Lecture 13: Acid/Base

Question 1

Define an acid and base.

Answer 1

Acids are molecules that release H+.

Bases are molecules that accept H+.

Question 2

Define pH.

Answer 2

Power of hydrogen, aka the amount of hydrogen ions present on a logarithmic scale.

Question 3

What is the normal range for body pH?

Answer 3

7.35-7.45

Question 4

What is the basic formula for carbonic acid to bicarb and hydrogen ions?

Answer 4

CO2 + H2O <=> H2CO3 <=> HCO3- + H+

Question 5

What is the Henderson-Hasselbalch equation used for?

Answer 5

Determining pH, given the concentration of bicarb and pCO2.

Question 6

What 3 systems are responsible for maintaining the body’s acid/base balance?

Answer 6

Chemical buffer systems, which include:
Bicarbonate buffer systems
Proteins
H+/K+ transcellular system
(Bone buffer system)

Respiratory acid/base control
Renal acid/base control

Question 7

What is the acid and base in the bicarbonate buffer system?

Answer 7

HCO3- is the base, as it can accept H+.
H2CO3 is the acid, as it contributes H+.

(Our body can readily eliminate the components that are not needed)

Question 8

What is the largest buffering system in the body?

Answer 8

Proteins.

Question 9

Why are proteins able to buffer the pH of the body?

Answer 9

They are amphoteric, aka they have binding sites for both bases and acids.

They are found in essentially all cells, but they have delayed onsets due to the transmembrane movement of an acid/base.

They can also help buffer the ECF/plasma.

Question 10

How does the H/K transcellular system work?

Answer 10

Both ions can freely move across a membrane.

Cells can exchange them for each other to maintain equilibrium.

Question 11

How does the bone buffering system work?

Answer 11

Excess H+ can be exchanged for Na and K on bone surface.

Bone breakdown releases Sodium and Calcium bicarb.

Note:
It is technically not a buffering system, as it is only active during acute acid loads and chronic acidemia.
Chronic acidemia can also cause weak bones as a result.

Question 12

How does the respiratory acid/base control work?

Answer 12

Controlling pCO2, which is in ECF.
Causes RAPID changes in pH, maximizing in 12-24 hours.
NOT AS EFFECTIVE as renal management.

Question 13

What receptors monitor our pCO2 and where are they found?

Answer 13

Chemoreceptors, which are found in the brainstem, carotids, and aorta.

Question 14

How do the lungs respond to acidemia and what is the chemical adjustment that occurs?

Answer 14

They will increase ventilation.

This decreases pCO2, which decreases the formation of carbonic acid.

Question 15

How do the lungs respond to alkalemia and what is the chemical adjustment that occurs?

Answer 15

They will decrease ventilation.

This increases pCO2, which increases the formation of carbonic acid.

Question 16

How does the renal acid/base control work?

Answer 16

Controls H+/HCO3- excretion via kidneys.

Takes several hours to days to reach full effect.
Can be sustained long-term.

Question 17

What functions do the kidneys play in renal acid/base control?

Answer 17

They excrete H+ ions freely and through making compounds like sodium phosphate or ammonia/ammonium.

They can also reabsorb HCO3- if needed.

Question 18

How do the kidneys respond to acidemia?

Answer 18

They will excrete H+ while reabsorbing HCO3-.

Question 19

How do the kidneys respond to alkalemia?

Answer 19

They will reabsorb H+ while excreting HCO3-.

Question 20

What two ions in the kidney are generally exchanged for one another?

Answer 20

H+ and K+.

Question 21

What happens to our ions in hyperkalemia?

Answer 21

We have increased K+ secretion, which means we have impaired H+ secretion. (aka we can get acidotic while in hyperkalemia)

Question 22

What happens to our ions in hypokalemia?

Answer 22

We have increased K+ reabsorption, which means we have impaired H+ reabsorption. (aka we can get alkalotic while in hypokalemia)

Question 23

What is hypochloremic alkalosis?

Answer 23

An inappropriate excess of HCO3- and loss of Cl-.

Question 24

What is hyperchloremic acidosis?

Answer 24

An inappropriate excess of Cl- and loss of HCO3-.

(Think carbonic anhydrase inhibitor)

Question 25

What are some acute conditions that can affect our acid-base balance?

Answer 25

URI/LRI (respiratory infections), V/D, AKI (acute kidney injury), malnutrition, electrolyte disorder, abnormal volume status, and substance OD.

Question 26

What are some chronic conditions that can affect our acid-base balance?

