Acid Base Balance

Question 1

Name 4 complications with acid-base disturbance.

Answer 1

• protein structure
• neuron excitability
• potassium balance (electrochemical gradient)
• cardiac arrhythmias

Question 2

Normal pH of arterial blood =

Answer 2

7.38-7.42

Question 3

Aciodosis:

Answer 3

blood pH < 7.35

Question 4

Alkalosis:

Answer 4

blood pH > 7.45

Question 5

Name 4 sources of acid-base disturbances.

Answer 5

• respiratory acidosis
• metabolic acidosis
• respiratory alkalosis
• metabolic alkalosis

Question 6

What is respiratory acidosis?

Answer 6

increased plasma CO2

Question 7

What is the source of CO2 for respiratory alkalosis?

Answer 7

metabolism

Question 8

What is used for compensation for respiratory alkalosis?

Answer 8

ventilation

Question 9

What is metabolic acidosis?

Answer 9

decreased pH (not CO2)

Question 10

How can you get metabolic acidosis?

Answer 10

• high protein diet
• high fat diet
• heavy exercise
• severe diarrhea (loss of bicarbonate)
• renal dysfunction

Question 11

What is respiratory alkalosis?

Answer 11

decreased plasma CO2

Question 12

What is metabolic alkalosis?

Answer 12

increased pH (not CO2)

Question 13

How can you get metabolic alkalosis?

Answer 13

• excessive vomiting (H+)
• consumption
• renal dysfunction

Question 14

What is bicarbonate loading?

Answer 14

a technique that some try to use to offset changes to acidity caused by exercise

Question 15

Describe the benefits of bicarbonate loading.

Answer 15

generally, most people cannot tolerate the bicarbonate load and benefits are minimal

Question 16

What are the 3 lines of defence mechanisms against acid base disturbances?

Answer 16

• buffering of hydrogen ions
• respiratory compensation
• renal compensation

Question 17

What is the quickest defence against changes in pH? How long does it take?

Answer 17

• buffering

- seconds: limited only by time it takes to bind acid or release H+

Question 18

What is the most important ECF buffer?

Answer 18

bicarbonate

Question 19

HCO3– + H+ =

Answer 19

H2CO3

Question 20

What are ICF buffers?

Answer 20

• Proteins: Protein– + H+ = HProtein

- Phosphates: HPO42– + H+ = H2PO4–

Question 21

What is the second line of defence? How long does it take?

Answer 21

• respiratory compensation

- response is within minutes

Question 22

How does respiratory compensation regulate pH?

Answer 22

by varying ventilation

Question 23

In respiratory compensation, increased ventilation leads to …

Answer 23

decreased CO2

Question 24

In respiratory compensation, decreased ventilation leads to …

Answer 24

increased CO2

Question 25

Describe the mechanism by which decreases in plasma pH increases ventilation.

Answer 25

• dec. plasma pH (inc. acidity)
• detect and respond
• inc. ventilation
• dec. plasma P CO2
• inc. plasma pH
• neg. feedback

Question 26

What is the third defence? How long does it take?

Answer 26

• renal compensation

- hours –> days

Question 27

Renal compensation regulates:

Answer 27

• Excretion of H+ and HCO3-

- Synthesis of new HCO3-

Question 28

What are the 3 effects of increased acidity?

Answer 28

• inc. secretion of H+
• inc. reabsorption of HCO3-
• inc. synthesis of new HCO3-

Question 29

Describe renal handling of hydrogen and bicarbonate ions in the PCT.

Answer 29

bicarbonate reabsorption coupled to hydrogen

Question 30

Describe renal handling of hydrogen and bicarbonate ions in the DCT and collecting duct.

Answer 30

secretion of hydrogen ions coupled to synthesis of new bicarbonate ions

Question 31

Regulation of acids/bases by _____ usually sufficient.

Answer 31

kidneys

Question 32

Severe acidosis:

Answer 32

• Glutamine metabolism produces new HCO3-

- Secretes H+ in the form of ammonium

Question 33

What is the cause of respiratory acidosis?

Answer 33

hypoventilation

Question 34

Respiratory acidosis = ______ CO2 = _______ H+

Answer 34

• increased

- increased

Question 35

What is the compensation for respiratory acidosis?

Answer 35

• renal
• increased H+ secretion
• increased HCO3- reabsorption

Question 36

What is the cause of respiratory alkalosis?

Answer 36

hyperventilation

Question 37

Respiratory alkalosis = _____ CO2 = _____ H+

Answer 37

• decreased

- decreased

Question 38

What is the compensation for respiratory alkalosis?

Answer 38

• renal
• decreased H+ secretion
• decreased HCO3- reabsorption

Question 39

What is the compensation for metabolic acidosis?

Answer 39

respiratory and renal (unless renal problem)

Question 40

What is respiratory compensation for metabolic acidosis?

Answer 40

increased ventilation –> decreased CO2

Question 41

Acidosis ratio:

Answer 41

[HCO3–]/[CO2] < 20:1

Question 42

Alkalosis ratio:

Answer 42

[HCO3–]/[CO2] > 20:1

Question 43

______ regulate HCO3-.

Answer 43

kidneys

Question 44

______ regulate CO2.

Answer 44

lungs

Question 45

What is renal compensation for metabolic acidosis?

Answer 45

• inc. H+ secretion
• inc. HCO3- reabsorption
• inc. synthesis of new HCO3=

Question 46

What is the compensation for metabolic alkalosis?

Answer 46

respiratory and renal (unless renal problem)

Question 47

What is respiratory compensation for metabolic alkalosis?

Answer 47

dec. ventilation –> inc. CO2

Question 48

What is renal compensation for metabolic alkalosis?

Answer 48

• dec. H+ secretion
• dec. HCO3- reabsorption
• dec. synthesis of new bicarbonate

Question 49

What is RCP?

Answer 49

• respiratory compensation point

- boundary between heavy and severe intensity exercise

Question 50

What is AT/GET?

Answer 50

the anaerobic threshold where lactate production exceeds removal and CO2 increases (ventilatory threshold) to buffer lactate: increases ventilation

Question 51

What is GET?

Answer 51

the boundary between moderate and heavy intensity exercise

Question 52

What is RCP (RC)?

Answer 52

• seen when acidaemia takes over from CO2 as the stimulus for ventilation
• typically occurs between 70-84% of VO2 peak
• VE increases at a greater rate than VCO2

Question 53

The RCP graph:

Answer 53

• may be due to increased K+ in plasma and activation of peripheral chemoreceptors
• indicates a near maximal effort by the individual exercising
• critical power may occur within the same time frame (dependent on type of test)
• may be the boundary between heavy intensity and severe intensity exercise