What would happen if you don’t get enough sun?

Which is the vitamin that is not normally found in any vegetarian food? Vitamin D.

Scientists have defined vitamins as organic (carbon-containing) chemicals that must be obtained from dietary sources because they are not produced by our bodies. Vitamins play a crucial role in our body’s metabolism, but only tiny amounts are needed to fill that role.

The discovery of Vitamin D was the culmination of a long search for a way to cure rickets in the 1920s, a painful childhood bone disease. Within a decade, the fortification of foods with vitamin D was on the way, and rickets became rare in the United States. However, research results suggest that vitamin D may have a role in other aspects of human health.

Vitamin Dit’s absent from all-natural foods except for fish and egg yolks, and even when it’s obtained from foods, it must be transformed by the body before it can do any good. That’s why the energy of the Sun is so important.

The sun’s energy turns a chemical in your skin into vitamin D3, which is carried to your liver and then your kidneys to transform it into active vitamin D.

The main cause of vitamin D deficiency is a lack of direct sunlight

Humans, day by day, spend less time outdoors. Most people work indoors now, and many of our leisure pursuits occur in an indoor setting as well. What’s more, when we are outside, many people avoid the sun as much as possible. The result is the body not absorbing enough UVB rays to create the amount of vitamin D it requires. Often, symptoms of vitamin D deficiency are quite mild. When noticed, they mainly consist of:

• Bone pain.
• Chronic fatigue.
• Frequent bone fractures.
• Muddled thought processes.
• Muscle weakness.
• Soft or deformed bones.

Though you may not notice any symptoms, that doesn’t mean that vitamin D deficiency doesn’t present serious health risks. These include:

• Children may develop severe asthma.
• Immune system problems, raising your risk of infection.
• Insulin resistance, impacting your body’s ability to process sugar and increasing your risk of diabetes, multiple sclerosis, and glucose intolerance.
• Osteoporosis, a condition that includes brittle bones that are more likely to fracture.
• Reduced cognitive function.
• Rickets, a bone disease that causes soft bones and skeletal deformities.

Other conditions that would happen without enough sunlight

Less chance of having a baby

Without sunlight, there will be more melatonin in a woman’s body. This is a hormone that suppresses fertility, thereby reducing her chances of conceiving a baby. Moreover, women who get less sunlight reach their menopause earlier than those who are exposed to the Sun. Men can also suffer from a lack of sunlight; it directly influences testosterone levels.

Raw nerves

It’s believed that if children don’t get enough sunlight, they’ll be more at risk of developing multiple sclerosis, a disease of the central nervous system when they become adults.

All those aches and pains

Without sunlight, be prepared to get more pains all over your body. Sunlight helps to warm the body’s muscles and reduce the pain caused by inflammatory conditions such as arthritis.

No sunny emotions

Without sunlight, we would be forever stuck with the seasonal affective disorder (SAD), commonly known as the winter blues. It’s a form of depression that is specifically caused by a lack of sunlight. Artificial light cannot fully replace natural sunlight.

Recent evidence suggests that vitamin D may help prevent many disorders, such as diabetes, multiple sclerosis, rheumatoid arthritis, chronic obstructive pulmonary disease, asthma, bronchitis, premenstrual syndrome, increased blood pressure, strokes and heart attacks, and even cancer. Low serum vitamin D levels are also associated with being overweight, abdominal obesity, metabolic syndrome, stroke, and diabetes. In addition, having lower blood vitamin D levels for a long period is associated with increased heart attacks and all-cause mortality.

In Kaiyan medical, we believe in the benefits of light. We believe in healing without chemicals. With our lights, we want you to have the best version of yourself. More at kaiyanmedical.com

Nothing is more important to us on Earth than the Sun. Without the Sun’s heat and light, the Earth would be a lifeless ball of ice-coated rock. The Sun warms our seas, stirs our atmosphere, generates our weather patterns, and gives energy to the growing green plants that provide the food and oxygen for life on Earth.

