3 DNA Science Fair Project Ideas (Extract DNA From Plants & Humans!)
DNA may sound like rocket science. But in reality, it’s not all that difficult to extract it from fruits, plants, and even humans!
In fact, there’s a variety of DNA experiments and science fair project ideas suitable for elementary and high-schoolers.
But why would it be an interesting subject for kids?
Starting with the discovery of cells in 1665, to learning how to differentiate organelles in the 1830s, to the discovery of DNA in 1953, people have been curious about what makes things alive .
Recent scientific discoveries have proven that DNA is responsible for almost everything happening in living organisms.
DNA holds the instructions needed for every cell to continue living. DNA instructs the creation of proteins, enzymes, cell respiration, the development of cells, and the overall functioning of the cells, and body.
Besides its programming capabilities, DNA is responsible for generational gene transmission, from blood types, and illnesses to facial features and hair color.
Whether the genes are dominant or recessive, they can be present throughout different generations, dead or alive, and they can be calculated and seen without the need for scientific research.
Related Post: Periodic Table of Elements Project Ideas & Activities (4 Quick & Cool Options)
3 DNA Experiments for All Ages (W/ 3 Types of DNA Extraction)
1. dna extraction from a strawberry.
Throughout history, plant DNA has undergone various changes, some because of climate changes, some because of fraught conditions. As a result of that is that fruits from the same tree/ bush can have a different number of genomes. But in the end, both fruits will look very similar.
Strawberries have very complex DNA. It’s an octoploid type of genome, meaning each cell has 8 copies of its chromosomes. So to be precise, one strawberry has around 35000 different genes. That’s 15000 genomes more than human DNA! Thus, extracting DNA from a strawberry will give you a large number of DNA strands.
It’s scientifically proven that plants have more complex DNA than animals and humans !
Materials Needed:
- 3 Strawberries;
- 3.9oz Ethanol alcohol;
- Measuring cup;
- Tablespoons;
- 1 tbsp. Salt;
- 4oz Distilled water;
- 2 tbsp. Dishwashing liquid;
- 1 Ziploc bag;
- Glass bowl;
- Cheesecloth;
Before experimenting, prepare the following:
- Put the alcohol in the freezer 24 hours before experimenting!
- Prepare an extraction liquid: pour half a cup of distilled water into a glass bowl, and put 1 tablespoon of salt and 2 tablespoons of dishwashing soap. Mix until combined.
Procedure – Part 1: DNA Extraction
- Remove the green parts of the strawberries.
- Put the strawberries in a ziploc bag, and squeeze the air out. Squish the strawberries with your fingers until they become a paste. If you’re facing difficulties when crushing the strawberries in a zip lock bag, you can use a mortar and pestle instead.
- Add 3 tablespoons of the extraction liquid to the ziploc bag. The ratio of strawberries to the extraction liquid should be 1 to 1. So for every strawberry used, use 1 tablespoon of the extraction liquid.
- Close the ziploc bag and squish until the extraction liquid fuses with the strawberries.
- After combining the extraction liquid with the strawberries, pour the mixture into a cheesecloth and squeeze out the excess liquids.
- Pour 3.9 ounces of the cold rubbing alcohol into a glass or plastic cup.
- Pour the squeezed strawberries into the cup with the alcohol in it.
- Swirl around the cup until the strawberries disintegrate into the alcohol. There should be a white residue floating in the cup. That’s the DNA right there!
- With a wooden stick collect the residue and put it into a Petri dish.
Part 2: Under the Microscope
Set up a microscope with a magnification of 40X. Use the closest alternative if your microscope does not provide a magnification choice of 40X. The chromosomes found in strawberry DNA may be seen under 40X magnification.
It’s easy to explore new methods and modifications for this experiment.
You can try using different fruits, while strawberries are one of the squishiest fruits, you can swap them with many other fruits like kiwis, bananas, other berries like raspberries and blackberries, and even onions would work perfectly. The squishier fruit the better the DNA extraction!
The whole squeezing process can be done in many ways: you can use a clean mortar and pestle instead of a ziplock bag, or if you want to finish the experiment as fast as possible try using a blender. The downside of using a blender is that it pulverizes the strawberries, and it will cut the DNA into smaller strands.
If you want to bring it up a notch, you can extract the DNAs of every fruit mentioned above and compare the achieved results.
