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Fringe “Essentials” Supplements
At Fringe, we believe that foundational health starts with giving your body what it needs to function every single day. That's why we created our Essentials line: three core supplements that we think most people should take on most days. The fringe essentials Line These include: Vitamin D & K Mix – for bone, immune, and cardiovascular health. Magnesium Mix – to support over 800 enzymatic processes in the body. Electrolyte + Mineral Mix – to replenish the vital nutrients missing from modern water. Each was chosen not because they’re trendy, but because they fill real gaps created by how we live today — from sun avoidance to soil depletion to water purification. Here’s Why These Three Have Earned Their Place in Our Essentials Line 1. The Vitamin D & K Combo: A Vital Synergy The Widespread Problem of Vitamin D DeficiencyDespite being called the "sunshine vitamin," most people today don’t get enough vitamin D — especially in North America, where long winters, sunscreen use, and indoor living are the norm. Over 90% of Americans don’t get enough vitamin D from their diets, making supplements essential to raise vitamin D levels when sun exposure is inadequate. Why does this matter? Vitamin D plays a crucial role in: Calcium absorption Bone mineralization and remodeling Immune function, including pathogen defense and inflammation control Mood regulation and brain health But supplementing with Vitamin D alone isn’t enough. How your body uses that calcium matters too.Vitamin K: Vitamin D’s Partner in Calcium TransportVitamin K (especially MK-7, the most bioavailable form of vitamin K2) acts like a traffic director for calcium, whose absorption from the intestines is regulated by vitamin D. It activates proteins that help shuttle calcium into bones and teeth (where it belongs), and away from soft tissues like arteries (where it absolutely does not belong).Without adequate vitamin K, high vitamin D and calcium levels could contribute to arterial calcification and cardiovascular issues. That’s why we combine Vitamin D3 and K2 (MK-7) in our Fringe Vitamin D & K Mix.In short: Vitamin D helps you absorb calcium. Vitamin K makes sure it goes to the right places. 2. Magnesium: The Mineral You're Probably Not Getting Enough Of Magnesium is involved as a cofactor or activator in more than 800 enzymatic reactions in the body — everything from energy production and muscle function to blood sugar regulation and stress modulation.Yet it’s one of the most commonly deficient nutrients, with over 50% of adults falling short of the Recommended Dietary Allowance (RDA). Why Is Magnesium Deficiency So Common? Modern agriculture has depleted our soil of magnesium, so plants (and animals that eat them) contain less. Processed foods — which make up the bulk of the modern diet — are stripped of minerals. Stress, caffeine, alcohol, certain medications, and sugar all increase magnesium excretion. Most multivitamins either lack magnesium or contain forms with poor absorption. Even people trying to eat a whole-foods, nutrient-dense diet may struggle to get enough, especially if they have higher needs due to exercise, stress, or underlying conditions.What Magnesium Supports: Nervous system regulation and resilience to stress Muscle relaxation and prevention of cramps or twitching Heart rhythm stability Sleep quality and circadian rhythm regulation Blood sugar control Bone strength (working hand-in-hand with Vitamin D) Fringe Magnesium Mix is formulated with bioavailable forms (including glycinate, orotate, and malate), making it gentle on digestion and effective at raising magnesium in the body.In short: If you’re not actively supplementing with magnesium, there’s a good chance you’re not getting enough. 3. Electrolyte + Mineral Mix: What Water Is Missing Most people think of electrolytes only when they’re sweating — but these charged minerals are always working behind the scenes to keep your body in balance. What Are Electrolytes? Electrolytes are minerals that carry an electric charge. They’re critical for: Hydration Muscle contractions (including your heart) Nerve signaling pH balance Nutrient transport in and out of cells The key players include sodium, potassium, magnesium, calcium, and chloride.The Hidden Problem: Modern Water Is Mineral-EmptyOur ancestors drank natural water from springs and rivers — water that picked up minerals as it flowed over rocks and through earth. This water was a meaningful source of nutrients, especially calcium and magnesium.Today, most of us drink filtered, distilled, or reverse-osmosis water. While necessary to remove contaminants like lead, arsenic, or chlorine, these processes also remove beneficial minerals.According to the World Health Organization (WHO), natural water can contribute 1% to 20% of daily intake for key minerals. Removing them leaves us not only with nutrient gaps, but with “hungry” water that can actually pull minerals from the body.Filtered water has been linked to: Increased mineral losses in urine, sweat, and feces Reduced