Answer 26

Liver, lung, CKD (chronic kidney disease), DM, intestines.

Question 27

What do I examine on a PE that could affect acid-base balance?

Answer 27

Respiratory Rate, lung auscultation
Edema, ascites
BP, HR, skin turgor, mucous membranes
Mental status, reflexes

Question 28

What lab tests can I order that are essential to determining acid-base balance?

Answer 28

A BMP (or CMP)

ABG (arterial blood gas):
Provides PaCO2, PaO2, HCO3-, and pH

Note:
You can also order a VBG, which gives PvCO2, SvO2 (venous O2 sat)

Question 29

Why is an ABG preferred over a VBG? When do I use a VBG?

Answer 29

VBGs require adjustments for their values, as venous pH is usually 0.02-0.05 lower and PvCO2 is higher by 3-8 mm Hg than PaCO2.
HCO3- is also 1-2 mEq/L higher.

We get VBGs usually if an ABG is unobtainable.

Question 30

What lab value is used as our approximate bicarb in a BMP?

Answer 30

Carbon dioxide.

Question 31

What is an anion gap?

Answer 31

Difference between measured cations and anions in ECF.

Question 32

How do I calculate anion gap?

Answer 32

[Na+] - ( [Cl-] + [HCO3-] )

Question 33

What is the normal anion gap range?

Answer 33

8-16

Question 34

Why do we care about anion gap, and when do we measure it?

Answer 34

It helps us determine the etiology of metabolic acidosis.

If the anion of the acid added is Cl-, we would see a normal anion gap.

If the anion of the acid added is something else, we would see an increased anion gap.

Question 35

What kind of things can cause increased anion gap?

Answer 35

Some common examples are diabetic ketoacidosis and salicyclic acid OD (aka aspirin).

Question 36

What values do I care about in an ABG for determining acid-base balance?

Answer 36

pH
pCO2
HCO3- (more accurate than a BMP)

Question 37

Why is an ABG useful in determining acid-base balance?

Answer 37

Used to work-up a patient
Determine the severity of an illness
Help guide treatment
Determine a patient’s response to treatment

Question 38

When do we order an ABG?

Answer 38

Suspected hypercapnia (increased PaCO2)
Suspected severe hypoxemia
Suspected ventilatory difficulty

Question 39

What kind of patients do we monitor with ABGs?

Answer 39

Ventilated patients
Dyspneic patients
O2 therapy

Question 40

Define acidosis and alkalosis.

Answer 40

Acidosis is a PROCESS that increases H+ by increasing PCO2 or by reducing HCO3-.

Alkalosis is a PROCESS that reduces H+ by reducing PCO2 or by increasing HCO3-.

Question 41

What does increased CO2 in the blood do to the acid/base equation?

Answer 41

Increased H+ ions.

Question 42

What are the main causes of respiratory acidosis?

Answer 42

Depression of CNS respiratory center
Lung disease
Airway obstruction and/or MSK disease
Breathing air with high CO2 content

Question 43

What are the symptoms of respiratory acidosis?

Answer 43

Neuro:
HA, CONFUSION, WEAKNESS, DROWSINESS/STUPOR, muscle twitching, tremors, paralysis, COMA

CV:
Vasodilation (warm, flushed skin)

Signs of underlying disease

Question 44

What happens to a person’s respiratory drive if they have chronic hypercapnia?

Answer 44

Their CO2 chemoreceptors started getting desensitized, so the body relies of PaO2 chemoreceptors instead. This means that the body will switch to hypoxic drive instead.

PaO2 will then become the principal ventilatory stimulus.

Question 45

Why is hypoxic drive concerning?

Answer 45

People on hypoxic drive will suffer greatly if placed on too much supplemental oxygen. They will become acidotic because they will breathe less.

Supplemental oxygen => increased PaO2 => less drive to breathe => less CO2 breathed out => respiratory acidosis.

Note:
Overzealous correction of hypoxemia with supplemental O2 requires ABG monitoring!

Question 46

What happens to our H+ ions if we have less CO2 in our blood?

Answer 46

We have less H+, so we enter alkalosis.

Question 47

What are some causes of respiratory alkalosis?

Answer 47

Excessive ventilation (pain, anxiety, mechanical ventilation, psychogenic)

Increased stimulus of CNS Respiratory center (Encephalitis, fever, salicylate toxicity, elevated blood ammonia, hypoxemia)

Question 48

What are some symptoms of respiratory alkalosis?

