Lab 2

Question 1

The most important physico-chemical buffer system in all fluid compartments of the body?

Answer 1

the carbonic acid - bicarbonate system

Question 2

What forms the Vital buffer system?

Answer 2

the kidneys and the lungs.

They are continually closely interacting

Question 3

explain the Buffering capacity of the lungs:

Answer 3

the lungs can retain the CO2, or excrete it to regulate the pH acutely.
Ex: Increased H+ (reduced ECF pH): the equation will move to the left, generating extra CO2, lead to hypercapnia, which stimulate the ventilation and the lungs can eliminate the CO2.

Question 4

What is Kussmaul breathing?

Answer 4

is observed because the pulmonary capacity to excrete CO2 is huge. Normal frequency of breathing but very deep inspiration and expiration.

Question 5

Explain buffering capacity of the kidneys:

Answer 5

The kidneys can excrete or retain H+, and also effectively regenerate the HCO3- via complex tubular mechanisms - takes hours/days.
Ex: If CO2 levels within the body increase, the equation will push to the right, and produce excess H+ and HCO3-, and then H+ can be eliminated by the kidneys.

Question 6

What kind of sample is necessary for acid/base analysis?

Answer 6

anticoagulated blood (Ca-equilibrated Li-heparinised syringe).

Question 7

Why is arterial samples essential?

Answer 7

for assessment of respiratory function, but either venous or arterial samples can provide useful information on the metabolic status of the animal.

Question 8

What is the “Astrup-technique”?

Answer 8

A closed sampling method to avoid air contamination of the sample.

Question 9

What can happen in air contaminated samples?

Answer 9

• pO2 will be increased (150mmHg pO2 is in atmospheric air)
• pCO2 may be decreased (shortly after samling as CO2 evaporates into the air
• pCO2 may be increased (in case of longer storage, produced by the metabolism of blood cells)

Question 10

How should the samples be stored?

Answer 10

Not more than 5-10 min at room temp. and not more than 30 min at 0-4*C (refrigerator)

Question 11

What method is used for Acid/base analysis?

Answer 11

analyzers utilize ionselective electrodes (ISE) to measure pH and CO2. Based on the measured parameters the HCO3-, ABE and other parameters are calculated.

Question 12

What temperature are the samples analyzed at?

Answer 12

37*C

Question 13

the solubility of gases is dependent on?

Answer 13

temperature, and the measured values need to be corrected to the temperature of the patient.

Question 14

Routinely used acid-base parameters:

- pH

Answer 14

7.35-7.45

Question 15

Routinely used acid-base parameters:

- pCO2

Answer 15

40 mmHg

Question 16

Routinely used acid-base parameters:

- ABE

Answer 16

+-3.5 mmol/l

Question 17

Routinely used acid-base parameters:

- TCO2

Answer 17

23-30 mmol/l

Question 18

Routinely used acid-base parameters:

- SBE

Answer 18

+-3 mmol/l

Question 19

Evaluation of AB state:

- Step 1

Answer 19

Evaluate wheter acidosis or alkalosis is present according to the pH!

• Blood pH reference range
• pH <7.35 acidosis is decompensated
• pH >7.45 alkalosis is decompensated

Question 20

Evaluation of AB state:

- Step 2

Answer 20

Search for the cause of the observed pH alteration

• The predominant change of pCO2 refers to primary respiration
• the predominant change of HCO3- and ABE refers to primary metabolic processes

Question 21

Respiratory background of pH alterations:

Answer 21

pCO2 shows a strong shift in the same direction as the pH.

- When pCO2 is >40mmHg, more of it bounds to water and forms carbonic acid.

Question 22

Increase of pCO2 in respiration can be called?

Answer 22

A shift in “acidic” direction

Question 23

What happens in case of impaired gas exchange in the lungs?

Answer 23

the remaining high CO2 forms carbonic acid and shifts the pH to acidosis: respiratory acidosis

Question 24

What happens during hyperventilation?

Answer 24

too much CO2 is exhaled which will cause elevation of the pH: respiratory alkalosis.

Question 25

Metabolic background of pH alterations:

Answer 25

Eg: in case of lactic acid production metabolic acidosis occurs, both metabolic parameters are shifted in acidic direction.
- HCO3- being an anion decreases in acidosis and increases in alkalosis.

Question 26

Calculation of Actual base excess:

Answer 26

is a calculated parameter which was defined to aid correction of acid-base disturbances.
- when metabolic alkalosis is seen this paramter shifts from 0 to the positive range: in metabolic acidosis to negative range.

Question 27

How is compensatory effect detected:

Answer 27

the given parameter is shifted in opposite direction compared to the pH.

Question 28

What is “mixed acidosis”

Answer 28

sometimes all parameters are shifted significantly in the same direction as the pH - this is observed mostly in advanced acidosis.