Another additional step you can add to this experiment is staining the DNA for more visible results. The best DNA stains for fruit DNA are Methylene Blue, Crystal Violet, or Ethidium Bromide.
If you’re doing this experiment without supervision, avoid using Ethidium Bromide. It requires supervision and strict safety measures. It’s a dangerous mutagen, it’s easily absorbed and it can cause serious genetic mutations.
On the other hand, the staining results from Ethidium Bromide are quite fascinating, and even though it has a dangerous nature it’s still being used in laboratories worldwide.
So, if you plan on using it, make sure to wear a lab coat, gloves, glasses, and a face mask, and follow your laboratory’s safety guidelines.
To sum up, this experiment is adequate for all ages and is especially fascinating to little future scientists. It’s an educational blend of biology, chemistry, and most importantly entertainment.
2. Extract Your DNA
In comparison with other DNAs, human DNA is surprisingly easy to understand. Human DNA strands are made out of deoxyribose sugars, and phosphate groups, which are closely connected with a covalent bond. They have a specific backbone order and have a specific pair of bases connected to them.
Every deoxyribose sugar is connected with a nitrogenous base, and they help with DNA and RNA replication. And there are 4 bases: A – adenine, C- Cytosine, G- Guanine, and T- Thymine. Each of them has a different function, and a different pair. Adenine pairs with Thymine, and Guanine pairs with Cytosine. When you bind the strands and base pairs they give DNA its functions, and form.
DNA can be extracted from every cell in the body, and most laboratories use blood samples, body fluids, hair cells, and tissues. This experiment is a simplified process where you can extract your DNA, without any specific laboratory formalities or dangerous chemical substances.
- Sample tubes;
- Distilled water;
- Dishwashing liquid;
- A few toothpicks/ wooden screws;
- Measuring spoons;
- Ethanol alcohol;
Additional Laboratory Materials for Further DNA Examination
- Petri dish;
- Microscope;
- Microscope glass slides;
Preparation:
- Put the alcohol in the freezer 24 hours before conducting the experiment.
- Prepare a saline solution: In a small, clean glass pour 2oz distilled water and ¼ teaspoon of salt. Mix until the salt disperses into the water.
- Prepare an extraction liquid: pour ½ oz of distilled water and 3 drops of dishwashing liquid into a glass. Mix it until the dishwashing liquid is completely dissolved.
- Clean and prepare the measuring cups, spoons, and glasses.
Procedure – Part 1: Getting to the DNA
- Using some warm water, clean your mouth. Make sure there is no residue on your teeth, gums, under the tongue, and around the cheeks.
- Massage the inside of your mouth with your tongue. Go around your teeth, gums, and cheeks. This will loosen the cells in your mouth, making the DNA easier to extract.
- Take a sip of the saline solution and swirl it around your mouth for 2 minutes.
- Spit out the solution in a clean glass.
- Prepare a clean glass and pour 3oz of alcohol into it.
- In the same glass pour a tablespoon of the extraction liquid. And mix until combined.
- Slowly pour the saline solution into the glass with alcohol in it. DNA is soluble in water but not in alcohol.
- Swirl around the glass until a white precipitate of DNA starts forming on the top.
- With a wooden screw collect the DNA and place it on a microscope glass slide.
- Prepare a microscope with a magnification of 40X. If your microscope does not have a magnification setting of 40X, choose the next best option. Under 40X magnification, the chromosomes contained in DNA may be best observed.
You can modify this experiment by changing the ingredients: instead of Ethanol alcohol, try using Isopropyl alcohol or denatured alcohol .
Another simple alteration is temperature, the freezing points of the liquids used in this experiment are very diverse, alcohol has a freezing point of -174.6 degrees Fahrenheit (-114.1 degrees Celsius), and water has a freezing point of 32 degrees Fahrenheit (0 degrees Celsius).
By changing the temperature of the water and alcohol, you can find the best final temperature suitable for the DNA extractions. Therefore, you can put the bottle of alcohol in the freezer for 2 hours, 12 hours, or even a few days.
You can repeat the experiment until you find the temperature that gives you a large quantity of DNA precipitates.
As previously mentioned, you can also stain the DNA for more colorful results.
Another addition to this experiment is using a Petri dish, with an agarose base to grow cultures of bacteria. With this, you can see what bacterial cultures are present in your saliva.
3. Extracting DNA From Plants Leaves
DNA from leaves has a similar structure to DNA from fruits.
