How Common Is Color Blindness? Interesting Facts

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Color blindness is common around the world and brings various challenges for many people. This condition, better known as color vision deficiency, is more than just mixing up reds with greens or blues with yellows. It includes a range of vision issues that change how people see the world. New research and detailed studies show interesting trends, pointing out the role of genetics and how color blindness varies in different places and among different ethnic groups. Whether in busy cities or quiet countryside areas, color vision deficiency can affect what people experience, what they learn, and the jobs they choose. This highlights why it’s important to know more about it and have the right kind of support for those who need it.

What is color blindness?

What is color blindness?

Color blindness, also known as color vision deficiency, is a condition where an individual’s ability to see colors and differentiate between certain shades is less than normal. The term “color blindness” can be misleading, as complete color blindness, where everything is seen in shades of gray, is extremely rare. More commonly, people with color blindness have difficulty distinguishing between specific colors, such as reds and greens or blues and yellows.

This condition is often genetic and is caused by an abnormality in the color-sensitive cells, known as cones, in the retina of the eye. The retina is the light-sensitive layer at the back of the eye that converts light into neural signals sent to the brain. There are three types of cone cells, each sensitive to different wavelengths of light corresponding to red, green, and blue. Color blindness occurs when one or more types of cones are absent, not functioning properly, or detect a different color than normal.

Types of Color Blindness

  1. Red-Green Color Blindness: This is the most prevalent form of color blindness and involves difficulty distinguishing between red and green hues. It is further divided into:
Red-Green Color Blindness
  • Protanomaly: Reduced sensitivity to red light, making reds appear greener and less bright.
  • Protanopia: The absence of red cone cells, leading to an inability to perceive red light, causing reds to appear as black or dark gray.
  • Deuteranomaly: Reduced sensitivity to green light, the most common type of color blindness, where greens appear more red.
  • Deuteranopia: The absence of green cone cells, making it impossible to perceive green light, with greens appearing beige or gray.
  1. Blue-Yellow Color Blindness: Less common than red-green color blindness, this type affects the ability to differentiate between blue and yellow.
  • Tritanomaly: Limited sensitivity to blue light, making it hard to distinguish between blue and green, and yellow and red appearing pink.
  • Tritanopia: The absence of blue cone cells, leading to an inability to perceive blue light, with blues appearing green and yellows potentially appearing light gray or violet.
  1. Complete Color Blindness (Monochromacy): This rare condition involves a total lack of color vision, with individuals seeing the world in various shades of gray.
  • Achromatopsia: A severe form where no cone cells are functioning, resulting in no color perception and often associated with other vision issues like poor visual acuity and light sensitivity.
  • Cone Monochromacy: A rare condition where two of the three cone cell types are not functioning, leaving the person with only one type of cone, making color discrimination impossible, though they might still be able to perceive some color.

How Common Is Color Blindness? Statistics

Color blindness affects a significant number of individuals worldwide, with estimates suggesting that about 350 million people live with some form of color vision deficiency​​. This condition encompasses a spectrum of deficiencies, ranging from difficulties distinguishing between certain colors to, in rare cases, seeing the world entirely in shades of gray.


The sharp inequality in color blindness prevalence between males and females is primarily due to its genetic transmission mechanisms. Color blindness is often linked to mutations in genes located on the X chromosome. Since males have one X and one Y chromosome, a single defective gene on the X chromosome will result in color blindness. Females, on the other hand, have two X chromosomes, so a defective gene on one X chromosome can often be compensated for by a normal gene on the other X chromosome, reducing the likelihood of developing color vision deficiencies​​​​.

This genetic basis explains why approximately 1 in 12 men are color blind, compared to only 1 in 200 women​​​​. Such a significant difference emphasizes the role of X-linked inheritance in the distribution of color blindness across populations.


  • Caucasian Populations: Red-green color blindness is notably more prevalent among Caucasian men, with estimates suggesting that up to 8% are affected. This higher rate can be attributed to the genetic diversity and specific mutations present in these populations​​.
  • Asian Populations: In Asian communities, the prevalence of red-green color blindness is lower, estimated at around 5% among men. This difference indicates variation in the genetic factors influencing color vision across ethnic groups​​.
  • African Populations: African men have an even lower estimated prevalence of red-green color blindness, at about 4%. The genetic variations specific to African populations contribute to this reduced rate​​.
  • Indigenous Populations: Intriguingly, certain indigenous groups, such as the Inuit (Eskimos), have an even lower prevalence of color blindness, with only about 1 in 100 individuals affected. This suggests that isolated populations with less genetic mixing may have lower rates of color blindness​​.