Answer 48

Neuro (increased excitability):
Dizziness, panic, light-headedness, TETANY, NUMBNESS/TINGLING, seizures, CHVOSTEKS/TROSSEAU signs.

CV:
Arrhythmias

Signs of underlying disease

Question 49

What are Chvostek and Trosseau signs? Cause?

Answer 49

Chvostek = twitching of facial in response to tapping of facial nerve

Trosseau = carpopedal spasm when BP cuff is inflated for 2-3 minutes

Note:
Caused by calcium binding to albumin. Usually, albumin binds to H+, but in respiratory alkalosis, there is less H+ to bind to.

Question 50

What lab test can confirm chvostek and trosseau?

Answer 50

Ionized calcium test.

Once calcium binds to albumin, it will become deionized, so ionized calcium counts would be low while BMP calcium would be normal.

Question 51

What are the 4 primary causes of metabolic acidosis?

Answer 51

Increased production or ingestion of acids.
Inability to renally excrete acid (H+)
Increased plasma Cl-
Excessive loss of HCO3- (renally or GI tract)

Question 52

Why does diarrhea cause HCO3- loss?

Answer 52

There is not enough time for the GI tract to extract the bicarb out.

Question 53

How is normal anion gap preserved during hyperchloremic metabolic acidosis?

Answer 53

Even with a loss of HCO3- via kidneys or GI, the kidneys will preserve Cl- to maintain a neutral electrical charge.

Question 54

What can caused an elevated anion gap?

Answer 54

Ingestion of an exogenous acid OR elevation of an unmeasured endogenous acid.

Exogenous would be like salicylate poisoning.
Endogenous would be like lactic acid elevation.

Question 55

What can cause a decreased anion gap?

Answer 55

Decreased anions, such as in hypoalbuminemia (albumin is negatively charged)

OR

Increased IgG/cations: multiple myeloma; elevations in Ca, K, or Mg

Question 56

What is the purpose of a delta gap?

Answer 56

It allows us to determine if a secondary, “hidden” acid-base disturbance is also present.

Question 57

How do I calculate delta gap and how do I interpret it?

Answer 57

Delta gap = anion gap - normal AG (12)
Then you add the delta gap to your HCO3-.

It should be 24.
<24 means that something else is contributing to the metabolic acidosis.

> 24 means that something else is contributing as a metabolic ALKALOSIS.

Question 58

How do I calculate modified gap and how do I interpret it?

Answer 58

It is a delta gap done without adding the bicarb.

Na + Cl -36

-6 or less = mixed high and normal AG metabolic acidosis.

-6 to 6 = only high AH metabolic acidosis.

6 or more = mixed high AG metabolic acidosis and metabolic ALKALOSIS.

Question 59

What are some common causes of increased anion gaps in metabolic acidosis?

Answer 59

Excess production of metabolic acids:
Lactic acidosis
Ketoacidosis
Poisoning

Renal failure:
Accumulation of renal wastes

Question 60

What are some common causes of a normal anion gap in metabolic acidosis?

Answer 60

HCO3- loss (renal tubular acidosis, diarrhea, carbonic anhydrase inhibitors, urinary diversion/fistula)

Inability to excrete H+ (Adrenal insufficiency or renal failure)

Excess administration of Cl (IV infusions, ammonium chloride)

Note:
Hyperchloremic metabolic acidosis causes a NORMAL anion gap! Your body is able to compensate using chloride.

Question 61

What is the acronym for high AG metabolic acidosis?

Answer 61

MUDPILES!

Methanol
Uremia
DKA
Paraldehyde and phenformin
Isoniazid
Lactic acidosis
Ethylene glycol
Salicylates

Question 62

What is the acronym for normal AG metabolic acidosis?

Answer 62

HARD UP!

Hyperalimentation (artificial supply of nutrients, aka TPN)

Acetazolamide (carbonic anhydrase inhibitor!)
Renal tubular acidosis (RTA) (loss of bicarb)
Diarrhea (loss of bicarb)
Ureteral diversion (loss of bicarb)
Pancreatic fistula

Question 63

What general things does acidosis do?

Answer 63

CNS depression!

Question 64

What are the neuro symptoms of metabolic acidosis?

Answer 64

Confusion
Weakness
Drowsiness/stupor
Coma

Question 65

What are the other non-neuro symptoms of metabolic acidosis?

Answer 65

CV:
Vasodilation (warm, flushed skin)
Cardiac arrhythmias

GI:
Abd pain
N/V and anorexia

Respiratory:
Increased depth and rate or respiration (aka Kussmaul)

Bone:
Decreased density/osteoporosis

Signs of underlying disease

Question 66

What kind of medication is metabolic acidosis resistant to?

