Acid Base Balance 2

Question 1

What can an acid or base load do if renal or respiratory function is abnormal?

Answer 1

Overwhelm the body and a change in pH occurs

Question 2

What is a decrease in pH called?

Answer 2

Acidosis

Question 3

What is an increase in pH called?

Answer 3

Alkalosis

Question 4

What do respiratory disorders affect that leads to a change in pH?

Answer 4

P_CO2

Question 5

What do renal disorders affect that leads to a change in pH?

Answer 5

[bicarbonate]

Question 6

What is respiratory acidosis?

Answer 6

pH fallen due to respiratory change, so P_CO2 must have increased:

• Results from reduced ventilation and therefore retention of CO₂

Question 7

What are some causes of respiratory acidosis?

Answer 7

• Acute
  
  • Drugs which depress the medullary respiratory centres, such as barbiturates and opiates
  • Obstruction of major airways
• Chronic
  
  • Lung disease such as bronchitis, emphysema, asthma

Question 8

What is the bodies response to respiratory acidosis?

Answer 8

The response is need to protect pH so need to increase [HCO₃^-]:

• Increase in P_CO2 will increase secretion of H and HCO₃^-
• Acid conditions stimulate renal glutaminase to get more NH₃ produced, but it takes time
• So there is generation of new HCO₃^- as well as increased reabsorption, because having generated more HCO₃^- the increase in P_CO2 will also increase the ability to reabsorb it

Question 9

The bodies response to respiratory acidosis is to increase [bicarbonate] which will protect the pH. However, what does this not correct?

Answer 9

The original disturbance that caused the increase in P_CO2 that causes respiratory acidosis

Question 10

In respiratory acidosis, what will correct the primary disturbance?

Answer 10

Restoration of normal ventilation

Question 11

When patients have lung diseases the pH can be protected by the kidneys maintaining high [bicarbonate]. When do problems arise?

Answer 11

When patients with lung disease develop renal dysfunction

Question 12

What is respiratory alkalosis due to?

Answer 12

Due to fall in P_CO2 and can only occur through increased ventilation and CO₂ blow-off

Question 13

What are some causes of respiratory alkalosis?

Answer 13

• Acute
  
  • Voluntary hyperventilation
  • Aspirin
  • First ascent to altitude
• Chronic
  
  • Long term residence at altitude
  • Decreased P_O2 to <60mmHg (8kPa) stimulates chemoreceptors to increase ventilation

Question 14

What does the body do to protect pH during respiratory alkalosis?

Answer 14

[HCO₃^-] should decrease

Question 15

What mechanism deals with alkaline conditions in the body?

Answer 15

Bicarbonate absorptive mechanism

Question 16

What is required to fix the original disturbance that causes respiratory alkalosis?

Answer 16

Restoration of normal veniltation

Question 17

How does an increase in P_CO2 impact H secretion and bicarbonate reabsorption?

Answer 17

Increased H secretion

Increased bicarbonate reabsorption

Question 18

How does a decrease in P_CO2 impact H secretion and bicarbonate reabsorption?

Answer 18

Decreased H secretion

Decreased bicarbonate reabsorption, more lost in urine

Question 19

What is metabolic acidosis due to?

Answer 19

Decrease in [bicarbonate]

Question 20

A decrease in [bicarbonate] causes respiratory acidosis. What can this be due to?

Answer 20

Increasing buffering of H or direct loss of bicarbonate

Question 21

What does the body do to protect pH during metabolic acidosis?

Answer 21

P_CO2 must be decreased

Question 22

What are some causes of metabolic acidosis?

Answer 22

• Increased H production, as in ketoacidosis of a diabetic or in lactic acidosis
• Failure to excrete the normal dietary load of H as in renal failure
• Loss of HCO₃^- as in diarrhoea
  
  • Ie failure to reabsorb HCO₃^-

Question 23

How does the body decrease P_CO2 to maintain pH during metabolic acidosis?

Answer 23

• Increase in ventilation is in depth rather than rate, reaching a maximum of 30L/min compared to normal 5-6L/min when arterial pH falls to 7

Question 24

What is the maximum degree of hyperventilating to try and maintain the pH during metabolic acidosis known as?

Answer 24

Kussmaul breathing

Question 25

What is Kussmaul breathing a sign of?

Answer 25

Renal failure or diabetic ketoacidosis

Question 26

How can ventilation change in L/min to try and maintain pH during metabolic acidosis?

