO
        3

      • Requires 48–72 hr for maximal compensation
      • Expected HCO
        3

        decreased by 5 mEq/dL for each 10 mm Hg decrease in PCO
        2
        .
      • If HCO
        3

        greater than predicted, concomitant metabolic alkalosis
      • If HCO
        3

        less than predicted, concomitant metabolic acidosis
    • Metabolic alkalosis:
      • Expected PCO
        2
        = 0.9 [HCO
        3

        ] + 9
      • If PCO
        2
        greater than predicted, concomitant respiratory acidosis
      • If PCO
        2
        less than predicted, concomitant respiratory alkalosis
  • Urine chloride:
    • More accurate marker than urine Na
      +
      for patient’s volume status:
      • UCl

        <20 mEq/L in volume depletion
      • UCl

        >40 mEq/L in euvolemia or edematous states
  • Useful in therapy for determining saline-responsive vs. saline-resistant causes of metabolic alkalosis

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