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RESPIRATORY REGULATION OF ACID–BASE BALANCE Lecture # 3 Page # 416 Ch: # 31 Guyton Physiology 15th Edition

  • The second line of defense against acid–base disturbances is the lungs.
  • The lungs regulate the CO₂ concentration in the extracellular fluid.
  • Increased ventilation removes more CO₂ from the extracellular fluid.
  • Removal of CO₂ decreases H⁺ concentration by mass action.
  • Decreased H⁺ concentration increases pH.
  • Decreased ventilation causes CO₂ to accumulate.
  • Increased CO₂ increases H⁺ concentration.
  • Increased H⁺ concentration decreases pH.

Easy Concept

↑ Ventilation

↓ CO₂

↓ H₂CO₃

↓ H⁺

↑ pH (Alkalosis)

↓ Ventilation

↑ CO₂

↑ H₂CO₃

↑ H⁺

↓ pH (Acidosis)

Pulmonary Expiration of CO₂ Balances Metabolic Formation of CO₂

  • CO₂ is continuously produced inside body cells.
  • CO₂ is formed during intracellular metabolism.
  • CO₂ diffuses from cells into the interstitial fluid.
  • CO₂ then diffuses into the blood.
  • Blood transports CO₂ to the lungs.
  • CO₂ diffuses from blood into the alveoli.
  • Pulmonary ventilation removes CO₂ into the atmosphere.
  • Normally, the extracellular fluid contains about 1.2 mmol/L of dissolved CO₂.
  • This corresponds to a PCO₂ of 40 mm Hg.

Mathematical Relationship

1.2 mmol/L dissolved CO₂PCO2=40 mm Hg\boxed{ 1.2\ \text{mmol/L dissolved CO₂} \Longleftrightarrow PCO_2 = 40\ \text{mm Hg} }1.2 mmol/L dissolved CO₂⟺PCO2​=40 mm Hg​

Easy Concept

Cells

Produce CO₂

Blood carries CO₂

Lungs remove CO₂

Body maintains normal PCO₂ = 40 mm Hg

  • If metabolic CO₂ production increases, extracellular PCO₂ increases.
  • If metabolic CO₂ production decreases, extracellular PCO₂ decreases.
  • Increasing pulmonary ventilation removes more CO₂ from the lungs.
  • Increased ventilation decreases extracellular PCO₂.
  • Therefore, extracellular PCO₂ depends on:
    • Pulmonary ventilation.
    • Tissue CO₂ production.

Easy Concept

More Tissue Metabolism

More CO₂

Higher PCO₂

More Ventilation

More CO₂ Removed

Lower PCO₂

Increasing Alveolar Ventilation Decreases Extracellular Fluid H⁺ Concentration and Raises pH

Figure Mentioned: Fig. 31.2

  • If metabolic CO₂ production remains constant, alveolar ventilation is the only factor that changes extracellular PCO₂.
  • Higher alveolar ventilation produces a lower PCO₂.
  • Increased CO₂ increases H₂CO₃ concentration.
  • Increased H₂CO₃ increases H⁺ concentration.
  • Increased H⁺ lowers extracellular fluid pH.

Easy Concept

↑ CO₂

↑ H₂CO₃

↑ H⁺

↓ pH

  • Fig. 31.2 shows the changes in blood pH produced by changing alveolar ventilation.
  • Increasing alveolar ventilation to 2 times normal raises extracellular fluid pH by about 0.23.

Mathematical Solution

Normal pH7.407.407.40

Increase in pH+0.23+0.23+0.23

Final pH7.40+0.23=7.637.40+0.23=7.637.40+0.23=7.63

Final Answer

pH=7.63\boxed{pH=7.63}pH=7.63​

  • Therefore, if normal pH is 7.40, doubling alveolar ventilation raises the pH to about 7.63.

Easy Concept

Ventilation ×2

CO₂ decreases

H⁺ decreases

pH increases

7.40 → 7.63

  • Decreasing alveolar ventilation to one-fourth normal lowers pH by about 0.45.