hydration (water is less retained) Impaired electrolyte homeostasis Why Supplementing Electrolytes Daily Makes SenseFringe Electrolyte + Mineral Mix is formulated to: Re-mineralize filtered or RO water Restore hydration balance Support energy production and exercise recovery Replenish electrolytes lost via sweat, urination, or stress Help offset mineral-poor modern diets It's a simple, effective way to bring your drinking water closer to what nature intended.In short: Supplementing with electrolytes daily helps restore the essential minerals missing from modern, filtered water — supporting hydration; energy, nerve and muscle function; and overall mineral balance. Why We Chose These 3 as Our Essentials You might be wondering: Why these three? Why not include more? Here’s what makes them “Essential”: They’re fundamental – They address chronic, widespread deficiencies They're backed by science - There are decades of research supporting their safety and benefits They’re difficult to get from nature in our modern world – Because of depletion of soil, water, and our indoor lifestyles, the nature-based sources of these nutrients are hard to access. They’re interconnected – Magnesium and Vitamin D work together; electrolytes and magnesium support hydration and muscle function; and vitamin K2 ensures D3 doesn’t misplace calcium. It’s true that some people would benefit from taking additional supplements. But these are the three that most people need most often. Our future plans include developing supplements for special populations, but we’re committed to always being transparent about who would (and would not) benefit from taking them. Our primary goal isn’t to sell products – it’s to educate, support, and empower people to enjoy optimal health as naturally as possible What Makes Fringe “Essentials” Supplements Unique? There are a lot of supplements out there. So, what makes Fringe’s Essentials line stand out? Here’s what sets our Essentials apart: Better Forms of Nutrients – Backed by Science + Vegan Vitamin D3 Unlike most D3 supplements sourced from lanolin (derived from sheep’s wool), ours is 100% vegan, derived from sustainable lichen. + MK-7 Vitamin K2 We use the most bioavailable, long-acting form of Vitamin K2, shown to stay active in the body for up to 48 hours and effectively direct calcium into bones and away from arteries. + Water-Soluble DK Formula Most fat-soluble vitamins are difficult to absorb without food. Our DK is designed for optimal absorption even without fat in a meal, supporting consistency and convenience. + Three Forms of Magnesium Our Magnesium Mix contains a thoughtful blend of magnesium glycinate, malate, and orotate — three highly bioavailable forms that are gentle on digestion and support energy, calm, muscle, and cardiovascular health. + Electrolytes + Trace Minerals Our Electrolyte & Mineral Mix includes a broad spectrum of trace minerals, not just sodium and potassium. Supporting everything from thyroid health to enzymatic function and mimic the natural balance found in spring water. Clean Formulations We skip all the unnecessary extras found in most supplements: No natural flavors No stevia or artificial sweeteners No sugar No gums or thickeners No unnecessary fillers No soy, dairy, or gluten Our belief is simple: If your body doesn’t need it, it doesn’t belong in your supplement. Our Small Scoops Mission One of our core values is helping people feel better, without overwhelming them with capsules or giant scoops. That’s why we’ve committed to our Small Scoops Mission.We formulate our powders to be low in volume and high in impact, so they can easily be mixed into water, added to a smoothie, or even mixed into foods. No giant tubs or 4-pills-a-day protocols. Just what your body needs, in a form you’ll actually want to use. Final Thoughts Health doesn't have to be complicated. Sometimes, it’s about giving your body the basic building blocks it needs with consistency.Fringe’s Essentials line isn’t about treating symptoms. It’s about supporting your body’s capacity to thrive by filling in modern-day nutrient gaps with the most foundational support we can offer.Because sometimes, feeling better starts with getting back to what’s essential.
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Red Light Therapy & Traumatic Brain Injury
What is Traumatic Brain Injury? Traumatic Brain Injury (TBI) occurs when the brain is damaged by an external force, like an impact, blast, or rapid acceleration/deceleration. Common causes of TBI include falls, sports injuries, vehicle accidents, and physical assaults. Damage from TBI’s can lead to long-lasting and even permanent impairment of brain function. TBI’s are common injuries in the US, with approximately 1.5 million Americans experiencing a TBI annually. TBI is considered an umbrella term that refers to any brain injury caused by an external source. TBI’s can be categorized by severity, ranging from mild to severe, and have unique characteristics: Mild TBI – Causes temporary confusion and headache. Moderate TBI – Causes prolonged confusion and cognitive