Blood gas analysis

Question 1

Acid-base homeostasis (basics)

Answer 1

• [H⁺] has high biological relevance
• H⁺ is constantly being produced by metabolism
• Acid-base homeostasis = maintaining normal [H⁺]
  
  • This involves integrated functions of lungs, kidneys, liver, and GI tract
• pH = -log₁₀[H⁺]

Question 2

What are the different buffering systems of the body?

Answer 2

• Chemical buffers (most basic buffering system)
  
  • Extracellular = HCO3–acts w/in seconds
  • Intracellular = phosphate, proteins–act w/in hours
• Respiration–acts w/in minutes
  
  • Respiratory compensation
• Renal system (excreting H+)–acts w/in hours-days
  
  • Metabolic compensation

Question 3

Henderson-Hasselbach equation (super basic)

Answer 3

• pH ≈ (HCO₃^- / PaCO₂)
• This is a simple way to understand how changes in HCO₃^- and PaCO₂ would influence the pH

Question 4

Blood gas analysis: what are the measured variables? Calculated variables?

Answer 4

• Measured
  
  • pH
  • PaCO₂
  • PaO₂
• Calculated
  
  • HCO₃^-
  • BE
  • Oxygen content (CaO₂)

Question 5

What does the suffix ‘-emia’ apply to? What does the suffix ‘-osis’ apply to?

Answer 5

• -emia = changes in blood
• -osis = physiological processes

Question 6

What do you assess for the respiratory component? Metabolic component?

Answer 6

• PaCO₂ = respiratory
• BE (base excess), (HCO₃) = metabolic

Question 7

What is the normal pH range?

Answer 7

• Normal = 7.35 - 7.45

Question 8

Define the following:

Acidosis

Alkalosis

Mixed acid-base disorders

Primary acid-base disorder

Compensation

Answer 8

• Acidoses = a physiological process, that occurring alone, tends to cause acidemia
• Alkalosis = a physiological process, that occurring alone, tends to cause alkalemia
• Mixed = different kinds of acidosis and/or alkalosis occurring together
• Primary = defined by the initial change in HCO₃ or PaCO₂
• Compensation
  
  • When a guy buys a big truck to compensate for a tiny d**k
  • Change in HCO₃ or PaCO₂ in opposite direction to those of the primary disorder. Not classified in terms of acidosis or alkalosis

Question 9

Here’s a pretty chart for acid base disorders

Answer 9

Question 10

When would you diagnose a mixed acid-base disorder (3)?

Answer 10

• pH value is unexpected from a change in HCO₃ or PaCO₂
• Normal pH with abnormal HCO₃ or PaCO₂
• HCO₃ or PaCO₂ are changing in opposite directions

Question 11

What are the normal values for pH, HCO₃ and PaCO₂? What about in herbivores? Cats?

Answer 11

• pH = 7.35 - 7.45
• HCO₃ = 24 +/- 4 mEq/L
• PaCO₂ = 35 - 45 mmHg
• Herbivores produce more bicarb
  
  • Normal values for HCO₃ are higher
• Cats are special
  
  • HCO₃ = ~20 mEq/L
  • PaCO₂ = ~30 mmHg

Question 12

Base excess (BE)–all the things

Answer 12

• Refers to an excess or deficit in the amount of base present in the blood
• Defines the metabolic component of acid-base disturbances
• Positive BE = metabolic alkalosis
• Negative BE (base deficit) = metabolic acidosis
• Refers to the difference of HCO₃ from normal value if PaCO₂ and body temperature were normalized

Question 13

Anion gap (AG)–all ze thingzz

Answer 13

• The amount of positive and negative ions should be equal in the blood
• Main positive ions: Na+ and K+
• Main negative ions: Cl- and HCO₃-
• The difference between them can be used to estimate the amount of unmeasured anions (= AG)
• AG = (Na + K) - (Cl - HCO₃)
• Normal AG is 16 +/- 4 mEq/L

Question 14

Elevated AG

Answer 14

• If there is a metabolic acidosis, calculate AG
• If AG is elevated, then unmeasured anions may explain the cause of the acidosis:
  
  • Ketoacidosis
  • Lactic acidosis
  • Uremia
  • Drug poisoning: aspirin, ethylene glycol, methanol, etc.

Question 15

Normal AG (with metabolic acidosis)

Answer 15

• Cause may be Cl- retention or HCO₃- excretion
• Typical examples
  
  • Diarrhea
  • Renal diseases

Question 16

Total CO₂

Answer 16

• CO₂ exists in blood as HCO₃ and dissolved CO₂
• Dissolved CO₂ is a small amount (~1.2 mEq/L)
• TCO₂ is almost the same as HCO₃
  
  • Can use interchangeably if bicarb is not available

Question 17

What are some other methods to diagnose acid-base disorders?

