Color blind glasses
Color blind glasses or color correcting lenses are light filters, usually in the form of glasses or contact lenses, that attempt to alleviate color blindness, by bringing deficient color vision closer to normal color vision or to make certain color tasks easier to accomplish. Despite its viral status, the academic literature is generally skeptical of the efficacy of color correcting lenses.
Color blindness
Color blindness (color vision deficiency) is the decreased ability to see
Varieties
There are several kinds of lenses that claim to increase accuracy in color-related tasks. The lenses may be eyeglasses, contact lenses or handheld lenses, but are divided in this article according to their working principle. Most lenses are intended for red-green color blindness, though some lenses are also marketed for blue-yellow color blindness. All lenses are passive optical filters, so can only subtract/attenuate selective wavelengths of light. However, there are large variations on this theme:
- Disparate lenses: using different filters over each eye
- Monocular lenses: using a filter on only one eye
- Binocular lenses: using the same filter over both eyes
Disparate lenses
The idea of using colored filters as color correcting lenses originated from August Seebeck in 1837. In 1857, James Clerk Maxwell constructed red and green glasses according to Seebeck's theory.[1] Seebeck noticed that red and green lenses change the relative luminosity of colors that the red-green colorblind usually saw as metamers and the subjects could thereby estimate the correct color. Based on these results, Maxwell hypothesized that color perception would improve after prolonged exposure to the glasses.[1]
Red-green disparately tinted lenses are not currently commercialized, likely because the resulting color vision is highly distorted (making color-naming tasks difficult) and the different lens colors are not aesthetic. However, a modern Swedish invention called the SeeKey uses red and green lenses to help the user identify colors. The lenses are not worn over the eyes, but are handheld. The user alternates looking between the two lenses and can infer a color by the relative brightness changes between the two lenses and direct vision. For example, red-green colorblind subjects routinely confused green and orange; using the SeeKey, orange would appear lighter through the red filter and darker through the green filter (relative to no filter). Using the lenses during the Ishihara test achieve a 86% improvement.[2] Unlike other color correcting lenses, the SeeKey is not intended to be worn consistently, and is only used when required for a color task.
Monocular lenses
Monocular lenses are usually red-tinted contact lenses worn over a single (the non-dominant) eye. These lenses are intended to leverage binocular disparity to improve discrimination of some colors. Compared to disparate lenses, one eye is left unfiltered in order to preserve a realistic perception of colors. Examples of this technology include X-chrom (1971; manual) and Chromagen (1998).
A 1981 review of various studies to evaluate the effect of the X-chrom contact lens concluded that, while the lens may allow the wearer to achieve a better score on certain color vision tests (specifically pseudoisochromatic plates like the Ishihara test), it did not correct color vision in the natural environment.[3] or practical industry.[4] The improvements in pseudoisochromatic plates is from a selective (for some colors) change in brightness, thereby introducing achromatic contrast to the images, rather than an increase in chromatic contrast. In fact, despite the claim of binocular disparity leading to color vision improvements, Ishihara test results actually improved when the dominant (unfiltered) eye was covered during the test.[4]
Although still commercialized, monocular filters are considered obsolete, since they lead to reduced visual acuity, changes in apparent velocity perception, visual distortions (such as the Pulfrich effect) and an impairment of depth perception.[5] These side effects can make monocular lenses a liability when intended as a solution to color blindness.
Binocular lenses
Binocular lenses apply the same filter to both eyes. They do not use binocular disparity (like monocular lenses) or temporal disparity (like the SeeKey) to extract information about color. There are two types of binocular filters, classified by the shape of their transmittance curves.
Tinted filters
Tinted lenses (e.g. Pilestone[6]/Colorlite[7]/ColorMax[8] glasses) apply a tint (e.g. magenta) to incoming light that can distort colors in a way that makes some color tasks easier to complete. These glasses can circumvent many colorblind tests, though wearing them during testing is typically not allowed.[9]
The
A 2010 assessment of several tinted filters showed no useful color enhancement as determined by the
Notch filters
Glasses with a
Lenses with notch filters only work on trichromats (anomalous or normal), and unlike some other types of lenses, do not have a significant effect on Dichromats.[13] However, special vision testing or genetic testing is required for the differential diagnosis of dichromats and trichromats, so it is usually not performed.[13]
Several studies conducted on the efficacy of EnChroma glasses have shown no improvement on traditional
Marketing
When X-chrom lenses—the first therapeutic color correcting lenses—were introduced in 1971, interest in the device was bolstered by false claims that the lenses could cure color blindness. At the time, the FDA had little power to regulate false claims regarding medical devices. In 1976, the FDA was granted this power, but the X-chrom lenses still remained outside of their jurisdiction as they were not classified as medical devices.[19] When ColorMax notified the FDA of their new color corrective lenses in 1998, the FDA enacted restrictions on the marketing that ColorMax could use:[19]
- No insinuations that the lenses would make the colorblind see in "normal color".
- No claiming FDA approval (notification is not approval and does not connote a validation of the technology).
- Must mention that any benefits to some color discrimination is at the expense of other colors.
