Respiratory Acidosis and Alkalosis

Question 1

what is the normal arterial range for Pao2 and PaCO2

Answer 1

PaO2 is 10-13.5kPa

PaCO2 is 4.7-6.0 kPa

Question 2

what is the normal alveolar range for PaO2 and PaCO2

Answer 2

PaO2 - 14 kPa

PaCo2 - 4.8kPa

Question 3

when is acidosis produced

Answer 3

• Acidosis is present when the cell and/or tissue pH is less than 7.35

Question 4

what produces respiratory acidosis

Answer 4

• there is a build up of carbon dioxide in the blood and this produces a shift in the body pH balance
• the blood becomes more acidic and decreases in pH

Question 5

what can cause hypercapnia

Answer 5

Alveolar hypoventilation leads to an increased PaCO2 (called hypercapnia). The increase in PaCO2 in turn causes a decrease in blood pH.

Question 6

what can cause respiratory acidosis

Answer 6

• Hypoventilation due to drugs that suppress breathing (including powerful pain medicines, such as narcotics, and “downers,” such as benzodiazepines), especially when combined with alcohol, not breathing of enough CO2 off
• Diseases of the airways (such as asthma and chronic obstructive lung disease)
• Diseases of the chest (such as scoliosis), which make the lungs less efficient at filling and emptying
• Diseases affecting the nerves and muscles that drive the lungs to inflate or deflate
• Severe obesity, which restricts how much the lungs can expand

Question 7

what is the ratio that controls pH

Answer 7

[HCO3-]/pCO2

Question 8

what is the Henderson hasselbach equation

Answer 8

pH = 6.1 + log([HCO3-]/0.03xpCO2)

Question 9

what has to be higher or lower to cause alkalosis

Answer 9

Thus: if HCO3- higher than reference and/or pCO2 lower than reference then pH high = alkalosis.

Question 10

what has to be higher or lower to cause acidosis

Answer 10

Similarly if HCO3- lower than reference and/or pCO2 higher than reference then pH low = acidosis.

Question 11

what will someone with respiratory acidosis have in terms of the Henderson hasselbach equation

Answer 11

• They will have a high Paco2 (E.G. greater than 5.3kPa) and slightly raised [HCO3-] (eg >26 mmol). This means the ratio of [HCO3-]/pCO2 decreases and thus pH also decreases.

Question 12

what is the normal pH range

Answer 12

7.35-7.45

Question 13

what raises to compensate respiratory acidosis

Answer 13

carbon dioxide is increased a lot and bicarbonate therefore rises a little in order to compensate

Question 14

where do the signs for respiratory acidosis often appear in

Answer 14

• main signs are in the brain
• this is because CO2 is a a lipid soluble gas and rapidly diffuses across the blood-brain barrier.
• Also because the CSF has little protein it is much less buffered than blood and thus changes pH faster in response to elevated pCO2.

Question 15

what are the symptoms and signs of respiratory acidosis primarily due to

Answer 15

• Symptoms and signs of respiratory acidosis are primarily a result of low CSF pH

Question 16

what are the symptoms of respiratory acidosis

Answer 16

Headache
drowsiness
lethargy
anxiety
sleepiness
fatigue
memory loss 
restlessness
muscle weakness

Question 17

what are the signs of respiratory acidosis

Answer 17

Slowed breathing
gait disturbance
blunted deep tendon reflexes,
disorientation, 
tremor,
 myoclonic jerks,
 papilledema, 
tachycardia ,
drop in blood pressure,
swelling of blood vessels in the eyes may also be present.

Question 18

why does a low CSF affect brain function

Answer 18

Normally the brain regulates its own local pH, shifting towards acid or alkali depending on local neuronal activity.
A global acidity of the blood disrupts this local control, and so areas of the brain may become relatively hypoxaemic or hyperoxic and this can affect local neuronal function

Question 19

how do you diagnose respiratory acidosis

Answer 19

• blood test sample to test for pH
• ABG
• the key finding would be The pCO2 in the blood will be high, usually over 5.9 kPa (45 mm Hg).

Question 20

how do you treat respiratory acidosis

Answer 20

• Bronchodilator drugs to reverse some types of airway obstruction
• Noninvasive positive-pressure ventilation (sometimes called CPAP or BiPAP) or mechanical ventilation if needed
• Oxygen if the blood oxygen level is low
• Treatment to stop smoking

the treatment is aimed at the underlying lung disease

Question 21

what is hyperkalamia

Answer 21

loss of potassium from cells and low pH may effect the distribution of the potassium, can cause atrial flutter

Question 22

what are the types of respiratory acidosis

Answer 22

acute

chronic

Question 23

what is the PaCO2 and pH in acute respiratory acidosis

Answer 23

• In acute respiratory acidosis, the PaCO2 is elevated above 6.3 kPa (47 mm Hg) with an accompanying acidemia (blood pH <7.35).

