Interactive resources for schools

Select an age range to seek interactive content for...

Concentration gradient

The difference in concentration between two areas

Water potential

A measure of the relative tendency of water to move from one area to another. Pure water has the highest water potential as all the water molecules are free to move. Every solution has a lower water potential than pure water as some of the molecules are associated with the solute particles.

Macromolecules

Very large molecules, often formed by the polymerisation of smaller subunits

Concentration

The amount of a substance (solute) in a solution

Amino acid

The basic building blocks of proteins. There are twenty amino acids used, in different combinations, to make every protein required by the human body.

Diffusion

The spreading out of the particles of a gas or any substance in solution down a concentration gradient

Glucose

A type of sugar: a mono saccharide with 6 carbon atoms (a hexose sugar).

Osmosis

The movement of water through a partially permeable membrane down a concentration gradient from a dilute solution (where there is a high concentration of water) to a concentrated solution (where there is a relatively low concentration of water).

Ions

Charge particles formed when an atom loses or gains electrons during the formation of ionic bonds

Passive transport across cell membranes

Everything that moves into and out of the cell has to pass through the cell membrane. Cell membranes are partially permeable. This means some substances pass through the membrane relatively easily but others cannot move through it without the input of energy from ATP. The properties of molecules affect how easily they are transported.

As a general rule:

  • Lipid soluble molecules are transported through the cell membranes more easily than water soluble molecules
  • Small molecules are transported through the membrane more easily than large molecules
  • The higher the charge on the molecule, the harder it is for it to be transported through the membrane

There are a number of different ways in which transport across partially permeable cell membranes takes place.

Membrane permeability to different types of particles
  • Diffusion: a process that takes place down a concentration gradient or electrochemical gradient from an area of relatively high concentration to an area of relatively low concentration. Cell membranes are no barrier to the diffusion of very small particles such as the gases oxygen and carbon dioxide, but charged molecules and large macromolecules cannot pass through.
  • Facilitated diffusion: diffusion that takes place down a concentration gradient through pores made by proteins that are integral to the structure of the membrane. Each channel is specific to the transport of a particular molecule or ion. These pores may be always present, or they may be gated, which means they can be open or shut depending on the environmental conditions.

    Examples of substances that move into the cell by facilitated diffusion through gated channels are sodium ions (Na+), potassium ions (K+) and chloride ions (Cl-).

    Facilitated diffusion also takes place using passive protein carrier molecules. It does not use ATP. The binding of the molecule to the carrier simply causes a change of shape which moves it through the membrane passively. Glucose and amino acids enter cells by facilitated diffusion using passive carriers.

    Facilitated diffusion
  • Osmosis: the movement of water down a water potential gradient across a partially permanent membrane. Water potential (Ψ) is a measure of the relative tendency of water to move from one area to another. Pure water has the highest water potential as all the water molecules are free to move. Every solution has a lower water potential than pure water as some of the molecules are associated with the solute particles.

The movement of water is very important in biological systems. Active transport can be used to accumulate solutes either side of a partially permeable cell membrane, changing the water potential. This results in the passive movement of water by osmosis in the required direction.

Animation showing diffusion, facilitated diffusion and osmosis across a cell membrane