Answer 66

Vasopressors!

Question 67

What ion in the bloodstream causes metabolic alkalosis primarily?

Answer 67

Excess bicarb.

Note:
Loss of H+ is not as significant BECAUSE our kidneys can correct it by getting rid of more bicarb. However, H+ retention comes at the cost of increasing serum potassium, which is high detrimental.

Question 68

What kind of medications in general cause impaired HCO3- excretion?

Answer 68

Drugs that cause you to vomit or pee a lot. This depletes the other electrolytes, such as Cl, K, and Na.

Note:
Cl is used to trade for bicarb, since they have the same electrical charge. Losing too much Cl means the body needs to keep bicarb to compensate for the loss of electrical charge.

Question 69

What are the common causes of metabolic alkalosis?

Answer 69

Excess amounts of bicarb/alkali substances (Sodium bicarb IV, or alkaline IV solutions)

Excessive loss of H+ (Vomiting, NG tubes, Hypokalemia, Milk-alkali syndrome)

Increased bicarb retention (loss of Cl)

Volume depletion (Diuretics)

Question 70

Why does hypokalemia cause metabolic alkalosis?

Answer 70

Because the body is low on potassium, it gets rid of H+ instead, since they are exchanged for each other. This increases the pH as we have barely any H+ ions.

Question 71

If I lose a lot of chloride, how does my kidney compensate?

Answer 71

It will retain HCO3-, which will cause us to get metabolic alkalosis.

Question 72

If I lose a lot of Na or K, how does my kidney compensate?

Answer 72

It will retain Na/K in exchange for H+, causing excess H+ LOSS, leading to metabolic alkalosis.

Question 73

What does alkalosis cause in general to neuro?

Answer 73

Increased neuronal excitability

Question 74

What are the neuro symptoms of metabolic alkalosis?

Answer 74

Dizziness
Panic
Light-headedness
Tetany
Numbness/tingling
Seizures
Chvostek/trosseau

Question 75

What are the CV symptoms of metabolic alkalosis?

Answer 75

Arrhythmias

Question 76

What does ROME stand for?

Answer 76

Respiratory
Opposites

(HIGH pH = respiratory alkalosis = LOW PaCO2)
(LOW pH = respiratory acidosis = HIGH PaCO2)

Metabolic
Equivalent

(HIGH pH = metabolic alkalosis = HIGH HCO3-)
(LOW pH = metabolic acidosis = LOW HCO3-)

Question 77

What are the two ways a mixed acid-base disorder can turn out?

Answer 77

If both go in the same direction…
You can have profound/severe/refractory alkalemia or acidemia.

If both go in OPPOSITE directions….
You can have a compensated acid-base disorder with a minimal pH change.

Question 78

Define compensation.

Answer 78

Process by which either kidneys/lungs make automatic adjustments when the other system is overwhelmed.

Question 79

If I have a primary metabolic acid-base disorder, how will my lungs compensate?

Answer 79

They will increase/decrease ventilation.

Question 80

If I have a primary respiratory acid-base disorder, how will my kidneys compensate?

Answer 80

Proximal tubule will adjust its HCO3-
Distal tubule will adjust its H+

Question 81

What is the goal of compensation?

Answer 81

Maintaining PCO2/HCO3- ratio.

Note:
Compensation NEVER overcorrects.

Question 82

What kind of disorder has acute and chronic compensation?

Answer 82

A primary respiratory disorder can have acute or chronic metabolic compensation.

Note:
Respiratory compensation is always the same.

Question 83

What is the direction of the compensatory system in response to a disorder?

Answer 83

It is always the SAME direction.

High PCO2 will be compensated by having HIGH HCO3-

Question 84

Why is metabolic compensation acute and chronic?

Answer 84

The acute response is due to cell buffering.
The chronic response is from renal adaptation.

Question 85

Given an ABG, what is the process for determining the acid-base disorder?

Answer 85

First, I would check what the pH is.

After that, I would check which HCO3- and PCO2 match up with primary metabolic or respiratory.

After I determine the primary disorder, I would check the compensation to see if it is partial or full.

Question 86

What are the special considerations I need to note when considering what acid-base disorder I am dealing with?

Answer 86

For a primary respiratory disorder, I need to also check if the metabolic compensation is acute or chronic.

For metabolic acidosis, I need to check the anion gaps and delta gaps to see if a secondary acid or base is contributing.