Answer 26

Can reach a maximum of 30L/min compared to normal 5-6L/min

Question 27

What normally occurs to fix the orginal disturbance that caused metabolic acidosis?

Answer 27

The kidneys restore [bicarbonate] and get rid of H ions

But a problem is the source of H ions is the carbonic acid from CO₂, but the respiratory compensation lowers the P_CO2 to protect the pH

Question 28

Explain what happens when there is an increase in metabolic H within the body?

Answer 28

1. Immediate buffering in ECF and then ICF
2. Respiratory compensation within minutes
3. Renal correction of disturbances takes longer to develop the full response to increased H excretion and generate new HCO₃^- because renal glutaminase takes 4-5 days to reach maximum
   
   1. As HCO₃^- starts to increase, respiratory compensation begins to wear off until eventually get rid of all excess H
   2. So respiratory compensation delays the renal correction, but protects the pH which is much more important

Question 29

What is the explanation that explains how the kidneys are able to correct metabolic acidosis by restoring [bicarbonate] and getting rid of H ions although the source of the H ions is carbonic acid from CO₂ (which is reduced due to respiratory compensation lowering P_CO2 to protect the pH)?

Answer 29

1. Compensation for A/B disturbances are always in the same direction as initial disturbance, remember pH is defined as ratio of [HCO₃^-]/ PCO₂, however they are never quite to the same extend so pH is not restored to 7.4
2. Complete compensation would remove the drive to correct the original disturbance
3. Because of the decrease in P_CO2 the total amount of H secreted by renal tubule will be less than normal but because the plasma [HCO₃^-] and therefore filtered load of HCO₃^- is reduced to an even greater extent, a smaller fraction of total H is needed to HCO₃^- reabsorption and therefore a greater proportion is available for excretion in the form of titratable acid and NH₄⁺

Question 30

Why does renal correction of disturbances for metabolic acidosis take longer than respiratory compensation?

Answer 30

Renal glutaminase takes 4-5 days to reach maximum

Question 31

How does respiratory compensation impact renal correction of metabolic acidosis?

Answer 31

Respiratory compensation delays the renal correction, but protects the pH which is much more important

Question 32

What occurs in metabolic alkalosis?

Answer 32

[HCO₃^-] must have increased and P_CO2 will increase to protect pH

Question 33

What is the bodies response to protect pH in metabolic alkalosis?

Answer 33

Increase P_CO2

Question 34

What are some causes of metabolic alkalosis?

Answer 34

• Increase H ion loss, such as vomiting loss of gastric secretions
• Increase in renal H loss, such as due to aldosterone excess or excess liquorice ingestion
• Excess administration of HCO₃^- is unlikely to produce alkalosis in subjects with normal renal function, but may do so in renal impairment
• Massive blood transfusions can lead to metabolic alkalosis because bank blood contains citrate to prevent coagulation, which is converted to HCO₃^-
  
  • Needs at least 8 units to have this effect

Question 35

In respiratory acidosis, how is: H and pH changed, what is the initial disturbance, and what is done to compensate?

Answer 35

Question 36

In respiratory alkalosis, how is: H and pH changed, what is the initial disturbance, and what is done to compensate?

Answer 36

Question 37

In metabolic acidosis, how is: H and pH changed, what is the initial disturbance, and what is done to compensate?

Answer 37

Question 38

In metabolic alkalosis, how is: H and pH changed, what is the initial disturbance, and what is done to compensate?

Answer 38

Question 39

Changes in [bicarbonate] or P_CO2 can be the primary disturbance, or the bodies response to compensate. What does this mean clinically?

Answer 39

It is important to distinguish between cause and effect, look at the pH

Question 40

What can an increase in pH be due to in terms of [bicarbonate] and P_CO2?

Answer 40

Increased [bicarbonate]

Decreased P_CO2

Question 41

What can a decrease in pH be due to in terms of [bicarbonate] and PCO_2​?

Answer 41

Decrease in [bicarbonate]

Increase in P_CO2

Question 42

For any given P_CO2 is does the decrease in pH change between chronic and acute acidosis?

Answer 42

• Small decrease in pH in chronic respiratory acidosis than in acute
• Due to mechanisms used to raise [HCO₃^-]
  
  • NH₃ production takes 4-5 days to be fully turned on, so initially can only raise [HCO₃^-] by titratable acid so is limited. With time can use NH₃ production which has a considerable capacity to raise [HCO₃^-]
• Similar difference seen between acute and chronic respiratory alkalosis because of the delay in turning of NH₃ production, in contrast to renal compensation which need time to reach completion, respiratory compensations occur in minutes so no difference

Question 43

What are the 2 main ways of increasing [bicarbonate]?