Nations most affected by color blindness include Arab countries, which have a notably high percentage of color blindness. Other countries with significant numbers of individuals affected by color blindness are India, Russia, Norway, France, the Netherlands, Switzerland, Scotland, and Germany. The prevalence of color blindness in these nations can be influenced by various factors, including genetics and the limited diversity of gene pools in certain populations.

Statistics indicate that color blindness is more common among Caucasians, with up to 8% of men and 0.5% of women of Northern European ancestry experiencing the most common forms of color blindness. This highlights the genetic component of color vision deficiencies and their variability across different ethnic and geographical groups.


The prevalence of color blindness and its variation across different age ranges is a topic of interest in understanding how this condition impacts various population segments. While congenital color blindness is present from birth and does not typically worsen with age, acquired color vision deficiencies can develop due to age-related changes or health conditions, affecting the overall prevalence rates within different age groups.

In terms of congenital color blindness, statistics show that red-green color deficiency is the most common type, significantly more prevalent among men and those assigned male at birth (AMAB) due to its X-linked recessive inheritance pattern. Among individuals of Northern European ancestry, for instance, about 1 in 12 AMAB and 1 in 200 people assigned female at birth (AFAB) are affected by red-green color blindness. The prevalence can vary by ethnicity, with some research indicating that Europeans might have the highest rates of this condition. Less common forms of color blindness, such as blue-yellow color deficiency, affect around 1 in 10,000 people, while achromatopsia and blue cone monochromacy are even rarer, affecting 1 in 30,000 and 1 in 100,000 people, respectively. Overall, it’s estimated that around 300 million people globally have some form of color blindness, predominantly the red-green type (Cleveland Clinic).

Age-related changes in vision, including conditions like cataracts, age-related macular degeneration (AMD), and glaucoma, can also affect color perception. For example, in the United States, about 20% of individuals over the age of 85 experience permanent vision loss, which could include difficulties with color vision. Moreover, more than 1.6 million people under the age of 40 live with uncorrectable visual acuity loss, and these younger individuals account for 13% of all cases of blindness. The variance in visual acuity loss and blindness across different states suggests that factors such as access to healthcare, chronic disease prevalence, and lifestyle choices like smoking may influence these rates (Prevent Blindness).

Color Blindness in Children

Color Blindness

Color blindness in children, especially among preschoolers, has been studied to understand its prevalence and distribution across different ethnic groups. A significant study conducted on a multi-ethnic group of preschoolers in California found that Caucasian male children have the highest prevalence of color blindness, with about 1 in 20 being color blind. In contrast, the prevalence was found to be lower in African-American boys, with only about 1.4% affected. The study also confirmed that girls across all ethnicities have a much lower prevalence, ranging from 0% to 0.5%. This aligns with the understanding that color blindness, particularly the red-green type, is an X-linked recessive trait, making it more common in males (American Academy of Ophthalmology).

Another study conducted in Gish Abay town district, Amhara Regional State, Ethiopia, among school children aged 8 to 18 years, reported a prevalence of color blindness at 4.24%. The study found a significant association between sex and color blindness, with males being more likely to be color blind than females. This study’s findings are consistent with the genetic inheritance pattern of color blindness, further emphasizing the higher prevalence in males due to the X-linked recessive nature of the most common forms of color blindness.

Color blindness is more than just seeing colors differently; it affects how people interact, learn, and work every day. The information we’ve shared shows that color blindness varies among different people, including by gender, where they come from, and their ethnic background. Knowing this helps us understand and care for each other better. It also shows why it’s important for everyone to support and include people with color blindness. As we move forward, it’s key to make sure we consider the needs of people with color blindness to create a world that appreciates everyone’s way of seeing things. For more details and help, it’s a good idea to look at trusted health and eye care websites.

Is color blindness rare?

Actually, color blindness is quite common. About 1 in 12 men and 1 in 200 women are color blind, making men 95% of those affected. Most people with color blindness, around 98%, have trouble distinguishing red and green.

Can people who are color blind see red?

While there are various types of color blindness, very few people can’t see any colors at all. The majority of those with color blindness mainly have difficulty perceiving red, green, or blue properly.

Are cats color blind?

Yes, but differently from us. Cats and dogs have blue and green cones in their eyes, which means their color vision is limited, similar to color blindness in humans. They especially struggle to see red, making some colors hard to tell apart.