Sucrose And Osmosis

The purpose of this lab is to test how molecular size and diffusion relate and to test the permeability of dialysis tubing using sucrose, glucose, starch and iodine.

It is expected that potassium permanganate will travel a farther distance than the methylene blue because the permanganate has a smaller molar mass then the methylene, particles that are larger take more time to move than smaller particles do. In the second experiment it is anticipated that sucrose will increase in volume whereas the water will decrease in volume, this is due to osmosis of water particles and the selective permeability in the dialysis tubing. The second part of the experiment, which dealt with color change in iodine and sucrose, it is predicted that dialysis tube

that contains starch will turn a blue-ish black color because of selective permeability in the tubing.
Movement through a membrane can mean many different things. This includes: diffusion, osmosis, dialysis and facilitated diffusion. The way of transport that is being tested in this lab is passive transport, which means that substances are moving along a concentration gradient. Each on of these methods is very different from the other but practically gets the same job done. In order for the inside of a cell, cytoplasm, to interact with the outside of the cell, the plasma membrane must allow substances to pass through it. The plasma membrane is very picky about what it allows through making it selectively permeable. The rate at which different materials pass through depend on certain components like temperature, membrane thickness, concentration gradient and size of particles. (Lab notes) In our experiment, size of particles is very important because this is what was tested. Larger particles move at a slower rate than smaller particles due to their weight. Diffusion is the process in which particles move from high concentration to low concentration on the cell membrane’s concentration gradient. This movement happens because the molecules will not stop moving and collide with one another. (cliffnotes) Depending on the molecule will determine whether or not the membrane uses carriers or protein channels. In the experiment, diffusion helped show how the two different substances used this method of movement to spread out within the agar plate.
Osmosis is specifically about the movement of water, the solvent, over the selectively permeable membrane and also, like diffusion, the particles move from high to low concentration.

(Cliffnotes) Osmosis played a really big role in the second part of the experiment. One of the beakers was filled with water and so was one of the dialysis tubes and both reacted with sucrose. When particles move through the membrane, whether they go in or out, the cell will either begin to shrink or grow, and can grow so much that it bursts. If a solution gains water it is called a hypertonic to the solution on the outside. If the opposite happens then the solution is hypotonic. When an equal amount of water particles are transferred between both solutions then they are both called isotonic solutions. (Lab notes) Dialysis is the process in which particles, that are different sizes, are separated using a selectively permeable membrane. In the experiment we used the dialysis tubes to test the permeability of water, sucrose and

iodine.

Data:

Media Color Change Explanation
Starch Tube Blue black-ish The tube is permeable to iodine and iodine particles are a lot smaller than the starch, so the iodine moves inside the tube. The iodine reacts with starch and gives the tube the blue/black color.
Water with Iodine No change The tube is not permeable to starch, so the starch stays inside the dialysis tube, which means there wont be a color change since the two wont react.

My results did indeed support my hypothesis.

The molecular size of the molecules affects the rate at which the molecule passes through the membrane. First we found the mass of Potassium permanganate (KMnO4), which has a molecular weight of 158.034 g/mol. Methylene Blue (C16H18N3SCl) whose molecular weight is much larger than the permanganate is 319.85 g/mol. The size of Methylene Blue is almost doubled that of Potassium permanganate. The distance traveled for Potassium permanganate was 3.5 mm in thirty minutes and Methylene blue traveled 3 mm over the same period of time. This shows that the smaller the particle, the faster it is for the molecule to pass through the semipermeable

membrane.
The next part of the experiment involved the three-dialysis tubes being placed in three different solutions: water, sucrose and iodine. Tube A contained water and was placed in the beaker filled with sucrose. The beaker of water is a hypertonic solution, because water moves toward the solution with higher osmotic pressure and in this case, sucrose. This causes the water that is mixed in with the sucrose tube to rush into the beaker to better balance the concentration of water across the membrane. This caused the tube to shrivel up. This is why the initial volume went from 6mL to 4mL. Tube B which contained sucrose was then placed in the beaker filled with water, the solution is hypotonic meaning there is a higher concentration inside the tube than there is outside. The water from outside the tube rushed into the tube of sucrose, which caused the tube to swell. This is why the initial volume here went from 4mL to 6mL. The last tube, which contained the starch solution, was placed in a beaker filled with iodine. The membrane of the dialysis bag is not permeable to starch, which means that starch will not leave the dialysis tube. However, the dialysis tube is permeable to iodine, so the iodine from the outside solution passes through the membrane and into the starch tube, which caused the blue/black color.
The experiment had a few errors that may have caused inaccuracy with results. Placing the different solutions into the dialysis bags was quite difficult and if not tied correctly caused leaks and invalid results. Placing the different substances onto the agar plates also caused some trouble with accuracy. The amount of potassium permanganate wasn’t the same amount of the methylene blue. I personally struggled with this and managed to drop some of the potassium in different spots on the agar plate.