The difference is that green leaf cells have different structures and different organelles which contain fewer types of DNA than fruit cells.
Fruit cells have different types of plastids which all have different DNAs, and have different structures, forms, and uses. Thus the DNA extracted from fruits isn’t as clean as the DNA extracted from leaves.
Green leaf cells contain a wide layer of chloroplasts, they contain DNA that’s different from the DNA present in the nucleus of the cells. The DNA in chloroplasts is easy to break down and easy to extract.
This experiment focuses on extracting a cleaner but a smaller amount of DNA.
- 4oz spinach leaves;
- 1 tablespoon of salt;
- 3oz distilled water;
- Blender/ Mortar and pestle;
- Toothpick/ wooden screw;
- Put the alcohol in a freezer 24 hours in advance.
- Put the water in the fridge 12 hours before conducting the experiment.
- Clean the equipment that will be used in the experiment for better results.
- In a blender, put 4oz of spinach leaves, 1 tablespoon of salt, and 3oz cold, distilled water. Blend until the leaves get liquified.
- After blending the leaves, pour them into a glass cup, and add a teaspoon of dishwashing liquid. Mix until the dishwashing liquid breaks down.
- Add 3oz of cold, ethanol alcohol into the cup with the leaves.
- Swirl the glass until white gelatinous precipitates form at the top of the solution.
- Collect the precipitate with a toothpick or a wooden screw, and place it on a glass slide for further examination.
You can substitute the types of leaves used. Any plant with moderately sized green leaves will work. You can change the spinach leaves with basil, swiss chard, lettuce, salad, or leaves from flowers you can find in your garden.
You can use a mortar and pestle instead of a blender, it’s more time-consuming but it will give you the same results as a blender.
Furthermore, you can stain the DNA with different types of fluorescent stains, after staining, the DNA sample will have a more prominent look.
The best DNA stains for plant DNA are ruthenium-based stains, such as the aforementioned Methylene Blue, Crystal Violet, or Ethidium Bromide.
Avoid using Ethidium Bromide if you are conducting this experiment without supervision. It needs close monitoring and stringent safety precautions. It is a hazardous mutagen that is quickly absorbed and can result in significant genetic changes.
Frequently Asked Questions
Which fruits and vegetables are the best for dna extractions at home.
The best types of fruits and vegetables for DNA extractions are mushier fruits and vegetables like strawberries, raspberries, and overall all berries, plums, kiwis, bananas, mangoes, and onions.
DNA can be extracted from other fruits and vegetables like apples, pears, plums, carrots, beets, potatoes, and lettuce.
The downside of using stiffer fruits and vegetables is that they need more preparation and they are harder to mash.
Why do you need to use dishwashing soap when extracting DNA?
Dishwashing soap, shower gels, and other cleaning liquids with Sodium chloride in them help with dissolving the lipid cell membranes and the proteins present in cells.
Sodium Chloride breaks down any proteins, and enzymes bound to the DNA strands and it helps with achieving cleaner results.
When combined with water, and alcohol, the dishwashing liquid prevents the dissolved materials from mixing with DNA.
Which type of alcohol is best for DNA extractions?
The best types of alcohol for DNA extractions are 95% Ethanol or Isopropyl alcohol.
Cold Ethanol alcohol should be used when the DNA sample contains a higher concentration of DNA. The temperature and consistency of Ethanol will help with the formation of DNA precipitates.
When the DNA concentration is lower, use Isopropyl alcohol. It doesn’t separate the proteins present in DNA, therefore the amount of precipitates is bigger but the result is cloudier DNA.
Other types of alcohol may cause cloudy results, so they aren’t useful in DNA extractions.
Ana Marija is a young STEM aficionado with a passion for writing. She is a non-formal educator in natural and social sciences, and currently studying theoretical physics at University. Fascinated by music and art, she takes an avant-guarde approach in combining modern-day activities with science.
Editor’s Picks
7 Best LEGO Star Wars Sets | Our Top Picks of All Time!
Best LEGO Creator Sets – Take Your Pick From These 7 Gems!
How to Use a Metal Detector: 8 Essential Tips to Get the Most of It
Best Metal Detector for Kids: 5 Top Picks (+ Buying Guide)
Best 2+ Player Cooperative Board Games (Top 6 in 2024)
MEL Chemistry Review: Is Your Child the Next Bill Nye?