Mathematical Solution

Normal pH7.407.407.40

Decrease in pH0.45-0.45−0.45

Final pH7.400.45=6.957.40-0.45=6.957.40−0.45=6.95

Final Answer

pH=6.95\boxed{pH=6.95}pH=6.95​

  • Therefore, reducing alveolar ventilation to one-fourth normal decreases the pH from 7.40 to 6.95.

Easy Concept

Ventilation = ¼ Normal

CO₂ increases

H⁺ increases

pH decreases

7.40 → 6.95

  • Alveolar ventilation can change over a very wide range.
  • It may decrease to 0.
  • It may increase up to 15 times normal.
  • Therefore, the respiratory system can produce large changes in body fluid pH.

Easy Concept

Ventilation Range015×Normal0 \longrightarrow 15 \times \text{Normal}0⟶15×Normal

Large changes in CO₂

Large changes in H⁺

Large changes in pH

KEY CONCEPT

  • Respiratory system is the second line of defense against acid–base disorders.
  • ↑ Ventilation → ↓ CO₂ → ↓ H₂CO₃ → ↓ H⁺ → ↑ pH (Respiratory Alkalosis).
  • ↓ Ventilation → ↑ CO₂ → ↑ H₂CO₃ → ↑ H⁺ → ↓ pH (Respiratory Acidosis).
  • Normal dissolved CO₂ = 1.2 mmol/L.
  • Normal PCO₂ = 40 mm Hg.
  • Doubling ventilation: pH = 7.40 → 7.63.
  • Reducing ventilation to one-fourth: pH = 7.40 → 6.95.
  • Alveolar ventilation can vary from 0 to 15 times normal, allowing large changes in body fluid pH.

Mathematical/Biochemical Equations Solved

  1. ↑ Ventilation → ↓ CO₂ → ↓ H₂CO₃ → ↓ H⁺ → ↑ pH
  2. ↓ Ventilation → ↑ CO₂ → ↑ H₂CO₃ → ↑ H⁺ → ↓ pH
  3. Normal dissolved CO₂

1.2 mmol/LPCO2=40 mmHg\boxed{1.2\ \text{mmol/L}\Longleftrightarrow PCO_2=40\ \text{mmHg}}1.2 mmol/L⟺PCO2​=40 mmHg​

  1. Doubling ventilation

7.40+0.23=7.637.40+0.23=7.637.40+0.23=7.63

  1. Reducing ventilation to one-fourth

7.400.45=6.957.40-0.45=6.957.40−0.45=6.95

  1. Ventilation range

015×Normal0\rightarrow15\times\text{Normal}0→15×Normal

Figure 31.2: Effect of Alveolar Ventilation on Extracellular Fluid pH

  • (Figure 31.2) shows how changes in alveolar ventilation affect the pH of body fluids (extracellular fluid).

Understanding the Axes

X-Axis (Horizontal)

Rate of Alveolar Ventilation (Normal = 1)

This shows how fast a person is breathing compared with normal.

ValueMeaning
0.5Breathing at half the normal rate (Hypoventilation)
1.0Normal breathing
1.5Breathing 1.5 times faster than normal
2.0Breathing 2 times faster than normal
2.5Breathing 2.5 times faster than normal (Hyperventilation)
  • Moving to the right = Breathing faster
  • Moving to the left = Breathing slower

Y-Axis (Vertical)

pH Change in Body Fluids

This axis shows how much the extracellular fluid pH changes from the normal value.

Upper Half (Positive Values)

  • +0.1
  • +0.2
  • +0.3

These indicate that pH increases.

  • Blood becomes more alkaline (basic).

Middle Point (0)

This is the Normal pH.

  • Normal ventilation
  • Normal CO₂
  • Normal blood pH

This point is marked “Normal” on the graph.

Lower Half (Negative Values)

The graph labels them as 0.1, 0.2, 0.3, 0.4, 0.5 below zero.