We know the Sun through its heat and light, but other, less obvious aspects of the Sun affect Earth and society. Energetic atomic particles and X-rays from solar flares and other disturbances on the Sun often affect radio waves traveling the Earth’s ionosphere, causing interference and even blackouts of long-distance radio communications. Disturbances of the Earth’s magnetic field by solar phenomena sometimes induce huge voltage fluctuations in power lines, threatening to blackout cities. Even such seemingly unrelated activities as the flight of homing pigeons, transatlantic cable traffic, and the control of oil flow in the Alaska pipeline apparently are interfered with by magnetic disturbances caused by events on the Sun. Thus, understanding these changes — and the solar events that cause them — is important for scientific, social, and economic reasons.

We have long recognized the importance of the Sun and watched it closely. Primitive people worshiped the Sun and were afraid when it would disappear during an eclipse. Since the early seventeenth century, scientists have studied it with telescopes, analyzing the light and heat that manage to penetrate our absorbing, turbulent atmosphere. Finally, we have launched solar instruments and ourselves-into space to view the Sun and its awesome eruptions in every aspect.

Once we looked at the Sun by the visible light that reached the ground, it seemed an average, rather stable star. It was not exactly constant, but it seemed to vary in a fairly regular fashion, with a cycle of sunspots that comes and goes in about eleven years. Now the Space Age has given us an entirely different picture of the Sun. We have seen the Sun in other forms of light-ultra violet, X-rays, and gamma rays that never reach the ground from space. This radiation turns out to be far more responsive to flare eruptions and other so-called solar activity.

We now see the Sun as a place of violent disturbances, with wild and sudden movements above and below its visible surface. Besides, solar activity's influence seems to extend to much greater distances than we had believed possible. New studies of long series of historical records reveal that the Sun has varied in the past in strange and unexplained ways. Scientists wonder how such variations might affect the future climate on Earth.

We have obtained a clearer picture of the scope of the Sun’s effects. Its magnetic field stretches through interplanetary space to the outer limits of the solar system. Steady streams and intense storms of atomic particles blow outward from the Sun, often encountering our Earth's atmospheres and the other planets. The spectacular photos of the Earth from space show only part of the picture. Instruments carried on satellites reveal a wide variety of invisible phenomena — lines of magnetic force, atomic particles, electric currents, and a huge geocorona of hydrogen atoms — surrounding the Earth. Each is as complex and changing as the visible face of the globe. The Earth’s magnetic field extends tens of thousands of miles into space, and many different streams of electrons and protons circulate within it. Huge electric currents flow around the Earth, affecting their high-altitude surroundings as well as our environment at ground level.

Space observations have greatly expanded our ability to look at the Sun, interplanetary space, and the Earth's immediate surroundings. We can now “see” many phenomena that are completely undetectable from the Earth’s surface, and we now have a much better, more complete, and more coherent picture of how events in one part of our solar system relate to activity in another.

The Sun as a Star

We sometimes forget that there is one star that is easily visible in the day time: our Sun. The Sun is the only star close enough to be studied in detail, but we are confident that all the processes in the Sun must also occur in billions of distant stars throughout the universe. To understand the nature and behavior of other stars, we must first understand our own. At the same time, observations of other kinds of stars help put the Sun in perspective.

The Sun is a relatively typical star among the approximately 100 billion stars in our Milky Way galaxy. The masses of most other stars that we see range from approximately one-tenth of the mass of the Sun to about 30 solar masses. The surface temperatures of most stars range from about 2000° C to 40,000° C. Although the Sun is somewhat on the cool side at about 6000° C, hot stars are rare, and most normal stars are cooler than the Sun. Compared to some of the explosive stars — novae, and supernovae — which sometimes appear in the sky, the Sun is stable and ordinary.

This long-term stability of our Sun probably was crucial for the development of life on Earth. Biologists believe that a relatively stable average temperature had to prevail on Earth during the past 3 billion years for life to evolve to its present state. The relative stability of the Sun is also important to astronomers trying to understand the basic nature of it and other stars. Violent activity in the Sun could mask the more subtle and long-enduring processes, which are the basic energy transport mechanisms of our star. Fortunately, they are not hidden, and we have been able to map the trend in solar properties with height above the visible surface.