- Earth Science
- Physics & Engineering
- Science Kits
- Microscopes
- Science Curriculum and Kits
- About Home Science Tools
Science Projects > Chemistry Projects > How to Extract DNA at Home
How to Extract DNA at Home
Deoxyribonucleic acid (DNA) is a chemical found in the nucleus of cells that contains the blueprint for the development and function of living organisms. It’s compared to a set of blueprints since it contains the instructions on how to build cells. The instructions are divided into segments along a strand of DNA and are called genes.
Genes provide the code for the production of a protein and control hereditary characteristics such as eye color or personality behaviors. Proteins determine cell type and function, so a cell knows whether it is a skin cell, a blood cell, a bone cell, etc., and how to perform its duties.
What You Need for DNA Extraction:
- Test tube with tight fitting lid
- Isopropyl or ethyl alcohol (at least 70% concentration, higher is better—we used 95%), chilled in freezer for several hours
- Pipette (if alcohol doesn’t come in a dropper bottle)
- Safety goggles
- Sodium chloride (salt)
- Distilled or bottled water
- Liquid dish soap or hand soap
- Stir rod or wooden skewer (optional)
- Small glass vial (optional)
What You Do:
1. Create a saline solution in a beaker by adding two lab scoops of salt to approximately 25 ml of distilled water. Stir until the salt is completely dissolved.
2. Pour the saltwater into the paper cup.
3. Without swallowing, drink a mouthful of the solution from the paper cup and swish it back and forth for at least 30 seconds, occasionally scraping your teeth along the inside of your cheeks as you do. It’s best to do this with a clean mouth, i.e. not right after lunch.
4. Spit your mouthwash solution back into the cup. Then bend the cup into a sort of spout and pour the mouthwashed solution into the test tube until it fills about one-half inch of the bottom of the test tube.
5. Carefully add two drops of the liquid soap.
6. Tilting the test tube approximately 45 degrees, use the pipette (or dropper on the alcohol bottle) to add 20 drops of the chilled alcohol so it slides down the test tube without disturbing the solution. Since it’s less dense, the alcohol will sit atop the mouthwash and soap solution.
7. Tightly put the cap on the test tube and very slowly and gently tilt it upside down then right side up three times. Do it carefully so as not to make bubbles.
8. Let the test tube sit undisturbed in an upright position for one minute. At this point, you should begin to see a milky white thread, possibly interspersed with bubbles, appear between the solution and the alcohol. That’s your DNA! After several minutes, the DNA should be suspended in the alcohol layer.
9. If you wish, insert your skewer or stir rod into the test tube and gently wind the DNA around it.
10. To save it, carefully scrape it into the small vial with a few drops of alcohol. Stored in the freezer, you can preserve your DNA almost indefinitely!
What Happened:
DNA stands for deoxyribonucleic acid (DNA) and it’s a molecule found in the nucleus of plant and animals cells. Passed from one generation of living organisms to the next through reproduction, DNA contains the blueprint for development, survival, and reproduction.
It’s compared to a set of blueprints since it houses the biological instructions that tell an organism how to build cells and what role they’ll play. Sometimes DNA’s structure is described as a twisted ladder that scientists refer to as a “double helix.”
The rungs of DNA are made from four different types of nitrogen-containing bases paired together through hydrogen bonds: adenine (A), thymine (T), cytosine (C), and guanine (G). Adenine and thymine connect to each other and cytosine and guanine connect to each other.
The sides of the ladder, also called the backbone of the DNA molecule, is made from an alternating pattern of phosphate, sugar, then phosphate again. Together, this grouping of a phosphate, sugar, and nitrogenous base makes up a subunit of DNA called a nucleotide, a sort of chemical building block.
But how can a molecule hold information? The base sequence determines the biological instructions that will be passed on through a DNA strand. These instructions are divided into segments along a strand of DNA and are called genes.
Genes provide the code for the production of a protein and control hereditary characteristics, such as eye color or personality behaviors. Proteins determine cell type and function, so a cell knows whether it is a skin cell, a blood cell, a bone cell, etc., and how to perform its duties.
When you swished the saltwater around in your mouth and scraped your teeth along the inside of your cheek, you were also collecting cheek cells. The salt helped them clump together.