These represent a decrease in pH.

  • Blood becomes more acidic.

Understanding the Red Curve

The red curve shows the relationship between:

Breathing Rate → CO₂ Level → Blood pH

Normal Point (Ventilation = 1)

At ventilation = 1

The graph passes through the Normal point.

Meaning:

  • Normal breathing
  • Normal CO₂ removal
  • Normal extracellular fluid pH

No pH change occurs.

Left Side of the Curve (Ventilation Less Than Normal)

Move left from the normal point.

Example:

Ventilation decreases from 1 → 0.5

This means:

  • Breathing becomes slower.
  • Less CO₂ is removed by the lungs.
  • CO₂ accumulates in the blood.
  • More carbonic acid (H₂CO₃) forms.
  • H⁺ concentration increases.
  • Blood pH decreases.

Result:

Blood becomes more acidic.

The graph moves downward.

Right Side of the Curve (Ventilation Greater Than Normal)

Move right from the normal point.

Example:

Ventilation increases from 1 → 2

This means:

  • Breathing becomes faster.
  • More CO₂ is removed by the lungs.
  • Blood CO₂ decreases.
  • Carbonic acid (H₂CO₃) decreases.
  • H⁺ concentration decreases.
  • Blood pH increases.

Result:

Blood becomes more alkaline (basic).

The graph moves upward.

Why is the Curve Curved Instead of a Straight Line?

Notice:

Near the normal point, the curve is steeper.

At very high ventilation, the curve becomes flatter.

This means:

  • Around normal breathing, small changes in ventilation produce noticeable changes in pH.
  • At very high ventilation rates, further increases in breathing cause only smaller additional increases in pH.

Understanding the Entire Curve

Far Left (Very Slow Breathing)

  • Very low ventilation
  • CO₂ retained
  • H₂CO₃ increases
  • H⁺ increases
  • pH falls markedly

Result: Severe acidosis.

Middle (Normal)

  • Normal ventilation
  • Normal CO₂
  • Normal H⁺
  • Normal pH

Far Right (Very Fast Breathing)

  • Very high ventilation
  • Excess CO₂ removed
  • H₂CO₃ decreases
  • H⁺ decreases
  • pH rises

Result: Alkalosis.

Easy Concept

Think of the lungs as a CO₂ remover.

If you breathe slowly

➡ CO₂ stays in the blood.

➡ More acid forms.

➡ pH falls.

If you breathe faster

➡ CO₂ leaves the blood.

➡ Less acid remains.

➡ pH rises.

One-Line Memory Trick

Slow breathing → ↑ CO₂ → ↑ H⁺ → ↓ pH → Acidosis

Fast breathing → ↓ CO₂ → ↓ H⁺ → ↑ pH → Alkalosis

KEY CONCEPT

  • Figure 31.2 shows how alveolar ventilation changes extracellular fluid pH.
  • Normal ventilation (1× normal) maintains normal blood pH.
  • Decreased ventilation (hypoventilation) causes CO₂ retention, H⁺ increases, and pH decreases (acidosis).
  • Increased ventilation (hyperventilation) causes more CO₂ removal, H⁺ decreases, and pH increases (alkalosis).
  • The lungs regulate blood pH by controlling the amount of CO₂ removed from the body.

Increased H⁺ Concentration Stimulates Alveolar Ventilation

Figure Mentioned: Fig. 31.3

  • Alveolar ventilation not only changes H⁺ concentration.
  • H⁺ concentration also controls the rate of alveolar ventilation.
  • Fig. 31.3 shows the relationship between blood pH and alveolar ventilation.
  • As pH decreases from the normal value of 7.4 to 7.0, alveolar ventilation increases 4 to 5 times normal.

Mathematical Values

Normal pH7.4\boxed{7.4}7.4​

Acidic pH7.0\boxed{7.0}7.0​

Alveolar ventilation45×Normal\boxed{4\text{–}5\times \text{Normal}}4–5×Normal​

Easy Concept

↓ pH (↑ H⁺)

Respiratory center stimulated

Alveolar ventilation increases

4–5 × Normal

  • When plasma pH rises above 7.4, alveolar ventilation decreases.

