Diffusion and Osmosis
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Transcript Diffusion and Osmosis
Diffusion and Osmosis
Chapter 3, Section 4
Of your textbook
Passive Transport
Particles
are constantly in motion, colliding
and scattering.
This motion is random.
Does
not require the cell to use ATP /
energy
The membrane is still semi-permeable, so
only certain substances can cross (in or
out) by passive transport.
Passive Transport
A concentration
gradient is
the difference in the
concentration of a substance
from one location to another
When there is a
concentration gradient, the
NET movement is DOWN
their concentration gradient from areas of higher
concentration to areas of
lower concentration
ANIMATION
Diffusion
Movement
of
molecules in a
fluid or gas
from an area of
higher
concentration to
an area of
lower
concentration
ANIMATION
Equilibrium
Diffusion
continues until
the solution is at
equilibrium (no
concentration
gradient).
Molecules still
move, but there
is no NET
movement.
Facilitated Diffusion
Some
small,
polar
molecules
cannot easily
diffuse across
a membrane.
They need the
help of
transport
proteins.
Facilitated Diffusion
The
process of diffusion being “helped” by
transport proteins is called facilitated
diffusion.
Still passive transport because molecules
are still moving down their concentration
gradient
Requires no ATP / energy
ANIMATION
Transport Proteins
In
facilitated diffusion,
transport proteins,
pierce the cell
membrane and allow
openings for
molecules to pass.
These proteins are
considered integral
proteins because they
are fully embedded in
the membrane.
Transport Proteins
There are many
types of transport
proteins.
Most only allow
certain ions or
molecules to pass.
Some are simple
channels or tunnels
and some are more
complex, shapechanging proteins.
Osmosis
The
diffusion of water across
a semipermeable membrane
is called osmosis.
In a solution, there are water
molecules and dissolved
particles (the solute).
The more dissolved particles
there are, the lower the
concentration of water
molecules.
ANIMATION
Solutions
Water
is considered the solvent.
The substance(s) dissolved in water is /
are the solute(s).
Together, solvent + solute solution.
Comparing Solutions
A solution
may be desribed as isotonic,
hypertonic or hypotonic relative to
another solution
These are comparisons; they require a
point of reference (ie, my hair is shorter…
…than it was last year).
The comparison in biology is usually to the
inside of a cell.
Isotonic
A solution is isotonic to a
cell if it has the same
concentration of dissolved
particles as the cell.
This means the water
concentration is also the
same.
Water molecules move into
and out of the cell at an
equal rate in an isotonic
solution.
The cell size remains the
same.
Hypertonic
A hypertonic solution has
a higher concentration of
dissolved particles than a
cell.
This means the water
concentration is lower than
that of the cell.
Thus, water flows out of
the cell – so, the cell will
shrivel and eventually die.
ANIMATION
Hypotonic
A hypotonic solution has a
lower concentration of
dissolved particles than a
cell.
Therefore the water
concentration is higher
than that of the cell.
Thus, water diffuses into
the cell – causing the cell
to expand and potentially
burst.
Impact on Cells
In an isotonic solution (center), water enters / exits
red blood cells at equal rates.
In a hypertonic solution (like salt water – right),
water rushes out and the cell shrivels.
In a hypotonic solution (like distilled water – left),
water rushes in and the cell swells / bursts (lysis).
Video clips:
RBC in isotonic solution
RBC in hypertonic solution
RBC in hypotonic solution
Adaptations - Plants
Plant
cells use the cell wall to prevent bursting.
At center, the plant cell is in an isotonic solution. Water
moves in / out at equal rates (no NET movement)
At left, the plant
cell is in a
hypotonic
solution.
At right, the
plant cell is in
a hypertonic
solution.
Water rushes
in, filling the
vacuole.
Water rushes
out of the
cell, draining
the vacuole.
This cell is
turgid / has
high turgor
pressure.
Video: Elodea in isotonic / hyper / hypo
This is called
plasmolysis.
Adaptations - Protists
Paramecia live in
freshwater
This makes paramecia
hypertonic to their
surroundings
Water is constantly
rushing into the
paramecium
So the paramecium uses
a contractile vacuole to
pump the water back out
(and prevent bursting)
Video: The contractile vacuole in action