Passive Transport (A) FILLED IN PDF

Summary

This document is a study guide on transport in cells. It covers different types of passive transport, like diffusion and osmosis, with diagrams and examples. It also includes practice problems.

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Transport in Cells
In order for cells to maintain homeostasis, they must have
a way of moving substances through the cell membrane.

The cell membrane controls movement of dissolved
molecules from the solution on one side of the cell
membrane to the solution on the other side.

The concentration of a solution is the amount of solute in a
liquid (solvent). HIGH concentration means LOTS of solute.
 What is concentration?
In order to measure the concentration of a solution,
you find out the mass of the solute in the solution and
divide it by the volume of solvent.
For example, if you dissolved 12 grams of salt (solute)
into 3 liters of water (solvent), the concentration would
be:

12g / 3L = 4 g/L (grams per liter!)

***There are two kinds of ways
that the cell regulates solute
concentration in cells: passive and
active transport.***
 Methods of Cell
Transport
Passive Transport Active Transport
Diffusion Protein Pumps
Facilitated Endocytosis
Diffusion Exocytosis
Osmosis
 Passive Transport: Diffusion
In diffusion, molecules move from an area of higher concentration to
an area of lower concentration without using energy

The solute particles will continue to move until equilibrium is
reached (same amount of solutes on both sides of the membrane).
 Diffusion Through Cell Boundaries
Solutes always move DOWN their concentration gradient (from high to low
concentration). Even solutes want some space for themselves!

There is a higher Solute move from high When equilibrium is
concentration of concentration to low reached, solute
solute on one side of concentration (HIGH particles continue to
the membrane as LOW). The solute will diffuse across the
compared to the other continue to diffuse membrane in both
side of the membrane. across the membrane directions.
until equilibrium.
 Rate of Diffusion
3 factors affect how fast diffusion occurs:

– Concentration: diffusion is faster at higher
concentrations

– Temperature: diffusion is faster at higher
temperatures

– Pressure: diffusion is faster at higher pressures
 Diffusion: Non-polar molecules
Small, non-polar molecules diffuse easily across the phospholipid
bilayer of a membrane
Example:
– In our lungs, passive transport down concentration gradients is
how oxygen (a small, non-polar molecule) enters red blood cells &
carbon dioxide leaves them
 Facilitated Diffusion
Molecules that are too big, polar, or
Glucose charged cannot move through the lipid
molecules bilayer on their own

They use the help of a protein

When a protein facilitates the diffusion
of a molecule from high to low
concentration, it is called facilitated
Glucose diffusion
protein
channel
Each facilitator protein is specific to
each kind of molecule (for example,
glucose can only go through glucose
facilitator proteins).
 Passive Transport: Facilitated
Diffusion
Channel Proteins Carrier Proteins
open and close to allow change shape to help
substances to diffuse move particles through
through the plasma the membrane
membrane
 Osmosis
In osmosis, water diffuses through a selectively permeable
membrane.
Water will always move from where there is MORE water (high
concentration of water) to where there is LESS water (lower
concentration of water).
 Passive Transport: Osmosis
When a cell is in a solution, that solution may be
hypertonic, hypotonic, or isotonic to the cell.

Hypertonic- when a solution has a higher
concentration of solutes (and less water) than the
cell
Hypotonic- when a solution has a lower
concentration of solutes (and more water) than the
cell.
Isotonic- when a solution has the same
concentration of solutes as the cell.
 Isotonic Hypotonic Hypertonic

Solution with same Solution with Solution with higher
solute concentration as lower solute conc. solute conc. than cell
cell than cell (water (water moves OUT
moves INTO cell) of cell)
 Draw a cell in a hypertonic environment

Which way will
the water = solute
travel? molecule

Cell

13
 Draw a cell in a hypotonic environment

Which way will
the water = solute
travel? molecule

Cell

14
 Draw a cell in a isotonic environment

Which way will
the water = solute
travel? molecule

Cell

15
 Practice Problem #1
Steps:
1.Compare the solute percentages only.
a) If the solution has MORE solute,
then it is hypertonic.
b) If the solution has LESS solute,
then it is hypotonic. 60% water
c) If the solution has the SAME 40% solute
amount of solute, then it is
isotonic.

2.Look at the water percentages only.
Draw an arrow showing which way the
water will travel (it will always go from the
high percentage to the low percentage) 25% water
75% solute

Hypertonic
What type of solution is the cell in? ________________________
 Practice Problem #2
Steps:
1.Compare the solute percentages only.
a) If the solution has MORE solute,
then it is hypertonic.
b) If the solution has LESS solute,
then it is hypotonic.
80% water
c) If the solution has the SAME
20% solute
amount of solute, then it is
isotonic.

2.Look at the water percentages only.
Draw an arrow showing which way the
water will travel (it will always go from the
high percentage to the low percentage) 10% water
90% solute

Hypertonic
What type of solution is the cell in? ________________________
 Water Movement in Animal Cells
Isotonic Hypotonic Hypertonic
solution solution solution
H2O
H2O H2O H2O

Anim
al
cell
(1) (2) (3)
Normal Lysed Shriveled
In an isotonic In a hypotonic solution, a In a hypertonic solution, a
solution, a cell stays cell gets very big and cell shrivels up
normal swells
 Osmoregulation in Animal Cells
For an animal to survive in a hypotonic or hypertonic environment, it
has to have a way to prevent excessive uptake or loss of water
This control of water balance is called osmoregulation
Example: a freshwater fish, which lives in a hypotonic environment,
has kidneys and gills that work constantly to prevent excessive
buildup of water in the body
 Water Balance in Plants
Water balance is different for plant cells because of their rigid cell
walls
A plant cell in an isotonic solution is flaccid, and non-woody plants
(such as most houseplants) wilt
In hypotonic environments, a plant cell is turgid and healthiest
– The elastic cell wall expands a bit, but the pressure it exerts prevents the cell
from taking in too much water and bursting
In an hypertonic solution, a plant cell loses water and its plasma
membrane pulls away from the cell wall, known as plasmolysis

Isotonic Hypotonic Hypertonic
Plasma
H2O H2O H2O membrane H2O

Plan
t
cell
Flaccid Turgid Shriveled