Blue Light (High-Energy Visible) and Blue Light Blocking Glasses

The eye’s cornea and lens are unable to filter or deflect Blue Light.

Photochemically-induced retinal injury is caused by the absorption of light by photoreceptors in the retina. Photoreceptors such as rod cells, cone cells & photosensitive ganglion cells convert light into electrical signals in the eye. Normally, when light hits a photoreceptor, the cell bleaches and becomes ineffectual until it has recovered through a metabolic process called Wald’s visual cycle. This visual cycle is the biological process which converts photons, such as electromagnetic radiation (UV light & Blue Light) into electrical signals in the retina.

When the retina is constantly and repetitively subjected to the presence and absorption of Blue Light, at a wavelength 400 – 500 nm, rod cells & cone cells become unbleached and responsive again to light before they are ready.

A few minutes of exposure to Blue Light at 408nm is enough to cause permanent death of photoreceptors and lesions of the retinal pigment epithelium.

Blue Light, Eye & Vision Damage

 

Now let’s compare wavelengths…

    • Blue Light (HEV) versus Ultra Violet A, B & C
    • UV-C (100 nanometres to 280 nanometres)
    • UV-B (280 nanometres to 315 nanometres)
    • UV-A (315 nanometres to 400 nanometres)
    • Blue Light (400 nanomatres to 500 nanometres)

What does this mean?

At a wave length between 400 – 500 nm, Blue Light passes through the cornea and lens and reaches the retina.

 

What are some of the known side effects of being exposed to Blue Light?

    • Cataract formation (also caused by long term exposure to UV light)
    • Age-related Macular Degeneration, the leading cause of low vision & complete vision loss
    • Night Blindness (also caused by lack of vitamin A)
    • Computer Vision Syndrome
    • Sleep deprivation / insomnia
    • Depression
    • Immune system suppression
    • Unstable moods / mood swings

Did you know…

    • Children’s eyes absorb more Blue Light than an adults, therefore children are at higher risk of sustaining vision impairment from exposure to Blue Light from digital devices

What are some known devices that emit Blue light?

    • LED lights (even in indirect presence, such as lightbulbs)
    • LED screens / TVs
    • Compact fluorescent lights
    • PC/laptop monitors
    • Smart phones / tablets

What can you do to prevent vision impairment and detrimental health issues contributed by Blue Light exposure?

    • Buy Blue Light Blocking Glasses.

Is Blue Light Linked To Cancer & Other Diseases?

Studies that can be found linked at the bottom of this page display a link between exposure to blue light at night, such as working the night shift, to types of cancer, diabetes, heart disease, and obesity. We also know that exposure to blue light suppresses the creation of melatonin, a hormone that assists with controlling our circadian rhythms, and there’s some preliminary studies that suggest lower melatonin levels might explain the association with cancer and other diseases.

That’s not all. A Harvard study identified preliminary results that link blue light to diabetes and possibly obesity. The researchers put 10 people on a schedule that gradually shifted the timing of their circadian rhythms similar to what occurs when you look at a screen or mobile phone. The test subjects blood sugar levels increased, placing them into a pre-diabetic state, and their levels of leptin, a hormone that keeps people feeling full after a meal, went down.

 

 

Furthermore, studies show that even dim light can interfere with your circadian rhythm and melatonin creation. A miniscule eight lux—the level of brightness well exceeded by most desk and table lamps and about twice that of a night light has an effect.

Stephen Lockley a Harvard sleep researcher made comment that light at night is part of the reason so many people don’t get enough sleep. Researchers have linked poor sleep patterns and lack of sleep to an increased risk for depression, as well as diabetes and cardiovascular problems.

 

Supporting Research

Blue Light Blocking Glasses & Biological Clock or Circadian Rhythm

Do Blue Light Blocking Glasses Help With Your Biological Clock & Circadian Rythm? Thats a question we get asked every all the time. Everyone has a different circadian rhythms, the typical length is around 24 hours. Those of us who stay up late (night owls) is slightly longer than 24 hours, while the rhythm of early birds is shorter, under 24 hours.

Do Blue Light Blocking Glasses Help With Your Biological Clock & Circadian Rhythm?

Dr. Charles Czeisler of Harvard Medical School identified in 1981 that daylight is the mechanism that keeps a person wake and sleep schedule synchronised with the outside world so it makes sense that less blue light at night, can help regulate your biological clock. So the answer is yes, Blue Light Blocking Glasses can help. If you would like to see what Blue Light Blocking Glasses we have in stock, please visit our shop.

 

What is Blue Light?

What is Blue Light?

Blue light is a specific wavelength of light that plays a significant role in our lives. It is part of the visible light spectrum, with a wavelength between approximately 380 and 500 nanometers. This type of light is most commonly associated with electronic devices, such as computer screens, smartphones, and televisions, but it is also emitted by the sun.

During the day, exposure to blue light can have several benefits. It helps regulate our body’s natural sleep and wake cycles, known as circadian rhythms. It can also enhance attention, boost reaction times, and uplift mood. These positive effects make blue light a beneficial force during daylight hours.

However, as night falls, the blue wavelength becomes a source of concern. In the natural environment, blue light exposure decreases as the sun sets, signaling to our bodies that it’s time to prepare for sleep. But in today’s digital age, we are exposed to high levels of artificial blue light long after sunset.

Screens are an integral part of our lives. From the moment we step out for work or school, during our commute, and even in the last minutes before we try to sleep, screens are omnipresent. This constant exposure to screens, and consequently to blue light, is a modern-day challenge.

Blue light exposure at night can disrupt our natural sleep-wake cycle, making it difficult to fall asleep and leading to poor sleep quality. Over time, this can have serious implications for our health and well-being. Therefore, understanding blue light and how to manage our exposure to it is crucial in our screen-dominated world.

Blue Light – Not Every Colour  Of Light Is The Same
Worker coding on computer

Is Blue Light Safe?

Is Blue Light Safe?

The safety of blue light is a topic of ongoing research and discussion. Do we need Blue Light Blocking Glasses, or is their need a myth? Scientific studies and evidence suggest that these glasses are indeed beneficial.

Blue light, in general, is not harmful. However, it’s a relatively new phenomenon in the context of human evolution, and we are only now beginning to understand its effects. It’s a silent factor that can affect your sleep, and over time, this disruption can potentially lead to health issues.

Before the invention of artificial lighting, the sun was our primary source of light, and people spent their evenings in relative darkness. With the advent of the light bulb, our exposure to light, and particularly to blue light, has dramatically increased. Now, our afternoons and evenings are as bright as midday, and our exposure to blue light extends well beyond sunset.

Blue Light – The Silent Assassin

Do We Need Blue Light Blocking Glasses? & Is Blue Light Safe?

 

 

Blue Light Blocking Glasses are designed to filter out the blue light emitted by screens. They have been shown to reduce eye strain, improve sleep quality, and even enhance mood. By wearing these glasses when using screens, especially in the evening, you can protect your eyes and maintain a healthy sleep-wake cycle.

Do We Need Blue Light Blocking Glasses? & Is Blue Light Safe?