By the second trimester, long before a baby's eyes can see images, they can detect light.
But the light-sensitive cells in the developing retina -- the thin sheet of brain-like tissue at the back of the eye -- were thought to be simple on-off switches, presumably there to set up the 24-hour, day-night rhythms parents hope their baby will follow. University of California, Berkeley, scientists have now found evidence that these simple cells actually talk to one another as part of an interconnected network that gives the retina more light sensitivity than once thought, and that may enhance the influence of light on behavior and brain development in unsuspected ways.
In the developing eye, perhaps 3% of ganglion cells -- the retina cells that send messages through the optic nerve into the brain -- are sensitive to light. To date, researchers have found about six different subtypes that communicate with various places in the brain. Some talk to the suprachiasmatic nucleus to tune our internal clock to the day-night cycle. Others send signals to the area that makes our pupils constrict in bright light.
But others connect to surprising areas: the perihabenula, which regulates mood, and the amygdala, which deals with emotions.
Recent evidence suggests that in mice and monkeys, these ganglion cells also talk with one another through electrical connections called gap junctions, implying much more complexity in immature rodent and primate eyes than imagined.
"Given the variety of these ganglion cells and that they project to many different parts of the brain, it makes me wonder whether they play a role in how the retina connects up to the brain," said Marla Feller, a UC Berkeley professor of molecular and cell biology and senior author of a paper that appeared this month in the journal Current Biology. "Maybe not for visual circuits, but non-vision behaviors. Not only the pupillary light reflex and circadian rhythms, but possibly explaining problems like light-induced migraines, or why light therapy works for depression."
Parallel systems in developing retina
The cells, called intrinsically photosensitive retinal ganglion cells (ipRGCs), were discovered only 10 years ago, surprising those like Feller, who studied the developing retina for nearly 20 years. She played a major role, along with her mentor, Carla Shatz of Stanford University, in showing that spontaneous electrical activity in the eye during development -- so-called retinal waves -- is critical for setting up the correct brain networks to process images later on.
Hence her interest in the ipRGCs seemed to function in parallel with spontaneous retinal waves in the developing retina.
We thought they (mouse pups and the human fetus) were blind at this point in development. We thought that the ganglion cells were there in the developing eye, that they are connected to the brain, but that they were not really connected to much of the rest of the retina, at that point. Now, it turns out they are connected to each other, which was a surprising thing."
Marla Feller, the Paul Licht Distinguished Professor in Biological Sciences and a member of UC Berkeley's Helen Wills Neuroscience Institute.
UC Berkeley graduate student Franklin Caval-Holme combined two-photon calcium imaging, whole-cell electrical recording, pharmacology, and anatomical techniques to show that the six types of ipRGCs in the newborn mouse retina link up electrically, via gap junctions, to form a retinal network that the researchers found not only detect light but respond to the intensity of the light, which can vary nearly a billionfold.
Gap junction circuits were critical for light sensitivity in some ipRGC subtypes. Still, not others, providing a potential avenue to determine which ipRGC subtypes provide the signal for specific non-visual behaviors that light evokes.
"Aversion to light, which pups develop very early, is intensity-dependent," suggesting that these neural circuits could be involved in light-aversion behavior, Caval-Holme said. "We don't know which of these ipRGC subtypes in the neonatal retina actually contributes to the behavior, so it will be fascinating to see what role all these different subtypes have."
The researchers also found evidence that the circuit tunes itself in a way that could adapt to the intensity of light, which probably has an important role in development, Feller said.
"In the past, people demonstrated that these light-sensitive cells are important for things like the development of the blood vessels in the retina and light entrainment of circadian rhythms, but those were kind of a light on/light of the response, where you need some light or no light," she said. "This seems to argue that they are actually trying to code for many different intensities of light, encoding much more information than people had previously thought."
University of California, Berkeley
Caval-Holme, F., et al. (2019) Gap Junction Coupling Shapes the Encoding of Light in the Developing Retina. Current Biology. doi.org/10.1016/j.cub.2019.10.025.
You want your baby to start living healthy and happy. However, things happen, and your baby can potentially become sick. Jaundice is one of the most common conditions that affect newborn babies, and it’s estimated 6 out of every 10 babies develop jaundice.