The degreasing agents in the soap worked to break down the cell membrane to release the DNA, which is housed inside the cell’s nucleus. Gently mixing the soap and mouthwash solution ensured you didn’t break up the DNA clumps too much. The rest of the cheek cells remained in the saltwater-soap solution.
The strand of clumped together DNA would have eventually dissolved in the saltwater, but since it’s not soluble in alcohol, it precipitates out where the liquid layers meet.
Further Study
For further study, experiment with different types of liquid soap. Try swishing with plain water to see how salt affects the experiment. See if using lower-concentration or room-temperature alcohol changes your results. You can also read this article to learn more about DNA structure , and younger students can build an edible DNA model .
Browse DNA Models:
- Super Models
- Simple Models
- Molecular Models
Welcome! Read other Chemistry articles or explore the rest of the Resource Center, which consists of hundreds of free science articles!
Shop for Chemistry Supplies!
Home Science tools offers a wide variety of Chemistry products and kits. Find affordable beakers, test tubes, chemicals, kits, and everything else you need for lab experiments.
Related Articles
Science Fair Projects for 8th Graders
Science Fair Projects for 8th Graders As kids reach the 8th grade, their exposure to science goes up a notch. Equipped with basic knowledge, they can begin to explore more complicated concepts and satisfy their curiosity for deeper answers to the 'whys' and 'hows' of...
Science Fair Projects for 7th Graders
Science Fair Projects for 7th Graders Science fair projects for 7th graders are a step up in complexity. Because 7th graders have a better grasp of science concepts, they’re expected to practice the scientific method in the way they approach their experiments–which...
Home Science Experiments for Preschoolers
Home Science Experiments for Preschoolers Home science experiments for preschoolers are a great way to pique your child’s curiosity, teach them valuable knowledge, and allow them to have some fun in the comfort of their own home. There are plenty of activities your...
Easy Science Fair Projects for Kids
Easy Science Fair Projects for Kids Science fairs are a long-standing tradition that provide kids with the opportunity to better understand practical concepts in fun and innovative ways. The great thing about the experiments presented at these events is that they...
How to Make a Pollinator Hotel
Have you ever wondered how you can help provide habitat for pollinators like honey bees and butterflies in your back yard? Learn how to make a pollinator hotel with this step-by-step guide and lesson. Pollinators are animals that help move pollen. Most pollinators are...
JOIN OUR COMMUNITY
Get project ideas and special offers delivered to your inbox.
What Are Some Good DNA Science Projects?
Deoxyribonucleic acid is an instruction or how-to manual for any genetic individual, including the human body. A complete set of these instructions for any organism is known as the genome, and DNA is not just found in humans. All living things including plants and bacteria contain DNA. Whether a student chooses to examine various aspects of human or animal examples of this material or discover more about plant and food DNA, the subject of deoxyribonucleic acid has enough variety and complexity to make it great for science projects.
What Makes a DNA Fingerprint Unique?
Human DNA is about 99.9 percent identical between any two people. It is also nearly identical to the DNA of chimpanzees. Even though the differences in human DNA are small, they are enough to give each person unique fingerprints. Testing unique DNA sequences to determine if they can make unique, individual fingerprints can be a good science project for fourth- to sixth-graders. Using an online random sequence generator, students can make or simulate DNA. They will use another online program to make fingerprints for each piece of DNA they have created. From these pieces of created DNA, students will be able to determine if DNA sequences are the same or unique.
Science Buddies http://www.sciencebuddies.org/science-fair-projects/project ideas/BioChem p016.shtml?fave=no&isb=c2lkOjEsaWE6QmlvQ2hlbSxwOjEscmlkOjU1ODkxODA&from=TSW
Extracting Onion DNA
DNA is not found in humans or animals only, but in all organic tissue. Foods, like onions, have DNA as well. Getting DNA from an onion is a science project that has a difficulty level appropriate for fifth-graders. The procedure is relatively simple, making use of many items already in the house such as a blender, alcohol and a kitchen timer. Students will place chopped onion in a solution of table salt, distilled water, alcohol and dish-washing liquid or shampoo. Put this solution into hot water followed by cold water to reveal onion DNA. Because onions contain very little starch, the student will be able to clearly see the DNA they have extracted.
