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PROTEINS ARE IMPORTANT INTRACELLULAR BUFFERS- Lecture # 2 Page # 415 Ch# 31 Guyton physiology 15th Edition

  • Proteins are among the most abundant (plentiful) buffers in the body.
  • They are especially abundant inside the cells, where their concentration is very high.
  • The intracellular pH is slightly lower than the extracellular fluid (ECF) pH.
  • However, changes in intracellular pH occur approximately in proportion to changes in extracellular fluid pH.
  • There is a small diffusion of H⁺ and HCO₃⁻ across the cell membrane.
  • H⁺ and HCO₃⁻ require several hours to reach equilibrium with the extracellular fluid.
  • Exception: In red blood cells (RBCs), equilibrium occurs rapidly.
  • CO₂ diffuses rapidly through all cell membranes.
  • The movement of CO₂, H⁺, and HCO₃⁻ (elements of the bicarbonate buffer system) causes the intracellular pH to change whenever extracellular pH changes.
  • Therefore, intracellular buffer systems help prevent changes in extracellular fluid pH.
  • However, these intracellular buffer systems require several hours to become maximally effective.
  • In red blood cells, hemoglobin (Hb) is an important intracellular buffer.
  • The buffering reaction is: H⁺ + Hb ⇌ HHb
  • Reaction Explanation:
    • When H⁺ increases, hemoglobin (Hb) binds H⁺ to form HHb.
    • When H⁺ decreases, HHb releases H⁺, forming Hb again.
    • This reversible reaction helps minimize changes in pH.
  • Approximately 60% to 70% of the total chemical buffering of body fluids occurs inside the cells.
  • Mathematical Calculation:
    • Minimum intracellular buffering = 60%
    • Maximum intracellular buffering = 70%
    • Therefore, about 6 to 7 out of every 10 parts of total body fluid buffering occur inside cells.
  • Most of this intracellular buffering is produced by intracellular proteins.
  • Except for red blood cells, the slow movement of H⁺ and HCO₃⁻ through cell membranes delays the maximum buffering action of intracellular proteins.
  • Therefore, maximum buffering of extracellular acid–base disturbances by intracellular proteins may take several hours.
  • Another reason proteins are effective buffers is their high concentration inside cells.
  • In addition, the pK values of many intracellular proteins are close to the normal intracellular pH.
  • Therefore, protein buffer systems work efficiently inside cells.

KEY CONCEPT

  • Proteins are the most abundant intracellular buffers because of their high concentration inside cells.
  • Intracellular pH changes approximately in proportion to extracellular fluid pH.
  • H⁺ and HCO₃⁻ diffuse slowly across cell membranes and require several hours to reach equilibrium, except in red blood cells, where equilibrium is rapid.
  • CO₂ diffuses rapidly through all cell membranes.
  • Hemoglobin (Hb) in red blood cells is an important intracellular buffer.
  • Buffer reaction: H⁺ + Hb ⇌ HHb.
  • Approximately 60–70% (6–7 out of every 10 parts) of total body fluid chemical buffering occurs inside cells, mainly due to intracellular proteins.
  • Protein buffers are highly effective because their pK values are close to intracellular pH.

Isohydric Principle: All Buffers in a Common Solution Are in Equilibrium With the Same H⁺ Concentration

  • The buffer systems in the body do not work separately.
  • All buffer systems work together because they all involve the same H⁺ (hydrogen ion).
  • Therefore, when the H⁺ concentration changes in the extracellular fluid, all buffer systems change their balance at the same time.
  • This is called the Isohydric Principle.
  • The Isohydric Principle is represented by the following equation:

[H+]=K1×HA1A1=K2×HA2A2=K3×HA3A3[H^+] = K_1 \times \frac{HA_1}{A_1^-} = K_2 \times \frac{HA_2}{A_2^-} = K_3 \times \frac{HA_3}{A_3^-}[H+]=K1​×A1−​HA1​​=K2​×A2−​HA2​​=K3​×A3−​HA3​​

Solving the Biological Equation into the Easiest Conceptual Understanding

Step 1: Understand Each Symbol

SymbolMeaning
H⁺Hydrogen ion concentration (acidity)
K₁, K₂, K₃Dissociation constants of different acids
HA₁, HA₂, HA₃Acid form of Buffer 1, Buffer 2, Buffer 3
A₁⁻, A₂⁻, A₃⁻Base form of Buffer 1, Buffer 2, Buffer 3