Easy Concept

↑ pH (↓ H⁺)

Respiratory center depressed

Ventilation decreases

  • The change in ventilation for each unit change in pH is much greater when pH is low.
  • The response is stronger when H⁺ concentration is high.
  • The response is weaker when pH is high.

Easy Concept

Low pH

Strong respiratory response

High pH

Weak respiratory response

  • Increased pH decreases alveolar ventilation.
  • Decreased ventilation lowers the amount of oxygen entering the blood.
  • Blood PO₂ decreases.
  • Low PO₂ stimulates ventilation.
  • Therefore, respiratory compensation for increased pH is limited.
  • Respiratory compensation is much more effective during marked decreases in pH.

Easy Concept

↑ pH

↓ Ventilation

↓ Oxygen (PO₂)

Oxygen receptors stimulated

Ventilation increases again

Compensation for alkalosis is limited

Feedback Control of H⁺ Concentration By the Respiratory System

  • Increased H⁺ concentration stimulates respiration.
  • Increased alveolar ventilation decreases H⁺ concentration.
  • Therefore, the respiratory system works as a negative feedback controller of H⁺ concentration.

Easy Concept

↑ H⁺

↑ Respiration

↑ CO₂ Removal

↓ CO₂

↓ H₂CO₃

↓ H⁺

Back to Normal

  • When H⁺ concentration rises above normal, the respiratory system is stimulated.
  • Alveolar ventilation increases.
  • Increased ventilation decreases extracellular PCO₂.
  • Lower PCO₂ decreases H⁺ concentration.
  • H⁺ concentration returns toward normal.

Easy Concept

↑ H⁺

↑ Ventilation

↓ PCO₂

↓ H⁺

Normal pH restored

  • When H⁺ concentration falls below normal, the respiratory center is depressed.
  • Alveolar ventilation decreases.
  • Decreased ventilation increases PCO₂.
  • Increased PCO₂ increases H⁺ concentration.
  • H⁺ concentration returns toward normal.

Easy Concept

↓ H⁺

↓ Ventilation

↑ PCO₂

↑ H⁺

Normal pH restored

  • Alkalosis depresses the respiratory centers.
  • The respiratory response during alkalosis is weaker.
  • The respiratory response during alkalosis is less predictable.
  • Reduced alveolar ventilation causes hypoxemia.
  • Hypoxemia activates oxygen-sensitive chemoreceptors.
  • Oxygen-sensitive chemoreceptors stimulate ventilation.
  • This limits respiratory compensation during metabolic alkalosis.

Easy Concept

Metabolic Alkalosis

↓ Ventilation

Hypoxemia

Oxygen-sensitive chemoreceptors activated

Ventilation increases

Respiratory compensation is limited

KEY CONCEPT

  • Figure Mentioned: Fig. 31.3
  • Fig. 31.3 shows that decreasing pH increases alveolar ventilation.
  • pH 7.4 → 7.0 increases ventilation to about 4–5 times normal.
  • ↑ H⁺ → ↑ Ventilation → ↓ PCO₂ → ↓ H₂CO₃ → ↓ H⁺.
  • ↓ H⁺ → ↓ Ventilation → ↑ PCO₂ → ↑ H₂CO₃ → ↑ H⁺.
  • The respiratory system acts as a negative feedback mechanism to maintain normal H⁺ concentration.
  • Respiratory compensation is stronger during acidosis than during alkalosis.
  • During alkalosis, hypoxemia stimulates oxygen-sensitive chemoreceptors, limiting the decrease in ventilation.