Question 24

when does acute respiratory acidosis occur

Answer 24

• Acute respiratory acidosis occurs when an abrupt failure of ventilation occurs

Question 25

what can cause acute respiratory acidosis

Answer 25

• This failure in ventilation may be caused by depression of the central respiratory center by cerebral disease or drugs,
• inability to ventilate adequately due to neuromuscular disease (e.g., myasthenia gravis, amyotrophic lateral sclerosis, Guillain-Barré syndrome, muscular dystrophy),
• airway obstruction related to asthma or chronic obstructive pulmonary disease (COPD) exacerbation.

Question 26

what is the PaCO2 and pH like in chronic respiratory acidosis

Answer 26

• In chronic respiratory acidosis, the PaCO2 is elevated above 6.3 kPa (47 mm Hg), But the blood pH is normal or near normal.

Question 27

what is the pH near normal in chronic respiratory acidosis

Answer 27

• This is because renal (metabolic) compensation is occurring and has produced a highly elevated serum bicarbonate (HCO3− >30 mm Hg). The high bicarbonate restores the pH to near normal.

Question 28

why does chronic respiratory acidosis occur

Answer 28

• Chronic respiratory acidosis may be secondary to many disorders, including COPD.
• Chronic respiratory acidosis also may be secondary to obesity hypoventilation syndrome, neuromuscular disorders such as amyotrophic lateral sclerosis, and severe restrictive ventilatory defects as observed in interstitial fibrosis and thoracic deformities.

Question 29

how does COPD cause chronic respiratory acidosis

Answer 29

• Hypoventilation in COPD involves multiple mechanisms, including decreased responsiveness to hypoxia and hypercapnia, increased ventilation-perfusion mismatch leading to increased dead space ventilation, and decreased diaphragm function secondary to fatigue and hyperinflation.

Question 30

how does metabolic compensation for respiratory acidosis work

Answer 30

• After a few days of respiratory acidosis the high blood [H+] stimulates the kidney to retain bicarbonate.
• A high plasma bicarbonate compensates for the high paCO2 and brings the ratio of bicarbonate to pCO2 back to near normal. This raises the pH back towards normal

Question 31

what is the compensation of the metabolic system for respiratory acidosis called

Answer 31

• This increased bicarbonate retention is sometimes called a compensating metabolic alkalosis

Question 32

what I the maximum level of bicarbonate plasma that can be reached for compensating metabolic alkalosis

Answer 32

• Maximum level of plasma HCO3 that can be reached in this way is 45 mmol/L

Question 33

what is respiratory alkalosis

Answer 33

• Respiratory alkalosis is a condition where the amount of carbon dioxide found in the blood drops to a level below normal range. This condition produces a shift in the body’s pH balance and causes the body’s system to become more alkaline

Question 34

what can cause respiratory alkalosis

Answer 34

hyperventilation
- hyperventiation can occur due to anxiety

• Intracerebral hemorrhage, meningitis, stroke (altered respiratory drive)
• Salicylate and Progesterone drug usage
• Anxiety, hysteria, stress and pain
• Cirrhosis of the liver
• Sepsis
• Elevated body temperature
• Hypoxia

Question 35

why does hyperventilation cause respiratory alkalosis

Answer 35

• The increased breathing produces increased alveolar respiration, expelling CO2 from the circulation. This reduces the level of carbon dioxide in the circulatory system, and the system reacts according to the Law of mass action.
• Hydrogen ions and bicarbonate in the plasma react (via the enzyme carbonic anhydrase) to make more CO2 .The net result of this is decreased circulating hydrogen ion concentration, and thus increased pH (alkalosis

Question 36

what are the signs and symptoms of respriatory alkalosis

Answer 36

• hyperventilation is the primary symptom
• dizziness,
• light headedness,
• agitation,
• confusions,
• cramps and tingling or numbing around the mouth and in the fingers and hands.
• Muscle twitching, hyperpnea, chest pain, blurred vision, spasms, and weakness may be noted. In extreme cases seizures, irregular heart beats, and tetany can also result.

Question 37

what are acidosis symptoms mainly associated with

Answer 37

Acidosis symptoms mainly associated with fatigue: eg drowsiness, lethargy, anxiety, fatigue, etc

Question 38

what are alkalosis symptoms mainly associated with

Answer 38

• Alkalosis symptoms mainly associated with overactivity : gait disturbance, altered deep tendon reflexes, disorientation, tremor, seizures, myoclonic jerks, etc

Question 39

what is the metabolic effects of respiratory alkalosis

Answer 39

1) The decrease in CO2 content of the blood causes constriction of cerebral blood vessels
2) Alkalaemia shifts the haemoglobin O2 dissociation curve to the left, impairing O2 delivery to the tissue.
3) pH related changes in blood Ca2+ levels can lead to an increase in neuromuscular excitability – if more calcium goes into the synapse more neurotransmitter comes out

Question 40

how does respiratory alkalosis lead to hypokalaemia

Answer 40

Respiratory alkalosis causes reduced hydrogen ion (proton) excretion by the kidney.
Some other cation has to take the place of the hydrogen
. This is often potassium, leading to increased potassium excretion and hypokalaemia.

