What is the Difference Between Osmotic pressure and Oncotic pressure?
🆚 Go to Comparative Table 🆚Osmotic pressure and oncotic pressure are both forces that influence the movement of fluid across semipermeable membranes, but they have different underlying mechanisms and functions. Here are the main differences between the two:
- Osmotic pressure is the force that drives the movement of water molecules from a region of low solute concentration to a high solute concentration. It is created by the presence of largely impermeable solutes (e.g., proteins) in the solution.
- Oncotic pressure, also known as colloid osmotic pressure, is the force exerted by proteins in the blood that draws water into the blood vessels. It is a type of osmotic pressure induced by plasma proteins, notably albumin, in a blood vessel's plasma.
Both osmotic pressure and oncotic pressure play vital roles in maintaining proper fluid balance in the body and are important for diagnosing and treating various medical conditions. In summary:
- Osmotic pressure refers to the general force that drives water across semipermeable membranes, while oncotic pressure specifically refers to the osmotic pressure exerted by proteins in the blood plasma.
- The only molecules that can contribute to the osmotic pressure across the capillary wall are large molecules, such as proteins, which cannot cross the membrane.
- Osmotic pressure has been introduced as the hydraulic pressure required to prevent the flow of water through a semipermeable membrane.
- Oncotic pressure is considered a type of osmotic pressure and is often used interchangeably with colloid osmotic pressure.
Comparative Table: Osmotic pressure vs Oncotic pressure
Osmotic pressure and oncotic pressure are both related to the movement of fluids across a membrane, but they have different underlying principles and applications. Here is a table comparing the key differences between the two:
Feature | Osmotic Pressure | Oncotic Pressure |
---|---|---|
Definition | Osmotic pressure is the pressure that develops across a semipermeable membrane due to the difference in solute concentrations on either side of the membrane. | Oncotic pressure is a specific type of osmotic pressure that is exerted by proteins in the blood plasma, particularly in biological fluids such as plasma. |
Measurement | Osmotic pressure can be measured by various methods, including freezing point depression, vapor pressure, and membrane osometry. | Oncotic pressure is typically measured by colloid osmotic pressure (COP), which is the difference between the osmotic pressure of the blood and the osmotic pressure of the plasma without proteins. |
Function | Osmotic pressure prevents the movement of water across the membrane from a region of high solute concentration to a region of low solute concentration. | Oncotic pressure is the force that draws fluid into the capillaries of the circulatory system and helps in preventing the accumulation of fluid in the tissues, which can lead to edema or swelling. |
Role in Biological Systems | Osmotic pressure plays a crucial role in various biological and industrial processes, such as water absorption by plant roots and the separation of solutes in industrial processes. | Oncotic pressure is essential in maintaining the balance of fluid exchange between blood and tissue components and is an important aspect of physiology. |
In summary, osmotic pressure is the pressure that develops due to the difference in solute concentrations on either side of a membrane, while oncotic pressure is a specific type of osmotic pressure exerted by proteins in the blood plasma, particularly in biological fluids.
- Oncotic vs Hydrostatic Pressure
- Hydrostatic Pressure vs Osmotic Pressure
- Water Potential vs Osmotic Potential
- Isotonic vs Isosmotic
- Osmolality vs Osmolarity
- Diffusion vs Osmosis
- Tonicity vs Osmolarity
- Imbibition vs Osmosis
- Osmosis vs Reverse Osmosis
- Isosmotic Hyperosmotic vs Hypoosmotic
- Osmosis vs Dialysis
- Molarity vs Osmolarity
- Turgor Pressure vs Wall Pressure
- Vacuum Pressure vs Vapour Pressure
- Osmosis vs Plasmolysis
- Air Pressure vs Liquid Pressure
- Pressure vs Flow
- Osmosis vs Diffusion in Biology
- Osmosis vs Active Transport