Answer 43

1) Ammonium excretion
2) Titratable acid

Question 44

What is an example of putting acid/base balanc einto practive?

Answer 44

Example is a badly controlled diabetic in ketoacidosis:

• So has metabolic acidosis
• Also has always smoked so has chronic bronchitis cause respiratory acidosis
• And has haemorrhage so has lactic acidosis

So combined has metabolic and respiratory acidosis

Question 45

How do you manage a patient who combined has metabolic and respiratory acidosis?

Answer 45

• Release high acidity will cause hyperkalaemia as H ions are buffered intracellularly in exchange for K ions
  
  • Danger of ventricular fibrillation
• Management
  
  • Insulin (plus glucose if non-diabetic), stimulates cellular uptake of K
  • Also for hyperkalaemia, calcium resonium which exchanges Ca ions for K ion
  • Ca gluconate (IV) decreases excitability of heart, stabilises cardiac muscle cell membranes

Question 46

What must be considered about ketoacidosis management in relation to K?

Answer 46

Patient wil have hyperkalaemia as H ions are buffered intracellularly in exchange for K ions, so there is a danger of ventricular fibrillation

Question 47

As well as acid/base balancing, what else are the kidneys important for?

Answer 47

Regulating ECF volume and composition

This can cause problems when fixing one compromises another

Question 48

What is an example of something that challenges the kidneys ability to balance acids/bases and also regulate ECF volume and composiiton?

Answer 48

Consider a bad case of vomiting:

• Loss of NaCl and water causes hypovolaemia
• Loss of HCl causes metabolic alkalosis

Question 49

What is the bodies response to a bad case of vomiting?

Answer 49

The hypervolemia will stimulate aldosterone to increase distal tubule reabsorption of Na:

• Under conditions of avid Na reabsorption (and due to loss of Cl) the main ion exchanged for Na is H
• The respiratory compensation for the metabolic alkalosis ie increase in P_CO2 helps drive the H secretion and exacerbates the metabolic alkalosis by adding yet more CHO₃^- to the plasma

Shows that restoration of volume takes precedence over correction of metabolic acidosis

Question 50

Which of restoring volume and metabolic alkalosis takes precedence?

Answer 50

Restoring volume

Question 51

How does the bodies response to a case of bad vomiting exacerbate the metabolic alkalosis that the vomiting causes?

Answer 51

The bodies response to fix volume causes the loss of more H, which exacerbates the metabolic alkalosis

Question 52

Why in vomiting, although you lose acids and alkalis, why do you become alkalotic and what is this called?

Answer 52

“Contraction alkalosis”

Due to decrease in ECF volume causing an increase in aldosterone

Question 53

What is an example of a sweetie that can cause metabolic alkalosis?

Answer 53

Liquorice contains glycyrrhizic acid, which is very similar to aldosterone, so that excess ingestion can cause metabolic alkalosis

Question 54

What is the anion gap?

Answer 54

Difference between the sum of the principle cations (Na and K) and the principle anions in the plasma (Cl and HCO₃), is normally 14-18mmol/L (ie (140 +4) – (104 +24) =16mmoles/L, (due to plasma proteins))

Question 55

What is an anion?

Answer 55

Negatively charged molecule

Question 56

What are cations?

Answer 56

Positively charged ions

Question 57

What are the principle cations of the body?

Answer 57

Na⁺ and K⁺

Question 58

What are the principle anions of the body?

Question 59

What is the anion grap normally?

Answer 59

14-18mmol/L (ie (140 +4) – (104 +24) =16mmoles/L, (due to plasma proteins))

Question 60

When is it useful to measure the anion gap?

Answer 60

In metabolic acidosis:

• There are 2 patterns of metabolic acidosis in terms of anion gap
  
  • In one there is no change from normal
  • In other the anion gap increases

Question 61

What are the 2 patterns of metabolic acidosis in terms of anion gap?

Answer 61

• In one there is no change from normal
• In other the anion gap increases

Question 62

Explain how in some metabolic acidosis there is no change in anion gap from normal, whereas in others the anion gap increases?

Answer 62

If the acidosis is due to for example a loss of bicarbonate from the gut then the reduction of bicarbonate is compensated by an increase in chloride so there is no change in anion gap, however in lactic acid or diabetic acidosis the reduction in bicarbonate is made up by other anions such as lactate, acetoacetate, b-OH butyrate and so the anion gap is increased