Acid-Base Physiology

Question 1

What are the extremes of the pH range that is compatible with life?

Answer 1

pH 7.80 and 6.80

Question 2

What do clinical laboratories measure in arterial samples?

• venous?

Answer 2

Arterial
• pH
• Carbon Dioxide
• Oxygen

Venous
• measure total CO2 from which you can calculate Bicarbonate

Question 3

What is a normal level for total CO2 plus bicarbonate?

• How does Bicarb concentration correspond to this?

Answer 3

~25-26 meq/L

• Bicarbonate Concentration Typically 24 mEq/L

So actual CO2 is 1.0 to 1.5 mEq/L

Question 4

What pH range do you typically see in patients in most clinical scenarios?
• what hydrogen concentration does this correspond to?

Answer 4

pH = 7.1 - 7.4

[H+] = 80 at 7.1
[H+] = 40 at 7.4

Question 5

What is normal pH in a patient?
• normal pCO2
• Normal HCO3-

Answer 5

Normal pH:
7.35 - 7.45

Normal pCO2
• 36-44 mmHg (40mmHg)

Normal HCO3-
• 22 - 26 meq/L (24 meq/L)

Question 6

What is the simplified H/H equation used clinically for acidosis and alkyosis?

Answer 6

pH = 24 (CO2)/(HCO3)

Question 7

What causes Metabolic Disorders of acidosis and alkylosis?

• Respiratory?

Answer 7

Metabolic:
Changes in Bicarbonate

Respiratory:
Changes in CO2

Question 8

What is the Buffer effect?

• is this seen in metabolic or respiratory disorders?

Answer 8

Respiratory disorders have buffer effect aka:
• Increased HCO3- with acidosis
• Decreased HCO3- with alkalosis

Question 9

Where does bicarbonate manifest most of its buffering effects?

Answer 9

EXTRACELLULARLY

• Bicarb. is an extracellular Buffer

Question 10

What is the Isoydric principle?

Answer 10

It says that all buffers change in the same direction

Question 11

If bicarbonate is the main extracellular buffer then what buffers are active in the urine?
• which is the body better at regulating?

Answer 11

Phosphate and Ammonia

Body more effectively uses AMMONIA to buffer urine pH

Question 12

What does it mean if Compensatory (secondary) mechanisms ARE NOT used in acid-base disorders?

Answer 12

the Disorder is MIXED

• with both respiratory and renal aspects of buffer system messed up there is no way to compensate

Question 13

What compensatory mechanisms are used for metabolic and respiratory acidosis and alkylosis?

Answer 13

Metabolic Dysfunction = Respiratory Compensation.
• Acidosis = Hyperventilation
• Alkylosis = Hypoventilation

Respiratory Dysfunction = Metabolic Compensation in kidney
• Acidosis = HCO3- reabsorption increased
• Alkylsosis = HCO3- secretion increased

Question 14

From fastest to slowest what systems react when the H+ and HCO3- balance is thrown off?

Answer 14

Immediate:
• Extracellular Fluids
• HCO3- + H+ H2CO3 CO2 + H2O is adjusted

Minutes to Hours:
• Lungs
• BREATHING changes

2-4 Hours:
• Intracellular Fluids
• Phosphate and Protein Buffer Changes

Hours to Days:
• Kidneys
• Hyrogen ion excretion, bicarb reabsorption and Bicarbonate generation

Question 15

What are the 3 GOLDEN rules of simple acid-base disorders?

Answer 15

1) PCO2 and HCO3 always change in the same direction.
2) The secondary physiologic compensatory mechanisms must be present.
3) The compensatory mechanisms never fully correct pH.

Question 16

What is the general cause of metabolic acidosis?

• what are some things that cause increased acid?

Answer 16

General Cause: any increase in acid or loss (failed reabsorption) of bicarbonate

increased acid generation:
Lactic acidosis, Ketoacidosis, ingestion of acids (aspirin, ethylene glycol, methanol), dietary protein intake (animal source)

Question 17

What is the general cause of metabolic acidosis?

• what are some things that cause decreased bicarbonate?

Answer 17

General Cause: any increase in acid or loss (failed reabsorption) of bicarbonate

loss of bicarbonate:
Gastrointestinal
•(diarrhea, intestinal fistulas)

Renal: type 2 proximal renal tubular acidosis
• decreased acid excretion (impaired NH4+ excretion)
• Renal failure (reduced GFR) decreased ammonium excretion
• Type I (distal) renal tubular acidosis
•Type 4 renal tubular acidosis (hypoaldosteronism)

Question 18

What is the root cause of Respiratory Acidosis?
• what rapid compensation is always associated with this type of acidosis?
• how effective is this compensation?

Answer 18

Induced Hypercapnia (Decreased Alveolar Ventilation)

• Rapid Increase in Plasma Bicarbonate concentration via Buffer Mechanism
• only a limited response of ~1-2 mEq/L

Question 19

What is ultimate compensation made in Respiratory Acidosis?

• how long does this take?

Answer 19

• Increasing acid Excretion by NH4+ to GENERATE BICARB

* Takes 2-3 days

Question 20

What is the most common cause of chronic respiratory acidosis?

Answer 20

Chronic Obstructive Pulmonary Disease

Question 21

What is the Root cause of Respiratory Alkalosis?