impairment. Severe TBI – Causes significant cognitive deficits and long-term complications. TBI’s can also be categorized by timeframe, including both acute (short-term) and chronic (long-term) effects. The acute phase last from hours to weeks, while the chronic phase lasts from weeks to years, depending on the severity of the TBI. Two TBI-related terms that may be familiar to people are concussions and Chronic Traumatic Encephalopathy (CTE). Concussions are a type of mild TBI, and although symptoms usually resolve within days to weeks, they can still have long-term effects, especially with multiple incidents. One potential long-term consequence of repeated concussions is CTE, a progressive neurodegenerative disease believed to be caused by repeated head injuries, including multiple mild TBIs. Treatment for TBI varies greatly depending on the severity of the injury. In general, it involves stabilization, symptom management, and rehabilitation. The primary goal of treatment during the acute phase is to protect brain tissue and focuses on cognitive rest and addressing symptoms. In the chronic phase, the primary goal of treatment is to restore cognitive, motor, and emotional function. Emerging treatments such as Red Light Therapy may be beneficial in supporting the brain during both the acute and Shop Red Light Therapy Head Wrap How does TBI affect the Brain Before we consider how Red Light Therapy may be used to support brain health following TBI, let’s take a closer look at the three major pathological processes that occur in the brain during this type of injury. Neuroinflammation: TBI causes neuroinflammation, which occurs in the hours to days following the injury. Neuroinflammation is inflammation of the brain, which can be helpful in the short term but is harmful when prolonged, leading to chronic neurodegeneration. Excess neuroinflammation is linked to brain fog, mood disorders, and an increased risk of neurodegenerative diseases such as CTE. Oxidative stress: Following a TBI, the brain produces excessive amount of reactive oxygen species (ROS), which can lead to oxidative stress. Oxidative stress can overwhelm our antioxidant defenses and cause damage to cells in the brain, worsening brain injury. Impaired brain energy metabolism: TBI impairs brain energy metabolism, particularly the ability of the brain to use glucose, which leads to a metabolic crisis where neurons are deprived of energy. After an initial phase of excessive glucose use, there is a decrease in glucose availability that can last from days to weeks, which makes neurons more vulnerable to damage and impairs healing. These three factors interact and include many overlapping molecules. For example, both neuroinflammation and impaired brain energy metabolism can lead to an increase in ROS production, further worsening oxidative stress. Similarly, impaired energy metabolism exacerbates neuroinflammation. This creates a self-perpetuating cycle of damage, which is why TBI recovery can be slow and why some people experience persistent symptoms for weeks, months, or even years following the injury. How does Red Light Therapy support brain function? Red Light Therapy is a promising tool for supporting the brain during TBI because it targets all three foundational brain pathologies, including neuroinflammation, oxidative stress, and impaired brain energy metabolism. Using both red and near infrared light (especially near infrared, which has deeper penetration), Red Light Therapy delivers wavelengths that interact with light sensitive molecules inside brain cells. Here's how Red Light Therapy affects neuroinflammation, oxidative stress, and brain energy metabolism: Neuroinflammation: Red and near infrared light wavelengths have anti-inflammatory effects, and unlike anti-inflammatory medications (such as NSAID’s), do not cause side effects. Studies have found that light therapy affects levels of many molecules involved in inflammation, including ROS, reactive nitrogen species, and prostaglandins. Red and near infrared light therapy have specifically shown to reduce neuroinflammation. Oxidative stress: Light is absorbed in cells by molecules called chromophores, many of which are found inside the mitochondria. Mitochondria are involved in regulating the production the ROS that cause oxidative stress when present in high amounts. Light therapy has been shown to modulate oxidative stress and ROS production. Impaired brain energy metabolism: Through its impact on mitochondria, light also affects metabolism. In addition to regulating ROS production, mitochondria also make ATP, which is the energy currency of the cell, via a chain of molecules that includes cytochrome c oxidase. Cytochrome c oxidase is activated by both red and near infrared light, which increases ATP synthesis and provides more energy to brain cells. As well, there are additional effects of Red Light Therapy in the brain that may help to support healing from TBI. This includes increasing brain blood flow, supporting brain adaptability, and regulating neuron cell death. Collectively, there are many ways in which