Poor color vision is a reduced ability to distinguish between certain colors. Although many people use the term "colorblind" to refer to the reduced ability to discriminate between colors, true colorblindness is a total lack of color vision, which is rare.
Poor color vision is usually inherited. Men are more likely to be born with poor color vision. Most people with poor color vision can't distinguish between certain shades of red and green. Less commonly, people with poor color vision can't distinguish between shades of blue and yellow.
Certain eye diseases and some medications also can cause poor color vision.
You may have poor color vision and not know it. Some people figure out that they or their child has the condition when it causes confusion — such as when there are problems differentiating the colors in a traffic light or interpreting color-coded learning materials.
People affected by poor color vision may not be able to distinguish:
- Different shades of red and green
- Different shades of blue and yellow
- Any colors
The most common color deficiency is an inability to see some shades of red and green. Often, a person who is red-green or blue-yellow deficient isn't completely insensitive to both colors. Defects can be mild, moderate or severe.
When to see a doctor
If you suspect you have problems distinguishing certain colors, see an eye doctor for testing. It's important that children get comprehensive eye exams, including color vision testing, before starting school.
There's no cure for inherited poor color vision, but if illness or eye injury is the cause, treatment may improve color vision.
Seeing colors across the light spectrum begins with your eyes' ability to distinguish the primary colors red, blue and green.
Light enters your eye through the cornea and passes through the lens and transparent, jelly-like tissue in your eye (vitreous body) to color-sensitive cells (cones) at the back of your eye in the retina. Chemicals in the cones distinguish colors and send that information through your optic nerve to your brain.
If your eyes are normal, you can distinguish different colors, but if your cones lack one or more light-sensitive chemicals, you may see only two of the primary colors.
Poor color vision has several causes:
Inherited disorder. Inherited poor color vision is much more common in males than in females. The most common color deficiency is red-green, with blue-yellow deficiency being much less common.
You can inherit a mild, moderate or severe degree of the disorder. Inherited poor color vision usually affects both eyes, and the severity doesn't change over your lifetime.
- Diseases. Some conditions that can cause color deficits are diabetes, glaucoma, macular degeneration, Alzheimer's disease, Parkinson's disease, chronic alcoholism, leukemia and sickle cell anemia. One eye may be more affected than the other, and the color deficit may get better if the underlying disease can be treated.
- Certain medications. Some medications can alter color vision, such as some drugs that treat heart problems, high blood pressure, erectile dysfunction, infections, nervous disorders and psychological problems.
- Aging. Your ability to see colors deteriorates slowly as you age.
- Chemicals. Exposure to some chemicals in the workplace, such as carbon disulfide and fertilizers, may cause loss of color vision.
You can start by seeing your family doctor or a general practitioner, or make an appointment with a doctor who specializes in eye disorders (ophthalmologist or optometrist).
Preparing a list of questions can help you make the most of your time with your doctor. For poor color vision, some basic questions to ask include:
- How might having poor color vision affect my life?
- Are there treatments for poor color vision?
- Are there brochures or other printed materials I can have? What websites do you recommend?
- Are there special glasses or contact lenses I can wear to help the problem?
What to expect from your doctor
Your doctor is likely to ask you a number of questions, such as:
- When did you first notice having trouble seeing certain colors?
- Does anyone in your family (including parents and grandparents) have poor color vision?
- Do you have any medical conditions?
- Are you taking any medicines or supplements?
If you have trouble seeing certain colors, your eye doctor can test to see if you have a color deficiency. You're likely to be given a thorough eye exam and shown specially designed pictures made of dots that have numbers or shapes embedded in them.
If you have a color vision deficiency, you'll find it difficult or impossible to see some of the patterns in the dots.
There are no treatments for most types of color vision difficulties, unless the color vision problem is related to the use of certain medicines or conditions that can be helped with other therapies.
If you have problems seeing shades of color, and there's an associated eye disease or injury, treatment of the disease may help your color vision.
Wearing a colored filter over eyeglasses or a colored contact lens may enhance your perception of contrasts. But such lenses won't improve your ability to discern colors.
Recent research has shown that some rare retinal disorders associated with color deficiency can be modified with gene replacement techniques. These treatments are under study, but some might become available in the future.
Although there are no clinical treatments to correct inherited color vision problems, most people find ways to work around their poor color vision. For example, you can:
- Memorize the order of colored objects. If it's important to know individual colors, such as with traffic lights, memorize the order of the colors.
- Label colored items that you want to match with other items. Have someone with good color vision help you sort and label your clothing. Arrange your clothes in your closet or drawers so that colors that can be worn together are near each other.
Feb. 13, 2014
- Color vision deficiency. American Optometric Association. http://www.aoa.org/patients-and-public/eye-and-vision-problems/glossary-of-eye-and-vision-conditions/color-deficiency. Accessed Sept. 17, 2013.
- Riordan-Eva P, et al. Vaughan & Asbury's General Ophthalmology. 18th ed. New York, N.Y.: The McGraw-Hill Companies; 2011. http://www.accessmedicine.com/resourceTOC.aspx?resourceID=720. Accessed Sept. 17, 2013.
- Ropper AH, et al. Adams & Victor's Principles of Neurology. 9th ed. New York, N.Y.: The McGraw-Hill Companies; 2009. http://www.accessmedicine.com/resourceTOC.aspx?resourceID=54. Accessed Sept. 17, 2013.
- Komaromy AM, et al. Gene therapy rescues cone function in congenital achromaptopsia. Human Molecular Genetics. 2010;19:2581.