Step 2: Expand the Equation

The equation actually means:

Buffer System 1

[H+]=K1×HA1A1[H^+] = K_1 \times \frac{HA_1}{A_1^-}[H+]=K1​×A1−​HA1​​

Meaning:

Hydrogen ion concentration depends on:

  • Dissociation constant (K₁)
  • Amount of acid (HA₁)
  • Amount of base (A₁⁻)

Buffer System 2

[H+]=K2×HA2A2[H^+] = K_2 \times \frac{HA_2}{A_2^-}[H+]=K2​×A2−​HA2​​

Meaning:

The same H⁺ concentration is also maintained by Buffer System 2.

Buffer System 3

[H+]=K3×HA3A3[H^+] = K_3 \times \frac{HA_3}{A_3^-}[H+]=K3​×A3−​HA3​​

Meaning:

The same H⁺ concentration is also maintained by Buffer System 3.

Step 3: What Does the Equal (=) Sign Mean?

The equal signs do not mean that:

  • K₁ = K₂ = K₃

or

  • HA₁ = HA₂ = HA₃

Instead, they mean:

Every buffer system is maintaining the same H⁺ concentration in the body fluid.

So,Same H+ is shared by all buffer systems\boxed{\text{Same } H^+ \text{ is shared by all buffer systems}}Same H+ is shared by all buffer systems​

Step 4: Easy Concept

Imagine there are three workers lifting one heavy box.

  • Worker 1 = Bicarbonate buffer
  • Worker 2 = Phosphate buffer
  • Worker 3 = Protein buffer

The box = H⁺ ions.

If the box becomes heavier (more H⁺),

➡️ All three workers immediately help together.

No worker works alone.

Similarly,

When H⁺ changes, all buffer systems adjust together.

This is the Isohydric Principle.

Step 5: What Happens if One Buffer Changes?

Suppose the bicarbonate buffer removes H⁺.

Immediately,

  • Protein buffer releases some H⁺.
  • Phosphate buffer also adjusts its H⁺.

Now,

All buffers reach a new equilibrium.

Suppose the protein buffer binds more H⁺.

Immediately,

  • Bicarbonate buffer changes.
  • Phosphate buffer changes.

Again,

All buffers become balanced together.

Step 6: Meaning of “Buffers Buffer One Another”

The buffer systems help each other.

They continuously transfer H⁺ ions between themselves.

Example:

Protein Buffer ←→ H⁺ ←→ Bicarbonate Buffer ←→ H⁺ ←→ Phosphate Buffer

Hydrogen ions move between buffer systems until all are balanced.

Step 7: Final Meaning of the Equation

The equation says:

  • Every buffer has its own acid (HA) and base (A⁻).
  • Every buffer has its own dissociation constant (K).
  • But all buffers share the same H⁺ concentration.
  • Therefore, changing one buffer automatically changes all the others.
  • K₁, K₂, and K₃ are the dissociation constants of the three different acids:
    • HA₁
    • HA₂
    • HA₃
  • A₁⁻, A₂⁻, and A₃⁻ are the base forms (free negative ions) of the three buffer systems.
  • Therefore, each buffer system has its own acid, base, and dissociation constant, but all of them are linked by the same H⁺ concentration.
  • The implication of the Isohydric Principle is that if the balance of one buffer system changes, the balance of all the other buffer systems also changes.
  • This happens because all buffer systems continuously exchange H⁺ ions with one another.
  • Therefore, the buffer systems help (buffer) one another by shifting H⁺ ions back and forth until a new equilibrium is reached.

KEY CONCEPT

  • All buffer systems work together because they share the same H⁺ concentration.
  • This concept is called the Isohydric Principle.
  • The equation: [H+]=K1×HA1A1=K2×HA2A2=K3×HA3A3[H^+] = K_1 \times \frac{HA_1}{A_1^-} = K_2 \times \frac{HA_2}{A_2^-} = K_3 \times \frac{HA_3}{A_3^-}[H+]=K1​×A1−​HA1​​=K2​×A2−​HA2​​=K3​×A3−​HA3​​ means that every buffer system maintains the same H⁺ concentration, even though each has its own acid (HA), base (A⁻), and dissociation constant (K).
  • Changing one buffer system automatically changes all the others, because they exchange H⁺ ions until equilibrium is restored.

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