Mathematical/Biochemical Equations Solved

  1. Normal pH → Acidic pH

7.47.0\boxed{7.4 \rightarrow 7.0}7.4→7.0​

  1. Ventilation Response

Alveolar Ventilation=45×Normal\boxed{\text{Alveolar Ventilation}=4\text{–}5\times\text{Normal}}Alveolar Ventilation=4–5×Normal​

  1. Acidosis Feedback

H+VentilationPCO2H2CO3H+\boxed{ \uparrow H^+ \rightarrow \uparrow Ventilation \rightarrow \downarrow PCO_2 \rightarrow \downarrow H_2CO_3 \rightarrow \downarrow H^+ }↑H+→↑Ventilation→↓PCO2​→↓H2​CO3​→↓H+​

  1. Alkalosis Feedback

H+VentilationPCO2H2CO3H+\boxed{ \downarrow H^+ \rightarrow \downarrow Ventilation \rightarrow \uparrow PCO_2 \rightarrow \uparrow H_2CO_3 \rightarrow \uparrow H^+ }↓H+→↓Ventilation→↑PCO2​→↑H2​CO3​→↑H+​

  1. Respiratory Compensation During Alkalosis

VentilationPO2HypoxemiaChemoreceptor StimulationVentilation\boxed{ \downarrow Ventilation \rightarrow \downarrow PO_2 \rightarrow Hypoxemia \rightarrow Chemoreceptor\ Stimulation \rightarrow \uparrow Ventilation }↓Ventilation→↓PO2​→Hypoxemia→Chemoreceptor Stimulation→↑Ventilation​

Figure 31.3: Effect of Blood pH on the Alveolar Ventilation Rate

  • (Figure 31.3) shows how changes in arterial blood pH affect the rate of alveolar ventilation (breathing).

Understanding the Axes

X-Axis (Horizontal)

pH of Arterial Blood

This shows how acidic or alkaline the blood is.

pHMeaning
7.0Very acidic
7.1Acidic
7.2Mildly acidic
7.3Slightly acidic
7.4Normal blood pH
7.5Alkaline
7.6More alkaline
  • Moving left = Blood becomes more acidic (↑ H⁺).
  • Moving right = Blood becomes more alkaline (↓ H⁺).

Y-Axis (Vertical)

Alveolar Ventilation (Normal = 1)

This shows the breathing rate compared with normal.

ValueMeaning
1Normal breathing
22 times normal breathing
33 times normal breathing
44 times normal breathing
  • Moving up = Faster breathing.
  • Moving down = Slower breathing.

Understanding the Red Curve

The red curve shows the relationship between:

Blood pH → Breathing Rate

Left Side of the Curve (Low pH)

Look at the left end of the graph.

Blood pH is about 7.0.

This means:

  • Blood is very acidic.
  • H⁺ concentration is high.

The body responds by:

  • Increasing alveolar ventilation to about 4 times normal.

Why?

  • Faster breathing removes more CO₂.
  • Less CO₂ means less carbonic acid (H₂CO₃).
  • Less H₂CO₃ means fewer H⁺ ions.
  • Blood pH increases toward normal.

Result: Severe acidosis causes a marked increase in breathing.

Middle of the Curve

As blood pH increases from 7.1 → 7.3:

  • Blood becomes less acidic.
  • H⁺ concentration decreases.
  • The need for rapid breathing decreases.

Therefore:

  • Alveolar ventilation gradually decreases.

Normal Point (pH ≈ 7.4)

At about pH 7.4:

  • Blood pH is normal.
  • H⁺ concentration is normal.
  • Alveolar ventilation is approximately 1× normal.

This is the normal operating point.

Right Side of the Curve (High pH)

Move toward pH 7.5–7.6.

Now:

  • Blood becomes alkaline.
  • H⁺ concentration decreases.

The respiratory center receives less stimulation.

Therefore:

  • Breathing becomes slower than normal.

Less CO₂ is removed.

CO₂ begins to accumulate.

More H₂CO₃ forms.

More H⁺ is produced.

Blood pH moves back toward normal.

Why is the Curve Curved?

Notice:

The curve is very steep at low pH.

This means:

A small fall in pH causes a large increase in breathing.

