Simple diffusion: Difference between revisions

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= '''SIMPLE DIFFUSION''' =
Simple diffusion is the movement of substances from high concentration to low concentration across the [[Lipid bilayer|lipid bilayer]] without the help of intermediate.The driving force for simple diffusion is the concentration''' '''gradient, and membrane potential''' '''gradient.


Simple diffusion is the movement of substances from high conc to low conc accross the lipid  bilayer without the help of intermediate.The driving force for simple diffusion is '''CONCENTRATION '''gradient, and membrane '''POTENTIAL '''gradient.  
In order for [[Molecules|molecules]] to diffuse either in/out of the [[Cell|cell]], they have to pass through the [[Hydrophobic|hydrophobic]] core of the lipid bilayer. This is the rate-limiting step for simple diffusion, the rate is determined by the [[Hydrophobicity|hydrophobicity]] of the substrate.  


In order for molecules to diffuse either in/out of the cell, they have to pass through the hydrophobic core of the lipid bilayer. This is the rate limiting step for simple diffusion, the rate is determine by the hydropobicity of the substrate.
=== Uncharged Solute ===


<br>
For uncharged solute such as [[Oxygen|oxygen]], [[Carbon dioxide|carbon dioxide]], [[Ethanol|ethanol]], [[Glucose|glucose]] and etc.. they can move down their concentration gradient across the [[Cell membrane|cell membrane]] very easily.


#<u>'''UNCHARGED&nbsp;SOLUTE'''</u>
During [[Equilibrium|equilibrium there]] will be no net movement of solutes across the membrane.


For uncharged solute such as Oxygen, Carbon dioxide, Ethanol, Glucose and etc.. they can move down their conc gradient accross the cell membrane very easily.
To measure the flux of a certain substrate:


During [[Equilibrium|equilibrium there]] will be no net movement of solutes accross the membrane.
- [[Fick's Law|Fick's Law]]
 
To measure the&nbsp;flux of a certain substrate:
 
- Fick's Law  


J= P X (C2-C1)  
J= P X (C2-C1)  
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J= flux; P= permeability; (C2-C1)= concentration gradient.  
J= flux; P= permeability; (C2-C1)= concentration gradient.  


<br>
=== Charged Solute ===
 
&nbsp;&nbsp;&nbsp;&nbsp;2.&nbsp; <u>'''CHARGED&nbsp;SOLUTE'''</u>


For charged solute such as ions, etc.. they diffuse down the lipid bilayer very poorly. The charge that they posses, either +ve/-ve causes them to be repelled from simillar charges. Their charge also causes them to bind to water molecules thus becoming quite large.<br>For charge solute, we have to also take account that when they move down their conc gradient, they create membrane potential.  
For charged solute such as [[Ions|ions]], etc.. they diffuse down the lipid bilayer very poorly. The charge that they possess, either +ve/-ve causes them to be repelled from similar charges. Their charge also causes them to bind to water molecules thus becoming quite large.For charge solute, we have to also take account that when they move down their concentration gradient, they create membrane potential.  


[[Equilibrium|Equilibrium state]] for charged solute is when the membrane potential exactly balances the concentration gradient.  
[[Equilibrium|Equilibrium state]] for a charged solute is when the membrane potential exactly balances the concentration gradient.  


<br>To measure the membrane potential required to reach equilibrium:  
To measure the membrane potential required to reach equilibrium:  


- Nerst equation  
- [[Nerst equation|Nerst equation]]


E= (RT/ZF) ln ( (C in)/(C out) )  
E= (RT/ZF) ln ( (C in)/(C out) )  


E= membrane potential; R= Gas constant; T= Absolute temp;&nbsp;F= Faraday constant
E= membrane potential; R= Gas constant; T= Absolute temp; F= Faraday constant

Latest revision as of 20:20, 5 December 2017

Simple diffusion is the movement of substances from high concentration to low concentration across the lipid bilayer without the help of intermediate.The driving force for simple diffusion is the concentration gradient, and membrane potential gradient.

In order for molecules to diffuse either in/out of the cell, they have to pass through the hydrophobic core of the lipid bilayer. This is the rate-limiting step for simple diffusion, the rate is determined by the hydrophobicity of the substrate.

Uncharged Solute

For uncharged solute such as oxygen, carbon dioxide, ethanol, glucose and etc.. they can move down their concentration gradient across the cell membrane very easily.

During equilibrium there will be no net movement of solutes across the membrane.

To measure the flux of a certain substrate:

- Fick's Law

J= P X (C2-C1)

J= flux; P= permeability; (C2-C1)= concentration gradient.

Charged Solute

For charged solute such as ions, etc.. they diffuse down the lipid bilayer very poorly. The charge that they possess, either +ve/-ve causes them to be repelled from similar charges. Their charge also causes them to bind to water molecules thus becoming quite large.For charge solute, we have to also take account that when they move down their concentration gradient, they create membrane potential.

Equilibrium state for a charged solute is when the membrane potential exactly balances the concentration gradient.

To measure the membrane potential required to reach equilibrium:

- Nerst equation

E= (RT/ZF) ln ( (C in)/(C out) )

E= membrane potential; R= Gas constant; T= Absolute temp; F= Faraday constant

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