Above the minimum temperature region in the photosphere, we have measured how the gas gets hotter as it thins out with height. The chromosphere and corona, each hotter than the layer below, are warmed by the transfer of energy from below through processes that are still not well understood.

Until space observations became possible, we knew nothing about coronae in any other stars and had only marginal information about stellar chromospheres' properties. Now, space observations have shown us that a large fraction of the stars in the sky have chromospheres and coronae.

On several dozen stars, we have even detected activity that may be connected with sunspot (or “starspot”) cycles like those of our own Sun. X-ray telescopes carried on satellites have recorded flares in other stars that are far more powerful than the already impressive flares of the Sun. By observing the strength and frequency of these events on stars with masses, ages, and rotation rates which differ from those of the Sun, we search for answers to such basic questions as: “How does the sunspot cycle period depend on the star’s rotation rate?” or “What is the relation between the temperature of a star’s corona and the strength of its magnetic field?” By deciphering the general pattern of stellar properties, we can better understand what makes things happen on the Sun.

The Sun presents us with a bewildering variety of surface features, atmospheric structures, and active phenomena. Sunspots come and go. The entire Sun shakes and oscillates in several different ways at the same time. Great eruptions called prominences hang high above the Sun’s surface for weeks, suspended by magnetic force, and sometimes shoot abruptly into space from the corona. The explosions called solar flares emit vast amounts of radiation and atomic particles in short periods of time, often with little or no warning.

Space observations have discovered many new aspects of solar events hidden from ground-based observatories—the Sunshine's hottest spots primarily in ultraviolet and X-rays, rather than in visible light. Thus, only from space can we map high-temperature solar flares' true structure and determine their physical conditions. Space observatories have shown us the higher, hotter layers of the Sun’s atmosphere that normally are invisible from the ground. Instruments on satellites revealed that in flares and other violent disturbances, the Sun acts like an atomic accelerator, driving electrons and protons to velocities approaching the speed of light. At such high speeds, the particles emit the high-energy X-rays and gamma rays measured by our satellites. Sometimes they even induce nuclear reactions on the surface of the Sun.

Two aspects of our improved knowledge of the Sun deserve special attention. One is the role of magnetic fields in determining virtually all aspects of the Sun’s upper atmosphere's structure and behavior. The other is discovering the solar wind, a stream of atomic particles that constantly evaporate from the Sun’s atmosphere and are accelerated to speeds of hundreds of kilometers per second, escaping into space in all directions.

The Earth-Sun Battle

For any solar particle to reach the Earth, it must first pass through the Earth’s magnetic field. Before the solar wind was discovered, the Earth’s field was thought to be symmetrical, resembling a huge bar magnet, fading off indefinitely into space. However, we now know that the solar wind shapes the Earth’s magnetic field's outer regions and is sharply bounded. Outside the boundary, space is dominated by the solar wind and the interplanetary magnetic field. Inside the boundary is the region or magnetosphere dominated by the Earth’s magnetic field. The measurements from many space missions have been combined to reveal that the solar wind blows out the Earth’s magnetosphere into a teardrop shape. The head of the drop extends only about 10 Earth radii, or about 65,000 kilometers (40,000 miles) “upwind” toward the Sun. The tail of the drop stretches away in the direction opposite the Sun, actually reaching beyond the Moon’s orbit. This long magnetotail extends more than 600,000 kilometers (370,000 miles) from the Earth.

At the boundary of the magnetosphere, there is a constant struggle between the Earth's magnetic field and the forces of the Sun. Buffeted by fluctuations in the solar wind velocity and density, the magnetosphere’s size and shape are continuously changing. When the solar wind strikes the magnetosphere, shock waveforms are analogous to the sonic boom preceding a supersonic airplane. Inside the boundary with the solar wind, the magnetosphere remains an active region. It contains two belts of very energetic charged atomic particles trapped in the Earth’s magnetic field hundreds of miles above the atmosphere. These belts were discovered by Professor James Van Allen of the University of Iowa and his colleagues in 1958, using simple radiation detectors carried by Explorer 1, the first U.S. satellite.

