Science, Tech, Math › Science Fruit Ripening and Ethylene Experiment Share Flipboard Email Print Science Activities for Every Subject Introduction Weather Make a Storm Glass to Predict the Weather Make a Simple Weather Barometer Make Real Snow Make a Cloud in a Bottle Determine Why the Sky Is Blue Food and Cooking Determine Vitamin C by Iodine Titration Make Biodiesel From Vegetable Oil Test for Protein in Food Experiment With Fruit Ripening and Ethylene See How Much Sugar Is in Soda Fire and Smoke Make Colored Fire Make a Smoke Bomb Make Chemical Fire Perform Magic Tricks With Fire Make a Sparkler Bubbles Make Bubbles That Don't Pop Make Glowing Bubbles Make a Giant Bubble Using Dry Ice Make a Bubble Rainbow Crystals Grow Bismuth Crystals Grow a Big Alum Crustal Grow a Borax Crystal Snowflake Grow Copper Sulfate Crystals Grow Table Salt or Sodium Chloride Crystals Chemical Reactions Build a Baking Soda Volcano Make Sulfuric Acid at Home Make Homemade Dry Ice Make Hydrogen Gas Make "Elephant Toothpaste" Juan Silva / Getty Images By Anne Marie Helmenstine, Ph.D. Chemistry Expert Ph.D., Biomedical Sciences, University of Tennessee at Knoxville B.A., Physics and Mathematics, Hastings College Dr. Helmenstine holds a Ph.D. in biomedical sciences and is a science writer, educator, and consultant. She has taught science courses at the high school, college, and graduate levels. our editorial process Facebook Facebook Twitter Twitter Anne Marie Helmenstine, Ph.D. Updated October 11, 2019 The purpose of this experiment is to measure fruit ripening caused by the plant hormone ethylene, by using an iodine indicator to detect the conversion of plant starch to sugar. A Hypothesis: The ripening of an unripe fruit will be unaffected by storing it with a banana. You've heard that "one bad apple spoils the whole bushel." It's true. Bruised, damaged, or overripe fruit gives off a hormone that accelerates the ripening of the other fruit. Plant tissues communicate by means of hormones. Hormones are chemicals that are produced in one location that has an effect on cells in a different location. Most plant hormones are transported through the plant vascular system, but some, like ethylene, are released into the gaseous phase, or air. Ethylene is produced and released by rapidly-growing plant tissues. It is released by the growing tips of roots, flowers, damaged tissue, and ripening fruit. The hormone has multiple effects on plants. One is fruit ripening. When the fruit ripens, the starch in the fleshy part of the fruit is converted to sugar. The sweeter fruit is more attractive to animals, so they will eat it and disperse the seeds. Ethylene initiates the reaction in which the starch is converted into sugar. Iodine solution binds to starch, but not to sugar, forming a dark-colored complex. You can estimate how ripe a fruit is by whether or not it is darkened after painting it with an iodine solution. The unripe fruit is starchy, so it will be dark. The riper the fruit is, the more starch will have been converted to sugar. Less iodine complex will be formed, so the stained fruit will be lighter. Materials and Safety Information It does not take many materials to perform this experiment. The iodine stain may be ordered from a chemical supply company, such as Carolina Biological, or if you are doing this experiment at home, your local school may be able to set you up with some stain. Fruit Ripening Experiment Materials 8 resealable plastic bags, large enough to contain a whole apple/pear and banana4 ripe bananas8 unripe pears or 8 unripe apples (pears usually are sold unripe, so they may be a better choice than apples)potassium iodide (KI)iodine (I)distilled watergraduated cylinderslarge brown glass or plastic bottle (not metal)shallow glass or plastic tray or dish (not metal)knife for cutting fruit Safety Information Do not use metal utensils or containers for preparing or storing iodine solutions. Iodine is corrosive to metals.The iodine solutions will stain skin and clothing.Read the safety information for chemicals used in the lab and follow safety precautions.After the experiment is completed, the stain may be washed down the drain. Procedure Prepare the Test and Control Groups If you are not sure your pears or apples are unripe, test one using the staining procedure outlined below before continuing.Label the bags with the numbers 1-8. Bags 1-4 will be the control group. Bags 5-8 will be the test group.Place one unripe pear or apple in each of the control bags. Seal each bag.Place one unripe pear or apple and one banana in each of the test bags. Seal each bag.Place the bags together. Record your observations of the initial appearance of the fruit.Observe and record the changes to the appearance of the fruit each day.After 2 to 3 days, test the pears or apples for starch by staining them with the iodine stain. Make the Iodine Stain Solution Dissolve 10 g potassium iodide (KI) in 10 ml of waterStir in 2.5 g iodine (I)Dilute the solution with water to make 1.1 litersStore the iodine stain solution in a brown or blue glass or plastic bottle. It should last for several days. Stain the Fruit Pour the iodine stain into the bottom of the shallow tray, so that it fills the tray about half a centimeter deep.Cut the pear or apple in half (cross-section) and set the fruit into the tray, with the cut surface in the stain.Allow the fruit to absorb the stain for one minute.Remove the fruit and rinse the face with water (under a faucet is fine). Record the data for the fruit, then repeat the procedure for the other apples/pears.Add more stain to the tray, as needed. You can use a (non-metal) funnel to pour unused stain back into its container if you wish since it will remain 'good' for this experiment for several days. Analyze the Data Examine the stained fruit. You may wish to take photographs or draw pictures. The best way to compare the data is to set up some sort of scoring. Compare the levels of staining for unripe versus ripe fruit. The unripe fruit should be heavily stained, while fully ripe or rotting fruit should be unstained. How many levels of staining can you distinguish between the ripe and unripe fruit? You may wish to make a scoring chart, showing staining levels for unripe, ripe, and several intermediate levels. At a minimum, score your fruit as unripe (0), somewhat ripe (1), and fully ripe (2). This way, you are assigning a quantitative value to the data so that you can average the value for ripeness of the control and test groups and can present the results in a bar graph. Test Your Hypothesis If the ripening of the fruit was unaffected by storing it with a banana, then both the control and test groups should be the same level of ripeness. Were they? Was the hypothesis accepted or rejected? What is the significance of this result? Further Study Further Investigation You can take your experiment further with variations, such as these: Fruit produces ethylene in response to bruising or wounding, too. Will the pears or apples in the experiment ripen more quickly if the ethylene concentration is higher, from using bruised bananas rather than undamaged bananas?If you have more bananas, you will have more ethylene. Does using more bananas cause the fruit to ripen faster?Temperature affects the ripening of fruit, too. Not all fruits are affected the same way. Apples and pears ripen more slowly when refrigerated. Bananas blacken when they are refrigerated. You could place a second set of Controls and Test Bags in the refrigerator to explore the effect temperature on ripening.Fruit ripening is affected by whether or not the fruit remains attached to the parent plant. Ethylene is produced in response to removing the fruit from its parent. You can design an experiment to determine whether fruit ripens more quickly on or off the plant. Consider using a smaller fruit, such as tomatoes, which you can find on/off the vine in supermarkets. Review After performing this experiment, you should be able to answer the following questions: What are some of the triggers for ethylene production by plants?How does the presence of ethylene affect fruit ripening?What are the chemical and physical changes that occur as the fruit ripens?How can an iodine stain be used to distinguish between ripe and unripe fruit?