Red Light Therapy may be used therapeutically in TBI, and these have been explored in several clinical and pre-clinical studies of both acute and chronic TBI. Is there evidence to support the use of Red Light Therapy in TBI? Yes! Red Light Therapy has been investigated in several studies of TBI using a range of different experimental approaches. These studies can be broken down by timeframe into both acute and chronic TBI, as well as by study type, including clinical (using humans as subjects) and pre-clinical (using animals as subjects). Acute TBI The acute phase of TBI immediately follows the onset of injury. Unfortunately, this creates some challenge in coordinating and executing research studies, since it is difficult to recruit human subjects into a research study who have just experienced a head injury. As a result, most of the research in this TBI phase has been done using animals given a head injury in a controlled environment. In a 2023 systematic review of 17 animal studies that used Red Light Therapy immediately post-TBI, it was found that early light therapy intervention could improve neurological outcomes and reduce the size of trauma-associated brain lesions. Optimal results were associated with both red and near infrared light, initiation within 4 hours post-injury, and up to three daily treatments. One human study was included in the review of Red Light Therapy for acute TBI, which suggested safety and feasibility, but treatment efficacy could not be determined. Chronic TBI Many more human studies have explored the use of Red Light Therapy in the chronic phase of TBI, which occurs weeks to months after the initial trauma. In a 2024 review of 16 human studies, overall improvements in neuropsychological outcomes and increased cerebral blood flow following transcranial PBM were observed. Here are some highlights of the clinical research findings: How can I use Red Light Therapy in TBI? 2019 study of 12 military veterans with chronic TBI lasting more than 18 months – Following six weeks of application of both red and near infrared light to the head using LED lights, neuropsychological scores and brain blood flow were improved. 2020 case report of 23-year professional hockey player with a history of concussions, and symptoms of headaches, mild anxiety, and difficulty concentrating - Following 8 weeks of application of near infrared light to the head using LED lights, many positive findings were observed, including increased brain volume, improved brain connectivity, increased brain blood flow, and improved neuropsychological test scores. 2023 study of four retired professional football players with suspected CTE – Following application of near infrared light to the head using LED lights three times per week for six weeks, a wide range of improvements were noted, including improved sleep, reduced depression, decreased PTSD, and decreased pain. Analysis of brain function showed several improvements. Collectively, research looking at the use of Red Light Therapy to support healing from TBI has yielded positive outcomes, both subjective (such as improved mood and decreased pain), and objective (such as increased brain volume and blood flow). There is stronger support for the use of Red Light Therapy in chronic TBI, but pre-clinical evidence supports the potential for benefit during the acute phase of injury. TBI Recovery Managing TBI involves a combination of stabilization, symptom relief, and rehabilitation, each playing a crucial role in recovery. Red Light Therapy is a safe and effective tool that can support healing throughout all three stages. While it can be conveniently done at home using a Red Light Therapy device, professional supervision is recommended during the acute phase to ensure safe and effective application. When exploring the range of available options, here are four things to consider: Light wavelength – The wavelength of light determines its color, with red light in the range of 620-700nm and near infrared light in the range of 700-1100nm. Although near infrared has been used most often to support healing from TBI, some studies have also found benefit from red light. Light with wavelengths between 600 and 1300nm have been found to penetrate maximally into the brain. So, look for products that provide both RL and NIRL in combination. Light intensity - Light intensity refers to the amount of light being delivered by a device, also referred to as power density. Studies of Red Light Therapy and TBI have used a range of intensities, from 10-100mW/cm2, and there is no clear indication that a particular intensity must be used. Devices across a range of intensities may provide benefit, and consumers aren’t limited to a specific intensity range. Type of device - Your personal level of comfort with a device is important. If it isn’t easy to use, and if it doesn’t feel good on your body, you probably won’t use it consistently. Many consumers find the most convenient devices to use are wireless, with a rechargeable battery. It is also important to use a device that can be adjusted to fit snugly on the