All of these restrictions would then also be enforced on subsequent color correcting lenses that would want to use the ColorMax (or X-Chrom) as a predicate medical device. Using a predicate device makes the regulatory pathway much easier.[19]
Viral videos centered on colorblind individuals trying color correcting glasses for the first time and having emotional reactions are very common and many lens producers have relied on this viral marketing. While the producers themselves are barred from making the above claims, false claims made in viral social media posts/videos by users of the lenses are unregulated. In 2016, a marketing company affiliated with EnChroma won a marketing award for best use of viral marketing.[20] One YouTuber involved with the marketing campaign, Logan Paul, admitted to embellishing his reaction to trying EnChroma glasses in his vlog,[21] and many have criticized the videos as mainly presenting faked/embellished reactions.[22] Still others have criticized the use of viral, emotional marketing as a way to distract from the "negative scientific news" towards glasses.[23]
Legality
A 1978 study by the
Similar concepts
This section contains similar applications for color correcting lenses and alternative tools for improving color vision.
Achromatopsia
Achromatopsia is a vision disorder with symptoms that include total color blindness, i.e. a complete lack of color vision. While there is no lens that claims to grant achromats color vision, lenses are an important part of achromatopsia management. For example, another symptom of achromatopsia is photophobia, which makes it difficult to see in bright light. Strongly tinted sun glasses[24] or contact lenses[25] are often used to decrease luminosity. Red-tinted lenses are very common, but different hues are used to optimize the comfort of the wearer.[26]
Achromats often use red filters while driving to help identify traffic lights when position cues are not sufficient. Similar to the operation of the SeeKey, modulating a red filter will allow the driver to use differences in brightness to determine which light is on.[27]
Smart Glasses
The color correcting lenses discussed above are all passive filters, and can therefore only subtract light at certain wavelengths. However, active lenses, which are also able to amplify light at certain wavelengths, are much more flexible in how they can 'correct' color vision and impose bigger shifts of color.
Lenses to simulate color blindness
The opposite of color correcting lenses are lenses that simulate
Dyslexia
Color correcting lenses have also been used as an aid in alleviating Dyslexia, a disorder hindering a subject's ability to read. In 2001, the company that made Chromagen lenses for color vision deficiency also claimed that the same lenses led to an "enhancement of reading rate in patients with reading disorders related to distortion of text."[19]
The passage was based on a 1996 study that claimed that color overlays on text (such as looking through a tinted lens) could generate a large and immediate effect on reading speed.[30] The FDA denied that the study supported the claim of reading-rate enhancement, but allowed a reduced claim of "relief of visual discomfort while reading" due to subjects in the study consistently rating “ease of reading” higher with the Chromagen lenses than with placebo lenses.[19]
A recent systematic literature review on tinted lenses used as dyslexia aids came to the same conclusions, stating that their use "to ameliorate reading difficulties cannot be endorsed and that any benefits reported by individuals in clinical settings are likely to be the result of placebo, practice or Hawthorne effects."[31]
References
- ^ S2CID 123930770.
- ^ Flück, Daniel (31 October 2007). "Seekey – Colorblinds See Otherwise Invisible Colors – Colblindor". Colblindor. Retrieved 29 September 2022.
- PMID 6971497.
- ^ PMID 313209. Retrieved 30 September 2022.
- S2CID 228815532.
- ^ Pilestone
- ^ Colorlite
- ^ ColorMax
- ^ "Guide for Aviation Medical Examiners (52. Color Vision)". Federal Aviation Administration. Retrieved 1 October 2022.
- ^ Wenzel, K; Urbin, A (2014). "Improving Colour Vision". Colorlite. Retrieved 1 October 2022.
- S2CID 26345126.
- ^ Zhou L. "A Scientist Accidentally Developed Sunglasses That Could Correct Color Blindness". Smithsonian. Retrieved 6 January 2018.
- ^ PMID 36242206.
- S2CID 250515800.
- ^ S2CID 53721875.
- S2CID 219331901.
- ^ S2CID 220057224.
- PMID 34999724.
- ^ S2CID 27061525.
- ^ "PRO Awards Gold: Best Use of Social/Viral Marketing 2016—Valspar Color for the Colorblind". Chief Marketer. Retrieved 1 October 2022.
- ^ Carvalho, Leonardo (6 June 2021). "Is Logan Paul Color Blind?: The Truth About the Controversy". EssentiallySports. Retrieved 1 October 2022.
- ^ "Fake Enchroma videos". Reddit. 9 October 2020.
- ^ S2CID 219753813.
- ^ Windsor, Richard. "Filters & Sunwear". www.achromatopsia.info. Retrieved 29 September 2022.
- ^ Windsor, Richard. "Contact Lenses For Achromatopsia". www.achromatopsia.info. Retrieved 29 September 2022.
- ^ Windsor, Richard. "Why Red Filters?". www.achromatopsia.info. Retrieved 29 September 2022.
- ^ Windsor, Richard. "Using Filters When Driving with Achromatopsia". www.achromatopsia.info. Retrieved 29 September 2022.
- S2CID 16127607.
- ^ PMID 35778454.
- S2CID 17584625.
- S2CID 19179581.