Question 41

what are the types of respiratory alkalosis

Answer 41

• Acute

- Chronic

Question 42

describe actue respiratory alkalosis

Answer 42

Occurs rapidly. During acute respiratory alkalosis, the person may lose consciousness where the rate of ventilation will resume to normal.

Question 43

describe chronic respiratory alkalosis

Answer 43

A more long-standing condition. Generally symptomless due to metabolic compensation.

Question 44

describe how the kidney deals with chronic respiratory alkalosis

Answer 44

The kidney excretes increased bicarbonate to give a metabolic acidosis that compensates for the respiratory alkalosis. If the condition has been present for 7 days or more full compensation may occur

Question 45

what Is the minimum plasma bicarbonate level achievable in compensation for respiratory alkalosis

Answer 45

The minimum plasma [HCO3-] achievable is about 12 mmol/L

Question 46

how do you diagnose respiratory alkalosis

Answer 46

Respiratory alkalosis may be suspected based on symptoms.
A blood sample to test for pH and arterial blood gases can be used to confirm the diagnosis.
The pH will be elevated above 7.44. The paCO2 in the blood will be low, usually under 35 mmHg.

Question 47

how do you treat respiratory alkalosis

Answer 47

• have to treat the underlying condition causing it
• Hyperventilation syndrome due to anxiety may be relieved by having the patient breath into a paper bag. By rebreathing the air that was exhaled, the patient will inhale a higher amount of carbon dioxide than he or she would normally.
• Atimicrobials may be used to treat pneumonia or other infections
• If the alkalosis is related to a drug overdose, the patient may require treatment for poisoning
• If the respiratory alkalosis has triggered the body to compensate by developing metabolic acidosis, symptoms of that condition may need to be treated, as well.

Question 48

what is type one respiratory failure

Answer 48

Type 1 Hypoxic (Pa O2 <60 mm Hg/ 8kPa) with normal or low PCO2

Question 49

what is type two respiratory failure

Answer 49

Type 2 Hypercapnic (PaCO2 >50 mm Hg 6.5 kpA) with or without hypoxia

Question 50

what are the common causes of type 1 respiratory failure

Answer 50

 Ventilation/Perfusion (V/Q) mismatch
 Shunting of blood across lungs
 Poor gas exchange (alveoli filled with fluid eg in pneumonia)
 Decreased minute ventilation (MV) relative to demand
 Increased dead space ventilation (less gas to alveoli)

Question 51

what is the confusion question to do with type I respiratory failure

Answer 51

Surely If a patient is hypoventilating such that they become hypoxic , then they must be accumulating CO2 and simultaneously become hypercapnic?

Question 52

how can type I respiratory failure occur due to (Surely If a patient is hypoventilating such that they become hypoxic , then they must be accumulating CO2 and simultaneously become hypercapnic? )

Answer 52

The answer is due to the difference in diffusion of oxygen and CO2 in the lungs. CO2 diffuses out more easily than O2 diffuses in
- so carbon dioxide excretion can be maintained at near normal levels despite greatly reduced ventilation and oxygen uptake

Question 53

what is the most common cause of respiratory failure

Answer 53

type I

Question 54

what respiratory pathology can occur with or without pH alteration

Answer 54

type I respiratory failure

Question 55

name some examples of type I respiratory failure

Answer 55

pulmonary edema
pneumonia
pulmonary hemorrhage.

Question 56

what is the ventilation perfusion ratio in the lungs

Answer 56

This refers to the match between ventilation of a lobe and the blood flow through it

Question 57

describe how the ventilation perfusion ratio works

Answer 57

If a lobe becomes poorly ventilated, the capillaries and arterioles constrict, reducing blood flow.
This is a useful adaptive mechanism in a healthy lung, as it redirects blood away from poorly ventilated regions to better ventilated ones.

Question 58

how does the ventilation perfusion ratio make type I respiratory failure worse

Answer 58

If for example all bronchioles are constricted due to asthma then the downstream alveoli will be hypoxic and thus all the local capillaries will constrict.
Thus even less oxygen uptake can occur in the affected region.
If large parts of the lungs are vasoconstricted due to hypoxia,
AV shunts can open to prevent pulmonary arterial hypertension and right heart damage, but this does not help the hypoxia.

Question 59

what is the anion gap

Answer 59

The anion gap is thus the amount of unmeasured anions in plasma

• The anion gap is the difference between the concentrations of the main cation sodium* and the main anions chloride and bicarbonate in the plasma

Question 60

how do you work out the anion gap

Answer 60

[Na+] - ([Cl-] + [HCO3-]) < 11 mEq/L

Question 61

what does it mean if the anion gap is higher than normal

Answer 61

• A high anion gap normally indicates that there is a loss of plasma bicarbonate and this is due to elevated levels of anions like lactate, beta-hydroxybutyrate and acetoacetate.
• thus a high anion gap normally indicates metabolic acidosis.

Question 62

what anions can replace bicarbonate

Answer 62

e.g. lactate, beta-hydroxybutyrate and acetoacetate

Question 63

what can metabolic acidosis occur due to

Answer 63

gastrointestinal loss of bicarbonate due to vomiting/diarrhoea, or renal loss of bicarbonate due to renal damage