head. Think about your personal preferences and choose a device that fits your criteria. Light Source - Light therapy is administered using either laser or LED lights. While early light therapy research was done using lasers, LED lights have become much more popular over the last decade. For at home use, look for a device that uses LED lights as safe and affordable option. The next step after selecting a Red Light Therapy device is to determine the treatment protocol. During the acute phase of TBI, it is recommended to consult with your health care provider to get their professional guidance regarding the most appropriate protocol for your case. During the chronic phase of TBI, support from a health care professional is also recommended, but people may be more independent during this period. Based on available clinical research, 10-40 minute treatment sessions, 3 to 5 times a week, are recommended. Do not exceed more than one session every 24 hours. Conclusion Red Light Therapy is a safe, affordable, and highly effective tool for supporting at-home recovery from TBI. By targeting the three core drivers of brain injury—oxidative stress, impaired metabolism, and neuroinflammation—it offers a scientifically backed approach to healing. Research suggests benefits across all stages of TBI, from the critical early hours to years post-injury. When choosing a device, look for red and near-infrared LED technology that aligns with your needs for comfort and convenience, empowering you to take an active role in your recovery. Shop Red Light Therapy Head Wrap For more information about Fringe light products, go to: https://fringeheals.com/shop-all-products/
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Red Light Therapy for Seasonal Affective Disorder
What is Seasonal Affective Disorder (SAD)? Seasonal Affective Disorder (SAD) is also known as the “winter blues” or “seasonal depression”. In the simplest terms, it is depression that follows a season pattern, usually occurring in the winter. SAD is considered a variant of Major Depressive Disorder or Bipolar Disorder, rather than a distinct condition. It is recognized in the Diagnostic Manual of Mental Disorders (DSM-5) and affects around 5% of US adults. January and February are the hardest months for people with SAD. The symptoms of SAD are similar to the symptoms of non-SAD depression, and include: feeling sad fatigue and loss of energy loss in interest or pleasure in activities changes in appetite and sleep (especially overeating and oversleeping) feeling worthless or guilty difficulty thinking, concentrating, or making decisions physical aches and pains thoughts of death or suicide. SAD occurs at a specific time of year and the diagnosis requires that it recurs at least two consecutive years in the same season. Symptoms last for around 4 to 5 months, and there is full remission of symptoms when the season ends. SAD usually occurs in the Fall or Winter. Risk factors for SAD include being female, living at a northern latitude, a family history of SAD, and being between 18 and 30 years of age. Both pharmacological and non-pharmacological treatments have been identified as first line therapies for SAD. Pharmacological treatments include antidepressant medications, such as selective serotonin reuptake inhibitors. Non-pharmacological treatments include cognitive behavioral therapy and light therapy. The goal of light therapy is to compensate for the loss of natural sunlight during the shorter and darker winter months, and most often involves exposure to bright white light. What is the relationship between light and SAD? The seasonal nature of SAD and its high prevalence during the winter months, along with resolution during warmer, sunnier seasons, suggests a causal relationship with sun and light exposure. Human biology is clearly linked with the rhythm of the sun, with people naturally following a sleep/wake cycle that is associated with night and day. This sleep/wake cycle is also known as our circadian rhythm. Circadian rhythms are the “physical, mental, and behavioral changes an organism experiences over a 24-hr cycle.” In addition to light and dark, circadian rhythms are also influenced by temperature, diet, exercise, stress, and social environment. Light, however, is the primary regulator, and it exerts this influence through effects on the brain. The influence of light on the brain starts with the eyes. Light enters the retina and activates cells called intrinsically photosensitive retinal ganglion cells. Retinal ganglion cells are active even in people who are completely blind, who show similar sleep and wake cycles to sighted people because of the response of these cells to light. Retinal ganglion cells show their greatest response to the blue light spectrum. Sunlight contains blue light, in addition to many other wavelengths of color. From the eyes, a signal is sent to the suprachiasmatic nucleus in the brain. Known as the “master circadian clock”, the suprachiasmatic nucleus is the most important circadian regulator. The clock in turn sends out many signals that regulate a