• what are the short term and long term fixes to this problem?

Answer 21

• Reduced CO2 due to INCREASED Alveolar Ventilation

Short Term:
• Minimal Change in Buffer to lower serum Bicarb

Long Term (1-2 days):
• More Bicarb excreted
• Less NH4+ excreted

Question 22

What are some diseases that cause Respiratory Alkalosis?

Answer 22

ANYTHING that causes HYPOXIA

• Anxiety, Hysteria
• Fever
• Salicylate Intoxication
• CNS diseases (trauma, stroke, etc.)
• Congestive Heart Failure
• Hepatic Insufficiency
• Pregnant Women

Question 23

Would you expect an acute or chronic respiratory disorder to have a greater change in pH associated with it?
why?

Answer 23

Acute, because there is less time for the long term NH4+ excretion compensatory mechanism to kick in

Question 24

Are respiratory or Metabolic Disorders associated with an ion gap?

Answer 24

Metabolic disorders is where you will see ion gap

• In respiratory disorders the Cl changes equally and inversely with plasma HCO3

Question 25

T or F: Acid Base disorders cause radical changes in Plasma Sodium

Answer 25

False

Question 26

Metabolic Alkalosis
• General Cause
• Specific Causes

Answer 26

Processes that raise plasma bicarbonate concentration

Etiology: Loss of hydrogen ion from the GI tract (vomiting) or into the urine (diuretic therapy)

Excessive urinary net acid excretion (primary hyperaldosteronism)

Question 27

Differentiate between a chloride responsive and chloride resistant Alkylosis.

Answer 27

Chloride Responsive Metabolic Alkylosis is usually associated with Hypovolemic states

Chloride Responsive:
• Urine Cl less than 20 meq/l (usually less than 10 meq/l) - indcates that the kidney’s are doing what they should and excreting more HCO3- and taking up more Cl- into the serum

Chloride Resistant:
• Urine Cl greater than 20 meq/l (usually more than 50 meq/l) - indicates that you are still taking up a lot of bicarb and excreting a lot of Cl-

Question 28

Differentiate between Acute and Chronic respiratory Acidosis and Alkylosis.

Answer 28

Acute Respiratory Acidosis:
HCO3- increases 1 mEq for each 10 mm increase in PCO2

Chronic Respiratory Acidosis:
HCO3- increases 4 mEq for each 10 mm increase in PCO2

Acute Respiratory Alkalosis:
HCO3- decreases 2 mEq for each 10 mm decrease in PCO2

Chronic Respiratory Alkalosis:
HCO3- decreases 5 mEq for each 10 mm decrease in PCO2

Question 29

In what two places in the nephron can you work to correct HCO3- concentrations?

Answer 29

• Proximal Tubule

* Collecting Duct (alpha or beta intercalated cells)

Question 30

In what Acid-Base disorder do we see an ion gap?

• why does this happen/explain the mechanism of the ion gap?

Answer 30

• Strong Acid HA fully dissociates at physiologic pH (into H+ and A-)
• H+ component is removed via HCO3-
• A- is either reabsorbed or secreted
• Reabsorption happens if A- is something that the body doesn’t want to get rid of (e.g. Lactate etc.)

Absorbed anion takes the place of the normal increase in Chloride that would replace decreased HCO3- (w/ less competition in the PT

Question 31

What is the formula for Ion Gap?

• what unmeasured ions may account for this gap?

Answer 31

• Ion Gap = Na - (Cl + HCO3-)

• Protein
• PO4
• SO4
• Organic Acids

Question 32

What are some major causes of an increased ion gap?

Answer 32

• Renal Failure
• Lactic Acidosis
• Ketoacidosis
• Ingestions: Asprin, Ethylene Glycol, Methanol

Question 33

T or F: you can have metabolic acidosis without an ion gap.

Answer 33

True, this occurs in situations of Renal Tubular Acidosis, Diarrhea, and some cases of chronic renal failure

Question 34

Where is the main place that bicarbonate is filtered?

Answer 34

• Proximal Tubules

* Final Excretion of ~50-100 meq/d occurs primarily in the collecting duct

Question 35

How is phosphate excretion maintained?

• what role does phosphate play in acid-base balance of urine?

Answer 35

Urinary Excretion of Dietary Phosphate

• It is a good urinary buffer especially at low urinary pH (levels can be raised up to 40 mEq/d)

Question 36

Why is Ammonium a better buffer of urinary acid load than phosphate?

Answer 36

• It can be increased to MUCH greater amounts (300 mEq/d) if necessary
• NH4+ is also Lipid Insoluble and thus is TRAPPED in the Urinary Lumen

Question 37

What is the Urine Anion Gap?

• what is it used for?

Answer 37

Urine Anion Gap
• Indirect estimate of NH4+ excretion

Calculation:
• (Na + K) - Cl

Question 38

What values are you looking for with Urine Anion Gap?

Answer 38

Probably looking for correction of respiratory acidosis

UAG = (Na + K) - Cl

Normally POSITIVE at ~10 mEq/l, becomes more positive and possibly even negative with increased urinary NH4+ excretion

Question 39

What is the major way the Na and Cl differ when it comes to acid/base disorders?

Answer 39

Na ALWAYS remains constant

Cl CHANGES

***If you see a normal Na with messed up Cl then think about acid-base disorders