2.4.11 Adaptations for Rapid Transport

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Cells and tissues involved in transport are often specialised to increase the rate of movement of molecules or ions across membranes. These adaptations optimise diffusion, facilitated diffusion, osmosis, active transport, and co-transport.

Key Adaptations for Rapid Transport:

Increased Surface Area:

Structures such as microvilli (found on epithelial cells in the small intestine) provide a large surface area to enhance the rate of transport processes like diffusion and active transport.
Example: Microvilli increase absorption of glucose and amino acids in the ileum.

Thin Exchange Surfaces:

Thin membranes or epithelial layers reduce the diffusion distance, speeding up transport.
Example: The alveoli in the lungs and capillaries have thin walls for efficient gas exchange.

Rich Blood Supply:

Dense networks of capillaries maintain a steep concentration gradient by constantly transporting absorbed substances away and delivering substances to cells.
Example: Nutrients absorbed in the ileum are transported into the bloodstream.

Concentration Gradients:

Systems maintain steep gradients for substances like oxygen, carbon dioxide, and glucose:
Ventilation in lungs maintains a gradient for oxygen and carbon dioxide.
Sodium-potassium pumps in co-transport create ion gradients for glucose uptake.

Specialised Transport Proteins:

Carrier proteins and channel proteins in the membrane ensure rapid and selective transport:
Facilitated diffusion relies on specific channel proteins for ions like Na⁺ or K⁺.
Active transport uses carrier proteins for substances like glucose.

Energy Supply:

Cells involved in active transport (e.g., epithelial cells) contain numerous mitochondria to produce ATP, which powers processes like the sodium-potassium pump.

Example: Epithelial cells in the ileum use ATP for glucose absorption.

Water Movement:

Aquaporins (specialised channel proteins) increase the rate of osmosis by allowing water to move more quickly through the membrane.
Example: Kidney cells use aquaporins for water reabsorption.

Examples of Adaptations in Different Systems:

Small Intestine:

Microvilli increase the surface area for nutrient absorption.
Rich blood supply in villi maintains concentration gradients.

Lungs:

Alveoli provide a large surface area and thin walls for rapid gas exchange.
Ventilation ensures a steep gradient for oxygen and carbon dioxide.

Root Hair Cells:

Thin extensions increase surface area for water and mineral uptake.
Active transport of ions maintains a water potential gradient for osmosis.

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Tip for Exams:

Be able to link adaptations (e.g., microvilli, mitochondria, or aquaporins) to their role in increasing the rate of transport.
Use specific examples, such as glucose absorption in the ileum or gas exchange in the lungs, to illustrate how adaptations improve transport efficiency.

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Summary:

Adaptations for rapid transport include increased surface area, thin membranes, rich blood supply, concentration gradients, and specialised proteins.
These adaptations are essential for efficient transport in systems like the small intestine, lungs, and roots.
Processes such as active transport, facilitated diffusion, and osmosis are optimised by these structural and functional features.

Adaptations for Rapid Transport Simplified Revision Notes for A-Level AQA Biology

2.4.11 Adaptations for Rapid Transport

Key Adaptations for Rapid Transport:

Examples of Adaptations in Different Systems:

Tip for Exams:

Summary:

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