Many of us fear the fallout from the wireless radiation of 5G and cell towers, yet we’ve forgotten the most commonplace predator in our lives.

 

Here’s what you’ll learn in this article:

1. How life cycles are similar to light cycles

2. How does blue light affect health: the Big Picture

3. Impact on melatonin

4. Why blue-blocking glasses dont’ save us completely

5. Impact our hormones

6. How liver detox is disrupted

7. How children absorb blue light

8. How blue light contributes to brain disease

9. Environmental impact

 

One of the most intense forms of EMF (electromagnetic field) we’re subject to in our modern society is blue light. Yes, light is EMF.

You can learn about light and EMF basics here:

Life cycles are light cycles

This light comes not only from our devices, televisions, and LED bulbs, but is also present in sunlight. Blue light from the sun can even boost our immune system by energizing infection-fighting T cells.

The solar spectrum provides a balance of light, whereas the spectrum of our indoor generation’s LEDs and electric lighting ruins this delicate equilibrium of light that forms the foundation of our metabolism.

Consider prey and predator as a couple. When predator eats prey, this has a positive effect on the eater, and a negative effect on the eaten animal.

The negative effect on predators when they eat prey: less prey animals prevents uncontrolled growth of the predator’s population. This stabilizes the population sizes of both groups when they are coupled.

Red light helps us relax and regenerates our nervous system, while blue light keeps us energized and primes our fight/flight response.

“Blue and red light in the sun are like predator and prey…they each perfectly balance one another. But modern artificial light has 4 times the amount of blue and no red. This destroys the coupled cycle.”

Jack Kruse

How does blue light affect health?

The blue light that is emitted from our screens is a shorter wavelength of approximately 450nm (nanometers) as compared to incandescent bulbs which can run into the infrared range (IR) of 700nm.

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Why does this matter?

Shorter wavelengths take longer to pass through our cells, whereas longer wavelengths from IR light pass through more quickly. You can see an illustration of this effect on the video I posted here: “What You Need to Know About EMF”.

You may not be able to tell, but the blue light that is emitted by our phones is pulsed, which is harder for our eyes to process. In order to understand why this type of light can be so harmful, we first must appreciate how light evolved to be beneficial to humans throughout our history.

Before the advent of electricity, societies lived by candlelight (infrared source) and under the full spectrum of the sun. Almost half of the solar spectrum is comprised of infrared light, which regenerates our body by increasing melatonin stores in our skin, eyes, as well as allowing our mitochondria to produce energy efficiently.

Back to the concept of balance. We’ve heard that UV light can cause skin cancer. Yes, alone it can. However, did you know that most of the data that links the sun to skin cancer comes from studies done indoors using UV light from man-made sources and not the sun.

We need UV, as well as the infrared spectrum for our bodies to work. Amino acids such as tryptophan absorb light in the UV spectrum of 210nm, and hormones like serotonin also absorb UV light at 337nm. Our mitochondria, which generate energy for our metabolism, love infrared light at 620-680nm.

What are we absorbing today?

Here’s the big picture:

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Notice how much more of a rich, full spectrum was available for our bodies before the advent of the light bulb?

Blue light destroys melatonin

Many researchers, including those from Harvard

, have shown that blue light at night, or even any artificial light at night (ALAN) destroys melatonin. Melatonin is a hormone that our bodies secrete at night so that we can regenerate, repairing all of the damage we’ve done during the day, as well as eliminate mitochondrial waste products through a process known as mitophagy.

Many of us think of melatonin as the “dark hormone.” Light at night suppresses melatonin. However what many don’t know is that light during the day is what regenerates the melatonin stores in our body. We actually have two different types of melatonin. One type is secreted by the pineal gland of our brain, and the other is called subcellular melatonin, and stored in our skin as we expose ourselves to sunlight throughout the day.

Our bodies typically need about two hours of total darkness to begin secreting melatonin at night, and it takes about four hours for melatonin secretion to peak. This means that if you look at your phone at 10pm, you won’t start the process of falling asleep in earnest until midnight. Since melatonin still requires time to run its course through our bodies, you may still have some in your system when you wake up, feeling groggy as a result.

Blue-light blocking glasses don’t save us completely

Proteins are the building blocks of life, and give our cells messages on how to function. The study of epigenetics, or how our environment triggers certain genes to turn on or off, maintains that these on/off signals are mediated by G protein-coupled receptors (GPCRs). Opsins are such a protein.

Our blue-light detectors: melanopsins

Opsins are light-sensitive retinol (vitamin A) proteins, and until 2017 was thought only to exist in our eyes. We now know that our skin and fat also contain this photoreceptor.

Melanopsin is particularly sensitive to the absorption of blue light (435nm – 480nm) and will communicate this light frequency to our central clock: the suprachiasmatic nucleus (SCN), which dictates our circadian rhythm.

Disclaimer: I do wear blue-blocking glasses at night.

Our eyes are more densely packed with mitochondria than our skin, so they can be more acutely affected by light.

God did give us only two eyes, so any time I can protect them I will. I’ll even jog backwards at sunset when I see other cars coming my way with their blue beaming rays.

Our Master Clock, the Suprachiasmatic Nucleus (SCN)

Our circadian rhythms drive our metabolism, and each of us even has an individual rhythm that dictates how well we can digest food at certain times during the day.

When these rhythms are thrown off, a cascade of effects occurs, which can lead to cancer, autoimmune disease, or diabetes as in the example below:

Blue light chronically elevates blood glucose. When blood glucose is chronically elevated by your blue light-toxic environment, red blood cells cannot deliver oxygen well to mitochondria.