Jaundice is usually a harmless condition in newborns that causes yellowing of the skin and the whites of the eyes. This condition occurs when there’s a build-up of bilirubin in the blood. Biliburn is a yellow substance produced during the normal breakdown process of the red blood cells. The liver removes bilirubin from the blood in children and adults, passing it through the bowels and exiting the body.
However, a newborn baby’s liver cannot remove bilirubin as easily as an adult. This can create a build-up of bilirubin if the newborn has problems processing it and passing it through the body.
While most jaundice cases go away on their own, some newborns need help to lower bilirubin levels in the body.
Jaundice can occur in a newborn for different reasons:
Doctors can easily spot a baby with jaundice based on the yellowing of the skin and the whites of their eyes. Typically, newborns are checked for jaundice prior to leaving the hospital.
Babies who contract jaundice undergo blood tests to check for bilirubin levels. High levels of bilirubin have the potential to become serious.
Most cases of jaundice disappear within a week or two of treatment. However, some cases are quite serious and need to undergo treatment.
Light treatment aids with eliminating bilirubin in the blood. The baby’s skin absorbs the wavelengths, altering bilirubin which can pass easily through their bowels.
Phototherapy treatment has long been used to treat jaundice, with a row of lights or a spotlight directed at the undressed newborn from a healthy distance. Two soft eye patches are applied over the eyes for protection. Luckily, today’s technology of phototherapy can deliver effective treatment without any of the former inconveniences.
As humans, we are made of energy and fueled by light. While nutrition and exercise play a role in our well-being and health, light plays a crucial role in us functioning optimally. New and groundbreaking research is unearthing a new understanding of how our cells function and the evidence points to the power of light.
Through technological advancements in science, it’s discovered that our bodies operate similar to a battery. Wavelengths of light give us power, while our overall health determines our ability to receive and maintain the energy from light. And this is where light therapy comes into the equation.
Science has proven that our bodies interact with specific wavelengths that benefit our bodies in various ways.
Red light therapy devices, such as light therapy masks, shine red and near-infrared light onto the skin, stimulating the production of adenosine triphosphate (ATP) within the mitochondria. By stimulating ATP, damaged cells heal, and new cells are produced faster than normal. But we’ll talk more about that in-depth a little later.
Red light therapy comprises both red light and infrared wavelengths, penetrating through the skin’s layers, right into the cells. Red light wavelengths boost collagen and elastin and improve cell communication. It penetrates superficially and helps aid various skin conditions.
Near-infrared wavelengths stimulate healing, increase mitochondrial function, and improve blood flow and tissue oxygenation. Near-infrared wavelengths penetrate deeply into the body.
At the core of your body’s healing capabilities are the mitochondria. The mitochondria play a vital role in your internal organs and tissue, including the liver, skin, heart, and muscles. It’s in charge of the body’s energy supply via ATP (adenosine triphosphate).
With both working together, they provide energy to our body and maintain the cell cycle and growth. This is why you’ll often hear the mitochondria referred to as the “powerhouse of the cell.”
Here's how the mitochondria is affected by red light:
Interestingly, our body weight is made of 70% water, with 99% of our bodies' molecules also made of water, making it a powerful component in red light therapy treatment.
Research by Prof Gerald Pollock of the University of Washington proved that water adjacent to a cell is structured water, also known as EZ water. This specific water forms a separation of charge, functioning in the body as positive and negative poles - similar to a battery.
While we’ve been talking about red light therapy, what does it actually mean? Typically, “red light therapy” refers to natural light treatments which deliver red and near-infrared wavelengths as natural sunlight using LEDs or cold lasers.
While you may think red light therapy includes all colors of light, it doesn’t. The term doesn’t include blue or white light, and it isn’t equivalent to full-spectrum light. Red light therapy doesn’t rely on heat, differentiating it from other light-based treatments such as infrared saunas and heat therapy.
Red light therapy is also known as RLT, photobiomodulation (PBM), phototherapy, LED therapy, LED light therapy, infrared therapy, low-level laser therapy, or low-level light therapy (LLLT).
