The big idea: A cell membrane is selectively (partially) permeable: it lets some substances cross but not others.
Small, non-polar molecules (like oxygen) slip through easily; large molecules (like starch or proteins) cannot pass through the bilayer at all.
To study this, scientists use a model — dialysis (Visking) tubing behaves like a partially permeable membrane.
Large materials that can't cross the bilayer are moved in or out in bulk by vesicles — this is bulk transport (endocytosis and exocytosis).
- Selective (partial) permeability
- A property of a membrane that allows some substances to pass through while blocking others, depending mainly on their size and chemical nature.
- Dialysis (Visking) tubing
- An artificial partially permeable membrane used to model a cell membrane: it has tiny pores that let small molecules through but hold back large ones.
- Model
- A simplified, controllable stand-in for a real system, used to test ideas safely — here, tubing standing in for a living membrane.
- Bulk transport
- Moving large amounts of material, or particles too big to cross the bilayer, into or out of the cell using membrane-bound vesicles. It requires ATP.
- Endocytosis
- Bulk transport that brings material INTO the cell: the membrane folds inwards and pinches off a vesicle around the material.
- Exocytosis
- Bulk transport that releases material OUT of the cell: a vesicle fuses with the plasma membrane and empties its contents.
Why 'selective' matters: If the membrane let everything through, the cell could not control its internal conditions.
Selective permeability is what lets a cell keep what it needs and exclude what it doesn't — the basis of every transport process in this topic.
Whether a particle crosses the membrane comes down to two things: its size and whether it is polar.
Small, non-polar molecules dissolve into the bilayer and pass straight through. Ions and small polar molecules need a protein to help them. Large molecules cannot cross the bilayer at all — so the cell must move them another way.
What gets through, and what doesn't: Through the bilayer freely: small, non-polar molecules such as oxygen and carbon dioxide (and, with aquaporins, water).
Only with a protein: ions and small polar molecules such as glucose (facilitated diffusion or active transport).
Not at all through the bilayer: large molecules such as starch and proteins — these are simply too big.
| Type of particle | Can it cross the membrane easily? | How it crosses (if it can) |
|---|---|---|
| Small, non-polar (e.g. O₂, CO₂) | Yes — freely | Simple diffusion straight through the bilayer |
| Water | Yes | Osmosis, helped by aquaporin channel proteins |
| Small ions and polar molecules (e.g. glucose) | Only with help | Facilitated diffusion or active transport through proteins |
| Large molecules (e.g. starch, proteins) | No — too big | Only by bulk transport (vesicles), not through the bilayer |
Modelling a membrane with dialysis tubing: Because real membranes are hard to study, biologists use a model.
Dialysis (Visking) tubing is an artificial partially permeable membrane: its pores let small molecules (like glucose) pass through, but hold back large ones (like starch).
Fill the tubing with a glucose-and-starch mixture, sit it in water, and after a while you find glucose has moved out into the water while starch has stayed inside — exactly what a selectively permeable membrane should do.
| In the dialysis-tubing model | What it represents in the body | Why |
|---|---|---|
| The dialysis tubing | The partially permeable cell / intestinal membrane | It has tiny pores that let only small molecules through |
| Glucose passing through the tubing | Small digested products being absorbed | Glucose is small enough to cross the selective barrier |
| Starch staying inside the tubing | Undigested large molecules NOT being absorbed | Starch is too large to pass through the pores |
| Water in the beaker outside | Blood / tissue fluid receiving the absorbed glucose | It is where the small molecules end up |
Bulk transport — vesicles for big cargo: Large materials that can never cross the bilayer are moved in packages called vesicles.
Endocytosis brings material in: the membrane folds inwards around the material and pinches off a vesicle.
Exocytosis sends material out: a vesicle fuses with the plasma membrane and releases its contents.
Both use ATP, so bulk transport is an active process — the cell spends energy to move the cargo.
Endocytosis
- Brings material INTO the cell
- Membrane folds inwards and pinches off a vesicle
- Takes in large food particles, pathogens, fluids
- Uses ATP (active)
Exocytosis
- Releases material OUT of the cell
- A vesicle fuses with the plasma membrane
- Secretes proteins, enzymes, hormones, wastes
- Uses ATP (active)
A memory hook: Endo = into the cell (think 'enter'); exo = exit the cell.
And both are active — vesicle transport always uses ATP, just like the pumps in active transport.
Where bulk transport sits: There are four ways across the membrane: simple diffusion, facilitated diffusion, active transport and bulk transport.
Bulk transport is the only route for material that is too large to cross the bilayer, and — like active transport — it costs ATP.
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How this is tested: Membrane transport is a data-question favourite. On Paper 1B / Paper 3 you are often given a dialysis-tubing experiment and asked to predict how the concentration of a small molecule (glucose) and a large molecule (starch) change inside vs outside the tubing — then explain the result from the tubing being partially permeable.
On Paper 1A a multiple-choice question may show a diagram of endocytosis or exocytosis and ask you to identify the process and a valid cellular use for it.
Watch the data: only the small molecule moves; the large one stays put because it cannot fit through the pores.
IB-style question — reason from the dialysis-tubing data
Dialysis tubing was filled with a mixture of glucose and starch and placed in a beaker of distilled water. After 30 minutes, glucose was detected in the water outside the tubing, but starch was not. Explain how this models the selective permeability of a cell membrane. [4]
How to score all four marks
- Name the property being modelled. The tubing is partially (selectively) permeable — it lets some molecules through but not others, just like a real cell membrane.
- Explain the glucose result. Glucose molecules are small enough to pass through the pores in the tubing, so they diffuse out of the tubing into the surrounding water (down their concentration gradient).
- Explain the starch result. Starch molecules are too large to fit through the pores, so they cannot cross the tubing and stay inside.
- Link back to a real membrane. This mirrors a cell / intestinal membrane, which absorbs small digested products (glucose) but holds back large undigested molecules (starch). (Award 1 mark each: tubing is partially permeable; glucose is small so it passes out; starch is too large so it stays in; the model represents selective absorption across a real membrane.)
Final answer
The tubing is partially permeable: glucose is small enough to diffuse out through the pores, but starch is too large to pass, so it stays inside — exactly how a selectively permeable membrane lets small molecules cross while blocking large ones.
✓ Why this scores full marks: Each mark is a distinct, data-linked point: the property (partially permeable), the small molecule (glucose passes), the large molecule (starch blocked), and the link to a real membrane.
The examiner wants the result explained by molecule size, not just restated.
IB-style question — draw bulk transport
Draw a labelled diagram to show how the cell moves large materials across its membrane by bulk transport, and state one process shown. [3]
What the diagram must show
- Show a vesicle at the membrane. Draw the plasma membrane and a vesicle carrying material (the cargo) either forming from the membrane or fusing with it.
- Label the direction. Show material moving into the cell (endocytosis: membrane folds inwards) or out of the cell (exocytosis: vesicle fuses and releases its contents).
- Note the energy. Label that bulk transport uses ATP, so it is active. (Award 1 mark for a vesicle with cargo at the membrane, 1 mark for the correct direction labelled endocytosis or exocytosis, 1 mark for noting ATP is used.)
Final answer
A vesicle carrying cargo at the plasma membrane, labelled either endocytosis (membrane folds inwards to bring material in) or exocytosis (vesicle fuses to release material out), with a note that ATP is used.
The four ways substances cross the membrane. The last panel is bulk transport: vesicles move large amounts of material into the cell (endocytosis) or out of it (exocytosis), and — like active transport — it uses ATP.
Interactive diagram
Explore the labelled diagram, charts and maps for this topic in full study mode.