wide range of processes in the body, including controlling the expression of up to 10% of our genes. Light is the primary regulator of this internal clock, although there are other non-light influences on this rhythm too. Melatonin and cortisol are the main hormonal mediators of the circadian rhythm, and the synthesis of both is regulated by light. Melatonin is secreted in response to the absence of light, triggering sleep. Cortisol is secreted in response to the presence of light, triggering wakefulness. The synthesis of both melatonin and cortisol is controlled by signals that come from the suprachiasmatic nucleus. In the winter months, decreased exposure to light causes the circadian rhythm to shift later in the day, which results in a misalignment between the sleep-wake cycle and the circadian rhythms’ natural processes. Exposure to certain types of light on winter mornings pulls the circadian rhythm back into alignment. Different types of light are known to have variable effects on the circadian rhythm. Both bright white and blue light suppress the release of melatonin, which promotes wakefulness. Blue light exposure can cause the circadian rhythm to shift even when applied later in the day, unlike bright white light which is more effective at causing a shift in the morning. Red light does not suppress melatonin levels or cause the circadian rhythm to shift. These variable effects of different wavelengths (colors) of light have important implications for light therapy, which is the application of external light sources to affect biology. Exposure to light has been clearly shown to be associated with mood. A study of over 400,000 people showed that increasing exposure to daylight associated with reduced risk of major depression and greater happiness. This may be mediated by serotonin, which is known as a “natural mood booster”. Serotonin is a critical link and regulator of both the circadian rhythm and mood, and levels increase with sun exposure. In contrast to the positive mood effects of sunlight exposure, exposure to artificial light later in the day can have adverse effects. In simple terms, the naturally stimulating effect of white and blue light on wakefulness is helpful in the early part of the day but is harmful in the evening and at night. The associations between light and levels of melatonin, cortisol, and serotonin provide clues as to how the dark, short days of winter can negatively impact mood. And while more research is needed to clearly understand the pathology of SAD, its positive response to light therapy suggest that light is one of the most important mediators. How is red light therapy for Seasonal Affective Disorder used? Light therapy is widely accepted as a first line non-pharmacological treatment for SAD. Usually, this involves treatment with bright light (called Bright Light Therapy, BLT), but dawn simulation is also used. Dawn simulation delivers light that gradually increases during the last half hour of sleep, while BLT delivers very bright light (most often white, but sometimes blue) shortly after waking. Bright light therapy has been shown to be more effective for people with more severe depression, but both are beneficial. As already described, retinal ganglion cells in the eye respond to light, particularly in the blue spectrum. White light contains all visible light frequencies, including blue, and both white and blue light promote wakefulness, in part through suppression of melatonin. This is why white and blue light are the main sources of light used in SAD light therapy. Light intensity is measured in Lux, and bright light is typically considered to be at least 10,000 Lux. Light intensity varies greatly, sometimes in surprising ways. Here are some light intensities under different conditions: Bright sunlight = 120,000 Lux Bright sunlight = 110,000 Lux Shaded area on a sunny day = 20,000 Lux Overcast day, midday = 1,000 – 2,000 Lux Sunrise/Sunset (clear day) = 400 Lux Sunrise/Sunset (overcast) = 40 Lux Moonlight (clear night) = 1 Lux Office lighting = 200 – 400 Lux Home lighting = 50 – 200 Lux In BLT, an external light source (usually called a “light box”) is used that delivers light at around 10,000 Lux. It is recommended to use BLT in the early morning shortly after waking for approximately 30 minutes. The person should position themself 60-80cm from the light box, with the light at eye level. Lower intensity light can be used (2,500 - 5,000 Lux) but with lower intensity light the treatment duration is extended to 1 to 2 hours. Treatment should be done until the season ends. Light used in BLT will be delivered by either fluorescent or LED lights. Fluorescent lights deliver white light, either warm or cool, while LED lights can deliver both white and blue light. White light is referred to as “colorless daylight” and is made up of all the frequencies in the visible light spectrum (including red, yellow, green, blue, etc.). White fluorescent bulbs and LED lights will also contain all of the visible light frequencies but they can vary in their spectral characteristics, such as the particular