Science Buddies http://www.sciencebuddies.org/science-fair-projects/project ideas/BioChem p001.shtml?fave=no&isb=c2lkOjEsaWE6QmlvQ2hlbSxwOjEscmlkOjU1ODkxODA&from=TSW
Build a DNA-Identifying Tool
Building a tool to identify DNA is a science project more attuned to seventh- through ninth-grade level study. The project involves building a gel electrophoresis chamber to compare molecules in food-coloring dye. Electrophoresis is the method scientists use to separate and see macromolecules such as DNA. Students will need stainless steel wire, nine-volt batteries, plastic foam and other supplies to build the chamber. Baking soda, food coloring, Agarose gel and other supplies will be needed to conduct the experiment. Students will place gel and food coloring in the chamber to determine how many macromolecules are in the dye and which dye goes through the gel fastest.
Science Buddies http://www.sciencebuddies.org/science-fair-projects/project ideas/BioChem p028.shtml?fave=no&isb=c2lkOjEsaWE6QmlvQ2hlbSxwOjEscmlkOjU1ODkxODA&from=TSW
- Science Buddies
Cite This Article
Brown, Serena. "What Are Some Good DNA Science Projects?" sciencing.com , https://www.sciencing.com/good-dna-science-projects-5933423/. 24 April 2017.
Brown, Serena. (2017, April 24). What Are Some Good DNA Science Projects?. sciencing.com . Retrieved from https://www.sciencing.com/good-dna-science-projects-5933423/
Brown, Serena. What Are Some Good DNA Science Projects? last modified August 30, 2022. https://www.sciencing.com/good-dna-science-projects-5933423/
IMAGES
COMMENTS
Though the Sun provides heat and light, which are essential for life on Earth, ultraviolet (UV) rays in sunlight can cause damage to DNA. In this science fair project, you will experiment with a strain of yeast that is super-sensitive to UV light. This project will demonstrate the lethal effects of UV light when DNA damage is not repaired. Read ...
Salt can also be added to make the tiny strands of DNA clump together. Then the DNA can be precipitated, or come out of the solution, by adding alcohol. In this biochemistry science project you will make your own DNA extraction kit from household materials and use it to purify DNA from strawberries.
Though the Sun provides heat and light, which are essential for life on Earth, ultraviolet (UV) rays in sunlight can cause damage to DNA. In this science fair project, you will experiment with a strain of yeast that is super-sensitive to UV light. This project will demonstrate the lethal effects of UV light when DNA damage is not repaired. Read ...
In fact, there's a variety of DNA experiments and science fair project ideas suitable for elementary and high-schoolers. But why would it be an interesting subject for kids? Starting with the discovery of cells in 1665, to learning how to differentiate organelles in the 1830s, to the discovery of DNA in 1953, people have been curious about ...
DNA stands for deoxyribonucleic acid (DNA) and it's a molecule found in the nucleus of plant and animals cells. ... Science Fair Projects for 8th Graders As kids reach the 8th grade, their exposure to science goes up a notch. ... Home Science Experiments for Preschoolers Home science experiments for preschoolers are a great way to pique your ...
DNA / RNA science fair projects and experiments: topics, ideas, resources, and sample projects. DNA / RNA Science Fair Projects Ideas and Sample Projects by Grade Level. Home: Jokes: ... DNA K-12 Experiments & Background Information What is RNA Interdisciplinary Topic: DNA. Elementary School - Grades 4-6.
Human genetics science fair projects and experiments: topics, ideas, resources, and sample projects. Human Genetics Science Fair Projects Ideas and Sample Projects by Grade Level. Home: Experiments: ... Use a computer program on the Web to compare a DNA sequence from several human genes with the corresponding genes in other animals. This will ...
Deoxyribonucleic acid (DNA) is an instruction or how-to manual for any genetic individual, including the human body. A complete set of these instructions for any organism is known as the genome, and DNA is not just found in humans. All living things including plants and bacteria contain DNA. Whether a student chooses to examine various aspects of human or animal examples of this material or ...
DNA, or Deoxyribonucleic Acid, is the molecule of life. DNA exists in every single organism, from the smallest bacteria to the largest mammal, and is the only known molecule that has the ability to replicate itself. ... caused by your use of such information. By accessing the Science Fair Project Ideas, you waive and renounce any claims against ...
Good science fair projects have a stronger focus on controlling variables, taking accurate measurements, and analyzing data. To find a science fair project that is just right for you, browse our library of over 1,200 Science Fair Project Ideas or use the Topic Selection Wizard to get a personalized project recommendation.