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Arterial Blood Gas Analysis

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Base Excess - /-2 mEq/L. Why Order an ABG? Aids in establishing a diagnosis ... 1 month old male presents with projectile emesis x 2 days. ABG - 7.49 / 40 / 98 / 30 ... – PowerPoint PPT presentation

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Title: Arterial Blood Gas Analysis


1
Arterial Blood Gas Analysis
  • Vanessa Klee MSIV

2
What is an ABG?
  • The Components
  • pH / PaCO2 / PaO2 / HCO3 / O2sat / BE
  • Desired Ranges
  • pH - 7.35 - 7.45
  • PaCO2 - 35-45 mmHg
  • PaO2 - 80-100 mmHg
  • HCO3 - 21-27
  • O2sat - 95-100
  • Base Excess - /-2 mEq/L

3
Why Order an ABG?
  • Aids in establishing a diagnosis
  • Helps guide treatment plan
  • Aids in ventilator management
  • Improvement in acid/base management allows for
    optimal function of medications
  • Acid/base status may alter electrolyte levels
    critical to patient status/care

4
Logistics
  • When to order an arterial line --
  • Need for continuous BP monitoring
  • Need for multiple ABGs
  • Where to place -- the options
  • Radial
  • Femoral
  • Brachial
  • Dorsalis Pedis
  • Axillary

5
Acid Base Balance
  • The body produces acids daily
  • 15,000 mmol CO2
  • 50-100 mEq Nonvolatile acids
  • The lungs and kidneys attempt to maintain balance

6
Acid Base Balance
  • Assessment of status via bicarbonate-carbon
    dioxide buffer system
  • CO2 H2O lt--gt H2CO3 lt--gt HCO3- H
  • ph 6.10 log (HCO3 / 0.03 x PCO2)

7
The Terms
  • ACIDS
  • Acidemia
  • Acidosis
  • Respiratory
  • ?CO2
  • Metabolic
  • ?HCO3
  • BASES
  • Alkalemia
  • Alkalosis
  • Respiratory
  • ?CO2
  • Metabolic
  • ?HCO3

8
Respiratory Acidosis
  • ?ph, ?CO2, ?Ventilation
  • Causes
  • CNS depression
  • Pleural disease
  • COPD/ARDS
  • Musculoskeletal disorders
  • Compensation for metabolic alkalosis

9
Respiratory Acidosis
  • Acute vs Chronic
  • Acute - little kidney involvement. Buffering via
    titration via Hb for example
  • pH ?by 0.08 for 10mmHg ? in CO2
  • Chronic - Renal compensation via synthesis and
    retention of HCO3 (?Cl to balance charges ?
    hypochloremia)
  • pH ?by 0.03 for 10mmHg ?in CO2

10
Respiratory Alkalosis
  • ?pH, ?CO2, ?Ventilation
  • ? CO2 ? ? HCO3 (?Cl to balance charges ?
    hyperchloremia)
  • Causes
  • Intracerebral hemorrhage
  • Salicylate and Progesterone drug usage
  • Anxiety ? ?lung compliance
  • Cirrhosis of the liver
  • Sepsis

11
Respiratory Alkalosis
  • Acute vs. Chronic
  • Acute - ?HCO3 by 2 mEq/L for every 10mmHg ? in
    PCO2
  • Chronic - Ratio increases to 4 mEq/L of HCO3 for
    every 10mmHg ? in PCO2
  • Decreased bicarb reabsorption and decreased
    ammonium excretion to normalize pH

12
Metabolic Acidosis
  • ?pH, ?HCO3
  • 12-24 hours for complete activation of
    respiratory compensation
  • ?PCO2 by 1.2mmHg for every 1 mEq/L ?HCO3
  • The degree of compensation is assessed via the
    Winters Formula
  • ? PCO2 1.5(HCO3) 8 ? 2

13
The Causes
  • Metabolic Gap Acidosis
  • M - Methanol
  • U - Uremia
  • D - DKA
  • P - Paraldehyde
  • I - INH
  • L - Lactic Acidosis
  • E - Ehylene Glycol
  • S - Salicylate
  • Non Gap Metabolic Acidosis
  • Hyperalimentation
  • Acetazolamide
  • RTA (Calculate urine anion gap)
  • Diarrhea
  • Pancreatic Fistula

14
Metabolic Alkalosis
  • ?pH, ?HCO3
  • ?PCO2 by 0.7 for every 1mEq/L ? in HCO3
  • Causes
  • Vomiting
  • Diuretics
  • Chronic diarrhea
  • Hypokalemia
  • Renal Failure

15
Mixed Acid-Base Disorders
  • Patients may have two or more acid-base disorders
    at one time
  • Delta Gap
  • Delta HCO3 HCO3 Change in anion gap
  • gt24 metabolic alkalosis

16
The Steps
  • Start with the pH
  • Note the PCO2
  • Calculate anion gap
  • Determine compensation

17
Sample Problem 1
  • An ill-appearing alcoholic male presents with
    nausea and vomiting.
  • ABG - 7.4 / 41 / 85 / 22
  • Na- 137 / K- 3.8 / Cl- 90 / HCO3- 22

18
Sample Problem 1
  • Anion Gap 137 - (90 22) 25
  • ? anion gap metabolic acidosis
  • Winters Formula 1.5(22) 8 ? 2
  • 39 ? 2
  • ? compensated
  • Delta Gap 25 - 10 15
  • 15 22 37
  • ? metabolic alkalosis

19
Sample Problem 2
  • 22 year old female presents for attempted
    overdose. She has taken an unknown amount of
    Midol containing aspirin, cinnamedrine, and
    caffeine. On exam she is experiencing
    respiratory distress.

20
Sample Problem 2
  • ABG - 7.47 / 19 / 123 / 14
  • Na- 145 / K- 3.6 / Cl- 109 / HCO3- 17
  • ASA level - 38.2 mg/dL

21
Sample Problem 2
  • Anion Gap 145 - (109 17) 19
  • ? anion gap metabolic acidosis
  • Winters Formula 1.5 (17) 8 ? 2
  • 34 ? 2
  • ? uncompensated
  • Delta Gap 19 - 10 9
  • 9 17 26
  • ? no metabolic alkalosis

22
Sample Problem 3
  • 47 year old male experienced crush injury at
    construction site.
  • ABG - 7.3 / 32 / 96 / 15
  • Na- 135 / K-5 / Cl- 98 / HCO3- 15 / BUN- 38 / Cr-
    1.7
  • CK- 42, 346

23
Sample Problem 3
  • Anion Gap 135 - (98 15) 22
  • ? anion gap metabolic acidosis
  • Winters Formula 1.5 (15) 8 ? 2
  • 30 ? 2
  • ? compensated
  • Delta Gap 22 - 10 12
  • 12 15 27
  • ? mild metabolic alkalosis

24
Sample Problem 4
  • 1 month old male presents with projectile emesis
    x 2 days.
  • ABG - 7.49 / 40 / 98 / 30
  • Na- 140 / K- 2.9 / Cl- 92 / HCO3- 32

25
Sample Problem 4
  • Metabolic Alkalosis, hypochloremic
  • Winters Formula 1.5 (30) 8 ? 2
  • 53 ? 2
  • ? uncompensated
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