Answer 17

• Strong ion difference (SID)
• Total concentration of non-volatile weak acids (Atot)

Question 18

PaCO₂ equation

Answer 18

• PaCO₂: partial pressure (mmHg) of CO₂ in the arterial blood
• PaCO₂ is directly related to CO₂ production and inversely to CO₂ elimination (alveolar ventilation)
• PaCO₂ ≈ (CO₂ production) / (alveolar ventilation)

Question 19

Normal PaCO₂ values? What should these definitions not be used for?

Answer 19

• Definitions should not be used to describe breathing pattern in the patient
• Any combination of RR, tidal volume, or breathing effort can reflect any PaCO₂ value

Question 20

Increased PaCO₂ will do what 4 things?

Answer 20

• Lower the PAO₂
• Lower the pH
• Reflect respiratory acidosis
• Reflect respiratory compensation for metabolic acidosis

Question 21

PaO₂

Answer 21

• Partial pressure (mmHg) of O₂ in the arterial blood
• Does not reflect O₂ content
• Interpreted in light of
  
  • FiO₂
  • Ambient pressure
  • PaCO₂

Question 22

FiO₂ and PAO₂

Answer 22

• FiO₂ = fraction of inspired O₂
  
  • For 100% O2: FiO₂ = 1
  • For air: FiO₂ = 0.21
• PAO₂ = partial pressure (mmHg) of O₂ in the alveolar space

Question 23

Alveolar gas equation

Answer 23

• PAO2 is a calculated value

Question 24

A-a PO₂ difference

Answer 24

• The upper limit of PaO₂ is the PAO₂
• If gas exchange in the lungs would be ideal, these values would be the same
• In real life, PaO₂ is always lower
• The difference between them is termed the A-a PO₂ difference
• The term “A-a gradient” is also used but isn’t ideal since it is not a ‘gradient’

Question 25

What does a higher than normal A-a PO₂ difference mean? What are some reasons for high values?

Answer 25

• Means that the PaO₂ is lower than expected
• Reasons
  
  • Ventilation/perfusion inequality (V/Q mismatch)
    
    • More specifically: low V/Q will drive PaO₂ down
  • Right to left shunt

Question 26

What are some reasons for V/Q mismatch?

Answer 26

• Atelectasis (common under anesthesia)
• Lung diseases such as
  
  • Asthma
  • Pulmonary edema
  • Adult respiratory distress syndrome (ARDS)
  • Pneumonia, etc.

Question 27

PaO₂/FiO₂ ratio

Answer 27

• Serves the same purpose as the A-a PO2 difference but is easier to interpret
• Normal = > 500 mmHg
• Should only be used as a rule of thumb when
  
  • PaCO2 is normal
  • Ambient pressure is at sea level

Question 28

Hypoxemia

Answer 28

• Insufficient oxygenation of arterial blood
• Defined as:
  
  • ​SpO2 < 90%
  • PaO2 < 60 mmHg

Question 29

What are 5 causes of hypoxemia (low PaO2)

Answer 29

1. Low FiO2 (more exactly PiO2)
2. Hypoventilation
3. Diffusion impairment
4. V/Q mismatch
5. Right to left shunt

Question 30

T/F: Under anesthesia, while breathing 100% O2, we use A-a PO2 difference to aid the diagnosis of V/Q mismatch resulting from pulmonary atelectasis

Answer 30

TRUE

Question 31

What are some additional causes of hypoxemia?

Answer 31

• Anemia
• Presence of pathological Hb species
  
  • Methemoglobinemia
  • Carboxihemoglobinemia
• PaO2 may be normal in these situations

Question 32

What is hypoxia? What are some causes?

Answer 32

• Insufficient oxygenation of tissues
• Causes
  
  • Hypoxemia
  • Insufficient tissue perfusion by blood
  • Insufficient uptake of O2 at celluar level
    
    • Cyanide poisoning
    • Left shift of the O2/Hb dissociation curve

Question 33

How much O2 is in the blood?

Answer 33

• CaO2: O2 content of the arterial blood
• CaO2 = Hb bound + dissolved in plasma
• CaO2 on air = 19.8 ml/dl
• CaO2 on 100% O2 = 21 ml/dl

Question 34

What are some pitfalls for arterial samples?

Answer 34

• Use small, sharp needles
• May use any artery
• Collect sample anaerobically
• Measure immediately or put on ice and measure w/in 2 hrs
• Use lithium heparin (not Na)
• Limiting dilution of blood samples with heparin to < 4%