As pH becomes normal or alkaline,

the curve becomes flatter.

This means:

Further increases in pH produce only small decreases in breathing.

Understanding the Diagram Above the Graph

The small diagram summarizes the body’s negative feedback response.

Step 1

↑ H⁺

Means:

Hydrogen ion concentration increases.

Blood becomes acidic.

Step 2

↑ Alveolar Ventilation

The respiratory center stimulates faster breathing.

Step 3

↓ PCO₂

More CO₂ is exhaled.

Blood CO₂ falls.

Step 4

Less CO₂ produces less carbonic acid (H₂CO₃).

Step 5

H⁺ concentration decreases.

Blood pH returns toward normal.

Meaning of the Dotted Arrow and (⊖)

The dotted arrow points from ↓ PCO₂ back toward ↑ H⁺.

The ⊖ (negative sign) represents negative feedback.

Meaning:

  • An increase in H⁺ starts the response.
  • The lungs increase ventilation.
  • CO₂ decreases.
  • H⁺ decreases.

Therefore, the original increase in H⁺ is opposed (reduced).

This is a negative feedback mechanism that stabilizes blood pH.

Easy Concept

Imagine the lungs as an automatic CO₂ exhaust fan.

When blood becomes acidic

  • H⁺ increases.
  • The fan works faster.
  • More CO₂ is blown out.
  • Acid decreases.
  • Blood pH returns toward normal.

When blood becomes alkaline

  • H⁺ decreases.
  • The fan slows down.
  • Less CO₂ is removed.
  • CO₂ builds up.
  • More H⁺ forms.
  • Blood pH falls back toward normal.

One-Line Memory Trick

↓ pH (↑ H⁺) → ↑ Breathing → ↓ CO₂ → ↓ H⁺ → pH returns toward normal

↑ pH (↓ H⁺) → ↓ Breathing → ↑ CO₂ → ↑ H⁺ → pH returns toward normal

KEY CONCEPT

  • Figure 31.3 shows the effect of arterial blood pH on alveolar ventilation.
  • Low blood pH (high H⁺) strongly stimulates alveolar ventilation.
  • High blood pH (low H⁺) reduces alveolar ventilation.
  • Increased breathing removes CO₂, reducing H₂CO₃ and H⁺, which raises blood pH.
  • Decreased breathing retains CO₂, increasing H₂CO₃ and H⁺, which lowers blood pH.
  • This is a negative feedback mechanism that helps maintain normal blood pH.

Efficiency of Respiratory Control of H⁺ Concentration

  • The respiratory system cannot completely restore H⁺ concentration to normal when the disturbance is caused outside the respiratory system.
  • Respiratory control is usually 50% to 75% effective.
  • This corresponds to a feedback gain of 1 to 3 during metabolic acidosis.

Mathematical Values

Respiratory effectiveness:50% to 75%\boxed{50\%\ \text{to}\ 75\%}50% to 75%​

Feedback gain:1 to 3\boxed{1\ \text{to}\ 3}1 to 3​

Easy Concept

Respiratory compensation

Does not correct 100%

Corrects about

50–75%

  • If acid is suddenly added to the extracellular fluid, pH decreases.
  • The pH may fall from 7.4 to 7.0.

Mathematical Solution

Initial pH7.4\boxed{7.4}7.4​

After acid is added7.0\boxed{7.0}7.0​

  • The respiratory system increases ventilation.
  • This response raises the pH to about 7.2–7.3.

Mathematical Solution

After respiratory compensation7.2 to 7.3\boxed{7.2\ \text{to}\ 7.3}7.2 to 7.3​

Easy Concept

Normal pH7.47.47.4

Acid Added

7.07.07.0

Respiratory Compensation

7.27.37.2\text{–}7.37.2–7.3

Not completely back to 7.4

  • Respiratory compensation occurs within 3 to 12 minutes.