The Northern and Southern Lights: Gifts from the Sun

The structure of the Earth’s magnetosphere also controls aurorae's behavior, seen in our night skies. Pre-Space Age textbooks stated that aurorae are produced by photons emitted from the Sun and reach the Earth’s upper atmosphere through gaps in the Earth’s magnetic field at the north and south magnetic poles. According to the theory, these protons strike oxygen atoms in the atmosphere, and the collisions cause the glow, which we call the Northern Lights.

This view has changed in the Space Age. The data collected by many spacecraft showed that the situation is more complicated. Particles from both the solar wind and from the Earth’s atmosphere apparently are stored in the magnetotail. From there, they periodically are violently ejected into the northern and southern polar regions of the atmosphere along the Earth’s magnetic field. They are accelerated to high speeds by a process not yet fully explained. The magnetotail is, in effect, a reservoir of particles that is periodically refilled. When the Sun is active during maximum sunspot years, this process is especially intense and frequent, and the aurorae are brighter and move closer to the equator.

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For thousands of years, people have used sunlight as a means to aid health and even cure illness. But the concept has gone in and out of favor over the course of time.

Some of the logic related to sunlight began in China around 6,000 BC. At that time, Chinese architects began building homes to face south so that the sun would heat the interior, a practice that continues even today. While windows were likely no more than a gap in the wall at the time, you can still imagine families gathering around to soak up the light and heat. Finally, the trend of solar-heated homes began to catch on in Greece and even Rome. Learn more about solariums.

Then, in the 1900s, research by Augusta Rollier led to the establishment of solaria — buildings designed to optimize exposure to sunlight — throughout Switzerland for the express purpose of sunbathing, which provided impressive results for fighting tuberculosis, smallpox, lupus, and even chronic diseases like arthritis.

But by the middle of the 20th century, the American Cancer Society began demonizing sun exposure as a significant cause of skin cancer.

However, doctors, scientists, and clinical research is demonstrating that consistent exposure to sunlight is actually a critical component of overall health.

Almost all life on earth needs sunlight for many essential functions. It’s hard to ignore its importance for our emotional and physical health as well. We did not evolve in the darkness. The fact that our bodies use UV wavelengths to produce vitamin D has been well established. Read more about vitamin D here.

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Is Sunlight Dangerous?

Several recent studies have come to the conclusion that consistent sunlight exposure actually reduces the chances of getting melanoma, and instead increases the survival rate. Also, throughout the ages, regardless of their geographical location, large groups of people have been exposed to nearly continuous sunlight. We evolved having sunlight.

So why did the melanoma epidemic not hit until the 1970s? And if sunscreen is the solution, why have melanoma rates increased over 200% since 1973 — even while the U.S. sunscreen industry has expanded from $18 million in 1972 to around $2 billion today? It’s hard to believe that sunlight was the major problem, nor sunscreen the solution.

A recent review of many such studies published in the European Journal of Cancer Prevention concluded that “there is accumulating evidence for sunlight as a protective factor for several types of cancer.”[5] Sadly, many people still live under the incorrect premise that sunlight is damaging and harmful.

The reality is that we have become so disconnected from natural sunlight that our bodies aren’t equipped to handle its under-appreciated benefits. You may be surprised to learn that as your body gets sunlight in the morning, you can actually prepare your cells for the effects of UV light later in the day. And amazingly, the wavelengths in evening sunlight have a natural repairing effect. That’s because red and infrared wavelengths, which are delivered in higher concentrations in the morning and evening, have the unique ability to boost mitochondrial function. This, in turn, enables our cells to both withstand the stresses — and harness the benefits — of UV light. In addition, exposure to sunlight as the seasons change allows our skin to develop a tan, which also forms a natural protection against the stronger UV wavelengths during the summer months.

