Lab 5 background
In this lab, we will study the movement of molecules.
The greater the movement of molecules, the greater the rate of diffusion.
Diffusion is the movement of molecules from an area of high to an area of low concentration.
Molecules move due to kinetic energy, the
energy of motion.
Brownian movement is defined as
random movement of small molecules.
As you increase the
temperature, molecules move
faster.
As you increase the
size (the molecular weight), the movement of
molecules is slower.
We will also study osmosis. This is
the movement of water from an area of
high to an area of low
concentration.
hypertonic - means
more solute and
less water. This means water will move
out.
hypotonic - means
less solute and more
water. This means water will move in.
isotonic - means there is
the same amount of solute in and out of the
cell so there will be no net movement.
There are 3 parts of the lab.
Part 5.1
Use agar. It is like jello. At room temperature, it is hard.
You will use 2 dyes of different weight and will measure the distance they travel through the agar.
Take 2 plates.
Record the diameter of the well at time 0
Put 5 drops of dye into one hole of the plate.
Put 5 drops of dye into the other hole of the plate.
Record the diameter of the wells at 10, 20 and 30 minutes.
You will then make a graph. Will it be a line
or a bar graph?
Part 5.2
Use a semipermeable membrane to do dialysis. The membrane has microscopic holes so that only molecules smaller than the holes can move in. Water can also pass through the membrane.
There are two parts of this experiment.
You will measure the weight of the dialysis tubing
to determine the net movement of the water.
If the weight of the tubing is heavier at the end
of the experiment, then water moved in.
If the weight of the tubing is less at the end of the
experiment, then water moved out.
You will use Benedict's reagent to determine if glucose moved out of the bag.
You will test the water outside the beaker and perform the
Benedict's test.
If it is positive, then glucose moved out.
Setup
Fill each bag with the 1M glucose solution.
Then put one bag into a beaker with water. Label this A. This solution contains less solutes than the bag and more water. It is hypotonic. Water will move in.
Put one bag into a beaker with 1M glucose. Label this B. This solution contains the same amount of solutes as the bag. It is isotonic.
Put one bag into a beaker with 3M glucose. Label this C. This solution contains more solutes than the bag. It contains less water. It is hypertonic. Water will move out.
Weigh each bag before you start and then after 30 minutes.
In the second part of the experiment, take 2 test tubes.
Place 1 ml of water in one test tube.
Take 1 ml of the solution from beaker A.
Perform Benedict's test.
Did glucose move out?
Part 5.3
I will demonstrate this part of the experiment.
I will take 4 testtubes.
One has 0.85% NaCl. This is the isotonic solution
One has 0.05 % NaCl.
One has 0.5 % NaCl.
One has 10% NaCl.
I will add ox blood to each tube.
You will have to record the appearance of each and determine if water moved out
or in relative to the cell.
If water moves into the cell, the cell may just swell or it
may burst. The tube will be clear if the cell bursts.
If water moves out of the cell, the cell will crenate,
scallop or shrink. The tube will be cloudy because there are
still cells present.
You also need to determine if the solution is hypertonic/hypotonic or isotonic.
You will compare everything to the 0.85% tube. This is the tube that is isotonic.