“Melanopsin is the blue light detector of light that links to the leptin hormone in our fat. The interaction between melanopsin and leptin allow the hypothalamus to know the correct energy balance in the body. This process also controls the levels of melatonin in the body, which control the efficiency of apoptosis (programmed cell death) and optimizes tissue level energy and information transfer to and from the brain’s hypothalamus, operating tight control over the molecular clock functions in the body.”

-Jack Kruse, M.D.

Basically, melanopsin not only regulates the amount of melatonin that will ultimately be released from our pineal gland at night, it is also the key driver in setting our circadian rhythms and sleep patterns.

Melanopsin regulates our sleep the following two ways

:

1. The circadian mechanism, which determines the optimal time for sleep.
2. The homeostatic system, which keeps track of how long the body is awake and asleep, triggering “sleep pressure” when the body suffers from sleep deprivation.

Melanopsin is also our eyes’ dimmer switch, as it allows the pupillary reflex to work during the time of sunrise and sunset. If you’re a romantic like me and like exploring unique vistas to see the sunset, melanopsin is what helps you find your way back home.

When we expose ourselves to excessive amounts of blue light, we not only deprive ourselves of quality sleep, we desensitize melanopsin so that we no can longer see as well in low-light environments.

Blue light affects our hormones

When we absorb high-energy EMF (electromagnetic fields) in the form of blue light, we also destroy our stores of retinol, or vitamin A.

We need vitamin A to make:

• thyroid hormone
• progesterone
• testosterone
• growth hormone

Once our melanopsin receptor is desensitized, the enzymatic pathway of vitamin A can be irreversibly damaged.

Another way our hormones are affected by blue light is cortisol. Cortisol is a stress hormone we use in our fight/flight response. It’s meant to be fast-acting, and have a resolution once we’ve run from the lion. However in our modern day, we’ve become chronically stressed at a very low level. This can create a condition known as hypercortisolism (Cushing’s syndrome).

Anytime cellular stress is high, which includes stress from excessive blue light- it also forces an all-important prohormone pregnenolone to be switched to cortisol production.

What does this mean?

Many of our hormones such as DHEA, androstenedione, Vitamin A, D, testosterone, estrogen, and aldosterone, are made from pregnenolone. When its production is disrupted, all of these hormonal levels fall dramatically as a result.

When cortisol is up, melatonin is also down.

These types of hormonal imbalances can lead to all types of mood disorders, cancers, and autoimmune disease.

Blue light disrupts detox

Our livers detox through the cytochrome p450 enzymatic pathway.

Why is this relevant?

This “p” enzyme was given its name because its absorption of light peaks at 450nm

, which is the same wavelength as blue light.

An excess of this light disrupts liver metabolism.

When we have melanopsin dysfunction, cytochrome p450 no longer works effectively.

Children absorb more blue light

Children under 10 years of age absorb 60% more blue light into their retina as the lens of their eyes is not yet fully developed – link to study.

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Blue light also scatters more easily than most other visible light, making it difficult for our eyes to focus. Instead, our eyes may digest blue light as poorly focused visual static. This reduction in contrast may make it more difficult for our eye to process blue light, contributing to eyestrain.

How blue light contributes to diseases of the brain

Blue light dehydrates cells because it causes them to stop producing H20 from mitochondria, the engines of our cells.

Why is this important?

Neurons absorb and release water when firing. When H2O is missing in action so are neurological capabilities.

Our neurotransmitters (NT) such as dopamine, serotonin, GABA, all need calcium to work. Exposure to excessive blue light is also associated with calcium efflux in mitochondria.  As calcium flows out of our mitochondria, and into our bloodstream, it causes problems with NT release.

Remember how blue light can affect our circadian rhythm by disrupting communication to our suprachiasmatic nucleus (SCN)?

When our SCN is out of rhythm, our brain becomes more susceptible to all kinds of disease, including Parkinson’s and Alzheimer’s, as our our cerebrospinal fluid (CSF) can no longer flush out toxins effectively through our glymphatic system when we sleep, contributing to formation of amyloid plaques and mis-folded proteins in our brain.

Each night we undergo a type of oil change for our brain, and the mechanism that facilitates this is our very own electricity.

We recharge like a battery at night

We use a crucial amino acid called DHA to regenerate at night. DHA allows us to use our body’s internal DC (direct current) electric circuit to regenerate at night.

Blue light destroys DHA everywhere in our tissues. As DHA levels decline, the inputs to the SCN from melanopsin photoreceptors also decline. We start to lose our ability to repair as a result.

Anatomy of LEDs

We were told that LEDs are environmentally-friendly, however is this true?

Fluorescent bulbs are toxic enough, containing mercury vapor that can now be energized through radio transmitters called “electronic ballasts.”

LEDs bring it to another level, as many are now Wi-Fi enabled, adding a layer of nervous system disruption to our environment. I guess hitting a light switch was too hard?

LEDs have special electronic components that require toxic metals such as aluminum, gallium, indium and gallium phosphide, and indium gallium nitride in order to work. These components are often switch mode power supplies, which operate at ultrasonic frequencies

, and have a multitude of health impacts. The FCC rules also allow every energy efficient bulb to emit microwave radiaton at frequencies up to 1,000 MHz.

These bulbs clutter landfills, and the precious metals used to make their electronic components take much longer to degrade in our soils than the copper wire of standard incandescents.

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The LED light above, which you can also turn on from your phone, is just one example. Our streets are also being littered with this type of light pollution with smartlights, which are actually way more of a computer and 5G surveillance system than they are a bulb.

To check out examples of smart lighting, and the misinformation campaign telling us they are safe, please see the following article:

Is energy really being saved by LEDs in our home?

By Roman S Shapoval 

The Power Couple by Roman Shapoval