wavelength distribution and intensity. When the spectrum of light from bright light devices is analyzed, it varies depending on the light source. Fluorescent lights, both warm and cool, emit light that shows several peaks that correspond to different colors, including red. White LED diodes usually have a sharp blue peak, but they also contain wavelengths of different colors. The main difference between white and blue BLT devices is that white light contains multiple colors (called polychromatic), even though it appears white or colorless, while blue light is a singular color (called monochromatic). It is sometimes claimed that SAD light boxes provide a “hefty dose” of blue light. This is not entirely true. The spectral analysis of devices that use both warm and cool fluorescent lights reveals a mixture of wavelengths (yes, including blue), but their calculated “blue light hazard” level is actually quite low. Warm fluorescent light is a bit better than cool fluorescent light, which showed around the same blue light hazard as white LED light. It’s also important to note that blue light is “disruptive” to the circadian rhythm precisely because our bodies are naturally designed to respond to the blue wavelengths of light from the sun. When used in the morning, exposure to blue light (even artificial) provides a cue for the system to wake up. It should go without saying that bright light therapy devices should not be used in the evening. BLT has been found to effectively reduce the symptoms of SAD, although white light shows more effectiveness than blue light. A meta-analysis published in 2015 found that bright white light therapy was effective, although the effects were weaker at some time points. A meta-analysis of bright blue light therapy for SAD did not find it to be beneficial. How Does Seasonal Affective Disorder Relate to Different Wavelengths of Light? SAD is related to the lack of daylight, or sunlight, during winter months. Sunlight consists of solar radiation, which is energy that is transmitted in the form of waves or particles. The spectrum of light in our environment consists of both light we can see (visible light) and light that our eyes can’t perceive (invisible light). This is called the electromagnetic spectrum. The visible light spectrum is quite narrow, consisting of wavelengths that range from 400 to 700nm and span from violet to red in color. Although the amount of solar radiation is not constant, approximately 40% percent of the light from the sun is visible light, which can be divided by color and wavelength. Near infrared light waves lie just beyond the “red” end of the visible light spectrum, so we don’t see them. Near infrared light is part of the “infrared” spectrum, which consists of both near infrared and far infrared light. Infrared light makes up 50% of the solar radiation that reaches the earth. The remaining 10% of the light from the sun is also invisible, falling just beyond the opposite “violet” end of the visible spectrum to IR. This is called ultraviolet light (UVL). What this means is that BLT only partly mimics the natural effects of sunlight, since it delivers only visible light. Bright white light does not include light in the UV spectrum of the sun. This is done intentionally, since UV rays are the component of solar radiation that are the main culprits in causing skin cancer. Bright white light also does not include light in the infrared spectrum of the sun. This omission is less justified, since infrared light does not have harmful effects on the skin (quite the opposite, in fact), and infrared light makes up a significant amount of natural sunlight. BLT that uses blue light excludes not only UV and infrared light but also the non-blue wavelengths of light, including red, orange, yellow, green and violet. Does Red Light Therapy Improve Seasonal Affective Disorder? Red and near infrared light therapy is the application of artificially generated light in the red and near infrared spectral bands. The term “red light therapy” usually describes the use of both red and near infrared light, although only the red light produced by the device is visible to the naked eye. Infrared light can still be perceived by the body as heat when it contacts skin. Like BLT, red and near infrared light therapy does not involve the use of UV rays. The red light used in light therapy usually ranges from 600 to 700 nanometres (nm), with the unit nm referring to distance the light wave travels in one cycle. The near infrared light used in light therapy usually ranges from 800 to 1100nm. Interestingly, there are no clinical trials of red light therapy to treat SAD, but there are many that have been done looking at the effects of red light on non-SAD depression. All of the non-SAD clinical trials of red light therapy used near infrared light applied directly to the head. A 2022 systematic review concluded that near infrared light therapy “can be classified as strongly recommended for moderate grade of major depressive disorder”. Similarly, a 2023 meta-analysis concluded that there is a “promising role of in