Question 29

Evaluation of AB state:

- Step 3

Answer 29

Evaluate whether compensation effort is visible in the result or not!
- If either the respiratory or the metabolic parameters is shifted in the opposite directin than the pH - the compensatory effect is visible
Eg: in metabolic acidosis the lungs try ot compensate by highly effective gas exchange; very deep breath and longer gas exchange (Kussmaul breathing)

Question 30

Kussmaul breathing helps to:

Answer 30

excrete alot of CO2, so pH is acidic and CO2 changes alkaline direction.

Question 31

Metabolic acidosis

- Causes:

Answer 31

• HCO3- loss: diarrhoea, ileus, kidney tubular disturbance
• Increased acid intake: fruits, too acidic silage, overdose of acidifying drugs, Vitamin C.
• Increased acid production: increased lactic acid production, anaerobic glycolysis, frequent in anorectic, weak animals.
• In cattle grain overdose: volatile acid overproduction
• Increased ketogenesis: leading to ketosis due to relative or objective starvation or diabetes mellitus
• Decreased acid excretion: renal failure
• Ion exchange: hyperkalaemia (H/K pump!!)
• Some xenobiotic: ethylene-glycol toxicosis: metabolies are acidic molecules, leading to metabolic acidosis, and finally renal failure will worsen it.

Question 32

Metabolic acidosis

- Effects:

Answer 32

• Kussmaul-type breathing - hyperventilation
• Hypercalcaemia: increased mobilisation from bones in case of long term acidosis (TCa), and decreased binding of calcium ions to albumin (Ca2+)
• Hyperkaaemia: decreased cardiac muscle activity; sinoatrial, or atrioventricular block, bradycardia

Question 33

Metabolic acidosis

- Treatment:

Answer 33

• providing adequate ventilation

- if pH <7.2 infusion therapy involving alkaline fluid

Question 34

What is the Anion gap?

Answer 34

a useful parameter when attempting to determine the cause of metabolic acidosis. The anion gap describes the difference between the commonly measured cations in plasma, and the commonly measured anions.

Question 35

reference range for anion gap:

Answer 35

8-19 mmol/l

Question 36

Metabolic alkalosis

- Causes:

Answer 36

• Increased alkaline intake: overdose of bicarbonates, or feeding rotten food
• increased ruminal alkaline production: high protein intake, low carbohydrate intake, anorexia, hypomotility
• Decreased hepatic ammonia catabolism (liver failure
• Increased acid loss: vomitting, gastric dilatation volvulus syndrome, abomasal displacement.
• Ion exchange: hypokalaemia; due to Henle loop diuretics (H/K PUMP!!)

Question 37

Metabolic alkalosis

- Effects:

Answer 37

• Breathing depression (compensatory respiratory acidosis), low breathing rate, hypoventilateion
• Muscle weakness, hypokalaemia
• Hypocalcaemia due to increased Ca2+ binding of albumin
• Ammonia toxicosis
• Arrythmia, biphasic P, QT increased (AV conduction disorder), flat T, U wave
• Paradoxical aciduria

Question 38

Respiratory acidosis

- Causes

Answer 38

• Upper airway obstruction
• Pleural cavity disease: pleural effusion, pneumothorax
• Pulmonary disease: severe pneumonia, pulmonary oedema, diffuse lung metastasis, pulmonary thromboembolism
• depression of central control of respiration: drugs, toxins, brainstem disease
• neuromuscular depression of respiratory muscles
• muscle weakness eg muscle weakness in hypokalaemia
• cardiopulmonary arrest

Question 39

Respiratory acidosis

- effects:

Answer 39

• Dyspnoea, cyanosis, suffocation, muscle weakness, tiredness

Question 40

Respiratory acidosis

- treatment:

Answer 40

• assist the ventilation, providing fresh air r oxygen therapy
• treatment of the cause: e.g diuretic treatment; in case of fluid accumulation in the lungs, pulmonary oedema; specific cardiologic treatment; in case of underlying cardiac disaease; treatment of pneumonia, removal of luid from pleural space
• mildly anxiolytic/sedating drugs to decrease the fear and excitement of animals caused by hypoxia

Question 41

Respiratory alkalosis

- Causes:

Answer 41

• Increased loss of CO2: hyperventilation, excitation, forced ventilation (anasthesia), epiletiform seizures, fever, hyperthermia, interstitial lung disease.

Question 42

Respiratory alkalosis

- effects:

Answer 42

• Hyperoxia, increased pCO2: pO2 ratio, may lead to apnoea

- increased elimination of HCO3- by the kidneys

Question 43

Respiratory alkalosis

- treatment:

Answer 43

• anxiolytic or mild sedative drugs in case of hyperexcitation. it is important to increase the pCO2 level by closing nose or nostrils, pulling paper sack on the nose until breathing normalizes

Question 44

Indication/goal of Blood gas analysis?