Mathematical Values

312 minutes\boxed{3\text{–}12\ \text{minutes}}3–12 minutes​

  • Respiratory responses to metabolic alkalosis are rapid.
  • Respiratory compensation during metabolic alkalosis is limited.
  • This limitation is caused by hypoxemia due to reduced alveolar ventilation.

Easy Concept

Metabolic Alkalosis

↓ Ventilation

Hypoxemia

Compensation Limited

Buffering Power of the Respiratory System

  • Respiratory regulation acts as a physiological buffer system.
  • It responds rapidly.
  • It prevents large changes in H⁺ concentration.
  • It provides protection until the kidneys respond.
  • The kidneys respond more slowly.
  • The kidneys remove the acid–base imbalance.
  • The buffering power of the respiratory system is 1 to 2 times greater than all extracellular chemical buffers combined.

Mathematical Values

12×\boxed{1\text{–}2\times}1–2×​

Easy Concept

Respiratory Buffer

1–2 times stronger

Than all chemical buffers combined

  • The respiratory system buffers 1–2 times more acid or base than chemical buffers.

Impairment of Lung Function Can Cause Respiratory Acidosis

  • Normal respiration helps buffer changes in H⁺ concentration.
  • Abnormal respiration can also change H⁺ concentration.
  • Severe emphysema is an example of impaired lung function.
  • Impaired lungs cannot remove CO₂ effectively.
  • CO₂ accumulates in the extracellular fluid.
  • Increased CO₂ causes respiratory acidosis.

Easy Concept

Lung Disease

↓ CO₂ Removal

↑ CO₂

↑ H₂CO₃

↑ H⁺

Respiratory Acidosis

  • Lung disease also reduces the body’s ability to compensate for metabolic acidosis.
  • Normally, metabolic acidosis increases ventilation.
  • Increased ventilation lowers PCO₂.
  • In lung disease, this compensatory decrease in PCO₂ is reduced.

Easy Concept

Metabolic Acidosis

Should increase ventilation

Lung disease prevents adequate ventilation

PCO₂ remains high

Poor compensation

  • After initial chemical buffering, the kidneys become the only remaining physiological mechanism.
  • The kidneys gradually return the pH toward normal.

Easy Concept

Chemical Buffers

Respiratory Compensation Fails

Kidneys become the only long-term regulator

pH gradually returns toward normal

KEY CONCEPT

  • Respiratory compensation is 50–75% effective.
  • Feedback gain = 1–3 during metabolic acidosis.
  • Acid can lower pH from 7.4 → 7.0.
  • Respiratory compensation raises pH to about 7.2–7.3 within 3–12 minutes.
  • Respiratory compensation is limited during metabolic alkalosis because of hypoxemia.
  • The respiratory system has 1–2 times greater buffering power than all extracellular chemical buffers combined.
  • Lung diseases (e.g., emphysema) reduce CO₂ elimination.
  • CO₂ retention → ↑ H₂CO₃ → ↑ H⁺ → Respiratory acidosis.
  • When respiratory compensation is impaired, the kidneys become the main mechanism for restoring normal pH.

Mathematical/Biochemical Equations Solved

  1. Respiratory effectiveness

50%75%\boxed{50\%-75\%}50%−75%​

  1. Feedback gain

13\boxed{1-3}1−3​

  1. Respiratory compensation

7.47.07.27.37.4 \rightarrow 7.0 \rightarrow 7.2-7.37.4→7.0→7.2−7.3

  1. Time required

312 minutes\boxed{3-12\ \text{minutes}}3−12 minutes​

  1. Buffering power

12×\boxed{1-2\times}1−2×​

  1. Respiratory acidosis pathway

Lung FunctionCO2H2CO3H+Respiratory Acidosis\boxed{ \downarrow Lung\ Function \rightarrow \uparrow CO_2 \rightarrow \uparrow H_2CO_3 \rightarrow \uparrow H^+ \rightarrow Respiratory\ Acidosis }↓Lung Function→↑CO2​→↑H2​CO3​→↑H+→Respiratory Acidosis

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