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So the evidence suggests that sunlight might not be the bad guy, after all, we just need to develop a better understanding of how sunlight affects our bodies, and how to harness its potential to improve our health.

The Benefits of Receiving Sunlight

Our retinas are connected directly to the suprachiasmatic nuclei of the hypothalamus gland, which acts as the master circadian pacemaker of the body. Because of this, light received through your eyes plays a critical role in hormonal functions including melatonin production, which regulates our sleep. Quite literally, your body knows to shut off this hormone through exposure to morning sunlight. This type of exposure early in the day also helps produce melatonin later in the evening, when light is absent. Even more amazing, the hypothalamus gland, which is controlled by light, is responsible for controlling body temperature, thirst, hunger, and emotional activity — in addition to regulating your hormones and circadian rhythm!

Dopamine is another chemical that is regulated by light and released in the brain. It functions as a neurotransmitter and is closely tied to the emotions of reward and pleasure. In fact, many addictive drugs increase dopamine neuronal activity. Not surprisingly, studies have demonstrated that light exposure is tied to increased dopamine production. So it’s clear that light received through our eyes plays a much more powerful role than most of us realize.

How You Can Benefit from More Light

Getting as much natural sunlight as possible is clearly important. For example, receiving morning sunlight correctly sets your circadian rhythm. However, nowadays, most of us find it challenging to spend hours in the sun — at the right time of day — on a regular basis. Our busy schedules just don’t allow for more time in the sun. In fact, it’s estimated that Americans spend more than 90% of their time indoors.

Because this is the case for most of us, a great way to receive the healthy wavelengths of light is by using a light therapy device. One way to think of red light therapy is as a supplement for your health. Dietary supplements help fill out the vitamins your body needs, and regular red light therapy sessions help fill in the lack of natural light our bodies need.

There are many proven benefits of receiving certain wavelengths of natural sunlight directly through our skin and bodily tissues. One aspect that has received little attention is related to the cellular processes affected by certain wavelengths of light.

Researchers in the field of light therapy, or photobiomodulation (PBM), have discovered some incredibly powerful functions derived from wavelengths of light in the optimal window. Improved mitochondrial function, which impacts virtually all cellular metabolic activity, has been widely demonstrated to improve health in a number of ways — including enhanced muscle recovery, reduced inflammation, increased testosterone, and better overall skin health.

In addition to these clinically-proven benefits, several studies have demonstrated that certain wavelengths of light can increase blood flow and assist in the formation of new capillaries. Dr. Gerald Pollack explores this concept in more detail in his award-winning book, The Fourth Phase of Water.

In conclusion, scientists are really just beginning to understand the crucial role that light plays in our overall health. But recent evidence strongly suggests that exposing our bodies to the right kind of light can lead to some wonderful benefits.

Scientific Sources and Medical References:

‍https://www.mcgill.ca/library/files/library/osler-ourfriendsun.pdf.

Sunscreen-Market-Analysis.pdf.

Berwick, M., et al. Sun Exposure and Mortality From Melanoma. J Natl Cancer Inst. 2005 Feb 2;97(3):195–9.

van der Rhee H, Coebergh JW, de Vries E. Sunlight, vitamin D and the prevention of cancer: a systematic review of epidemiological studies. Eur J Cancer Prev. 2009 Nov;18(6):458–75.

Avci, P, et. al. Low-level (light) therapy (LLLT) in skin: stimulating, healing, restoring. Semin Cutan Med Surg. 2013 Mar;32(1):41–52.

Cawley, EI, et al. Dopamine and light: dissecting effects on mood and motivational states in women with subsyndromal seasonal affective disorder. J Psychiatry Neurosci. 2013 Nov;38(6):388–97.

Ihsan FR. Low-level laser therapy accelerates collateral circulation and enhances microcirculation. Photomed Laser Surg. 2005 Jun;23(3):289–94.

Klepeis NE, Nelson WC, Ott WR, et al. The National Human Activity Pattern Survey (NHAPS): a resource for assessing exposure to environmental pollutants. J Expo Anal Environ Epidemiol. 2001 May-Jun;11(3):231–52.

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