Answer 44

is performed to assess effectiveness of gas-exchange i.e ventilation in the lungs e.g during dyspnoea or anasthesia

Question 45

Sample used for Blood gas analysis?

Answer 45

• Arterial samples: precise assessment of respiratory function, i.e how effective the gas exchange in the alveoli is.
• Venous: reflects gross changes only and gives information about how much oxygen is consumed by the body.

Question 46

Sampling used for Blood gas analysis?

Answer 46

• Anticoagulated blood

- Ca-equilibrated Li-heparinised plasma, preheparinised syringe

Question 47

Why must the Astrup Technique be used?

Answer 47

because transferring blood to a tube will alter the partial pressure of gases, therefore a closed sampling method should be used.
- the sample must be stored with no air/vacuum space, because the CO2 can evaporate and air contamination causes false increased p=2 pressure.

Question 48

How to measure Blood gas analysis?

Answer 48

within 15 minutes, or placed on ice, to minimize changes in blood gas partial pressure as a result of continued metabolism.

Question 49

Method of analyzing Blood gas?

Answer 49

The blood gas anaylzers directly measure the pCO2 and pO2 with ion specific electrodes. The samples are analyzed on standaridized temperature 37*C.

Question 50

Parameters and reference range:

- paO2

Answer 50

88-118 mmHg

Question 51

Parameters and reference range:

- paCO2

Answer 51

35-45 mmHg

Question 52

Parameters and reference range:

- SAT or SatO2

Answer 52

Venous: 75-80&
Arterial: 90-100%

Question 53

Parameters and reference range:

- FiO2

Answer 53

Room air: 0.209 (20.9%)
O2 enriched: 0.21-1.0
>0.5 risk of O2 toxicity

Question 54

What are the most important parameters to assess the fas exchange capacity of the animals?

Answer 54

paO2 and paCO2
- Following conclusions can be frawn for the overall effectiveness: normoventilation, hypoventilation or hyperventilation

Question 55

Normal arterial oxygen pressure (paO2) at room air:

Answer 55

80-110 mmHg

The saturation is around 97-100%

Question 56

When is cyanosis detectable?

Answer 56

Under 40-50 mmHg

Question 57

What is higher, pvCO2 or paCO2?

Answer 57

Normal pvCO2 is higher than paCO2

Question 58

Hypoventilation is when paCO2 is?

Answer 58

> 45 mmHg

Question 59

Hypoxaemia depends on?

Answer 59

the degree of hypercapnia and the FiO2

Question 60

Hypoventilation

- Causes:

Answer 60

• upper airway obstruction
• pleural effusion
• drugs or disorder affecting central control of respiration e.g: general anasthesia
• neuromuscular disease, which affects on respiratory system, also muscle weakness e.g: hypokalaemia
• overcompensation of metabolic alkalosis

Question 61

Hypoventilation

- Effects, signs:

Answer 61

Dyspnoea, cyanosis

Question 62

Hypoventilation

- Treatment

Answer 62

• assisting the ventilation e.g: oxygen therapy
• diuretic treatment: in case of fluid accumulation in the lungs, pulmonary oedema; or in the thoracic cavity
• mildly anxiolytic/sedating treatment

Question 63

What is VA/Q?

Answer 63

Additional to hypoventilation arterial blood gas tensions are also influenced by Ventilation-Perfusion Mismatch(VA/Q)

• normal ventilation with inadequate perfusion (insufficient blood passing the alveoli for oxygen)
• inadequate ventilation with normal perfusion (pulmonary capillary blood reaches the alveoli adequate quantities, but ventilation those alveoli has been insufficient to allow enough oxygen

Question 64

Hyperventilation is when paCO2 is?

Answer 64

< 35mmHg

Question 65

Hyperoxaemia usually present together with?

Answer 65

increased SAT

Question 66

Hyperventilation

- Causes:

Answer 66

• iatrogen: forced ventilation during anaesthesia (also high FiO2)
• seizures, epilepsy
• excitation (mild frequently visiting the vet, extreme e.g shock after accident)

Question 67

Oxygen saturation in venous blood informs about?

Answer 67

tissue O2 usage and venous SAT below 60% indicates that the body is in lack of oxygen, and ischemic disease occur.

Question 68

The “acid-base” or “blood-gas” analyzers include ion specific electrodes for:

Answer 68

pH, CO2, HCO3- and also ions: Ca2+, Na+, K+, Cl-.
When we interpret the result given by the analyzer we have to interpret all three evaluations: acid-base parameters, blood gas analysis and ionogram!