the treatment of depressive symptoms”. These results demonstrate that red light therapy has positive effects on mood. Another challenging symptom of SAD is sleep disturbance, which is another issue that red light therapy has been found to help. Application of red light therapy during wakefulness improves sleep quality in people with cognitive decline, Guillain-Barré Syndrome, fibromyalgia and stroke. Interestingly, sleep duration decreased with full body red light therapy in elite athletes, while other parameters such as exercise recovery improved. When red light therapy is applied during sleep, there is an increased clearance of waste products from the brain and improved flow of cerebrospinal fluid, which are required for optimal brain health. So, red light therapy is beneficial when applied when either awake or sleeping, and the benefits relate more to improving sleep quality and physiology, rather than to increasing sleep duration. As already described, increased exposure to outdoor light is associated with reduced risk of major depression and greater happiness. Since outdoor light is a combination of visible light (including blue and red), infrared, and UV light, this contrasts with the light used in BLT, which includes only white visible light or blue monochromatic light. With so many studies showing a benefit to using red light therapy (especially infrared light), it is possible that the addition of red light in the treatment of SAD could be beneficial. Combining Bright and Red Light Therapy to Improve Seasonal Affective Disorder Red light therapy can easily be combined with BLT in the treatment of Seasonal Affective Disorder. Since the rising sun appears red when first coming up over the horizon, exposure to red light followed by exposure to BLT is recommended. This is a practice that I’ve been doing for several years, following decades of winter seasons in which I suffered from some degree of seasonal depression. Initially, my doctor recommended that I purchase a fluorescent light box, which I used successfully for a few years. After gaining knowledge of red light therapy, I combined the two and now use them in tandem. My recommended practice is as follows: Shortly after waking, use a red light therapy panel (that delivers both red and near infrared light) for 10 minutes, sitting comfortably 6 to 12 inches away. If you prefer, or if it’s uncomfortable to keep your eyes open in front of the red light panel, you can close them – light still penetrates through to the retinal ganglion cells. However, it is safe to open your eyes as long as your red light panel is low to moderate intensity. The 10 minutes spent in front of the red light panel provides a great opportunity to work on breathwork or mindfulness, which have positive effects on mood. After 10 minutes of red light therapy, use a light box that delivers white light (preferably using warm fluorescent bulbs, which have a lower blue light hazard ratio) for 20 minutes. It is possible to do normal activities while in front of the light box, so people usually set them up in an office (so that they can work on a computer or read) or on a kitchen island. I recommend setting it up in an office space and spending that 20 minutes engaged in an activity that generates a positive mood. For most people, this means avoiding reading the news, but you can do things like sending emails to friends or reading something uplifting. Taking time to be calm and to orient your attention in a positive direction uplifts mood. Avoid bright light, especially blue light, at night. Exposure to blue light (especially bright blue light) is disruptive to sleep, which is why it is not recommended to use electronic devices (like iPads or e-readers) that emit blue light at night. Keep household lighting dim in the evening and at night. Red light therapy may also be used at night, although you should position yourself farther from the panel so that the light is less intense. Red light panels can even be used as a source of evening/nighttime illumination. Red LED light bulbs may also be used as a source of illumination at night. Conclusion We often hear the recommendation by health experts these days to “view morning sun” as a way to optimize health, including mental health. While it is no doubt ideal to have exposure to natural light in the morning, for people that live in cold winter climates this can be very difficult. Under these circumstances, light devices – both bright and red light - can be used to mimic sunrise and sun exposure. Although the combination of bright and red/near infrared light has yet to be subject to intensive research, there is strong evidence that both exert a positive influence on mood. Since daylight consists of a combination of light wavelengths, including near infrared light, there is good reason to believe that these two may work in tandem as a powerful tool in the prevention and treatment of Seasonal Affective Disorder. For more information about Fringe light products, go to: https://fringeheals.com/shop-all-products/
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