As stated before, red light therapy works to heal the entire body and functions on multiple levels.
Red light therapy affects the body in multiple ways, including bodily systems:
Fascia
Fascia is the thin casing of connective tissue that surrounds virtually every organ, muscle, nerve fiber, blood vessel, and bone in place. While it performs as an internal structure for your body, the fascia also contains nerves, making it almost as sensitive as skin.
The fascia may look like a layer of tissue; however, it’s made up of interwoven layers of collagen and elastin fibers. The fascia is overlooked, yet over recent years, it has been the key to understanding how changes in one area of our body affect others. Red light therapy works to improve communication within the fascia network.
Gut-Brain Axis
The gut-brain axis connects the emotional and cognitive centers of the brain with peripheral intestinal functions. Recent research discovered the importance of gut microbiota concerning these interactions.
Red light therapy can positively influence mood and neuropsychological issues by the following:
Immune System
Red and near-infrared light penetrate through the skin into the cells, which results in low-dose metabolic stress that strengthens the cells’ anti-inflammatory and natural defense systems. In turn, the body becomes resilient to infections.
Safe and low exposure to red light therapy improves the body’s response to external viruses and bacteria. Red light therapy can influence the immune response in the following ways:
Circulatory System
Red light therapy is scientifically proven to increase the micro-circulation of blood and support the circulatory system as a whole by stimulating the development of new capillaries which carry oxygen throughout the body.
Proper oxygen supply and flow are essential for the proliferation of cells, protein synthesis, tissue restoration, inflammatory response, and angiogenesis. In addition, circulation is also responsible for waste elimination, specifically degenerated cells.
Nervous System
The nervous system includes the brain, spinal cord, neurons, and neural support cells, which is your body’s command center. It controls your movements, automatic responses, and other body systems such as digestion and breathing.
Red light therapy affects the nervous system in the following ways:
For all forms of nerve damage, red light therapy offers non-pharmaceutical treatment options.
Stem Cells
Red light therapy shows impressive results regarding stem cell growth, maximizing the potential of stem cell implantation for various medical needs. Therefore, red light therapy may show positive results after surgery to stimulate stem cells which repair tissues and organs.
In studies, red light therapy has proven to stimulate mesenchymal stem cells in bone marrow, enhancing their ability to reach the brain. This research shows the possibilities of using red light therapy to heal degenerative conditions, including Alzheimer’s, Parkinson’s disease, and dementia.
It’s clear red light therapy provides multilevel treatment to the body, becoming a popular natural and holistic option for both professionals and consumers, but where did it come from?
Light therapy technology isn’t new; it’s been around for decades as NASA experimented with red light therapy during the 1980s and 1990s. Over the past 10-20 years, red light therapy reached a breakthrough in LED lighting technology, allowing the production of safe and affordable clinical and at-home devices.
In 2016, Kaiyan Medical became the first leading manufacturer of red light therapy of affordable FDA-approved and MDASAP-approved light therapy devices.
We mentioned red light therapy being a holistic treatment option, but what does that mean. Holistic medicine is a full-body approach to healthcare. By focusing on the body, mind, and soul, the body receives the full support and care it needs to function optimally.
Principles of Holistic Medicine
Holistic medicine is based on the following principles:
The purpose of treatment is to identify the underlying cause of the disease, rather than treating only the symptoms.
While there are endless benefits the body receives from red light therapy, here are the six main benefits.
Photobiomodulation, in other words, red light therapy, has proven effective against carpal tunnel syndrome, mucositis, neck pain, menstrual cramps, temporomandibular joint pain, and neuropathic pain from amputation. It also significantly reduces the pain of hypersensitivity while improving sensorimotor function.
These improvements come after anti-inflammatory cells populate the injured area, providing long-lasting pain relief. In addition, it’s also been shown to provide effective relief by affecting the following:
Red light therapy has proven to be highly effective in rapidly treating wounds from burns, scars, bedsores, ulcers, surgery incisions, and diabetic neuropathy.
NASA strongly supports this claim as this technology was used in treating wounds. Red and near-infrared light proves effective in all four phases of the wound-healing process:
These processes are regulated by various factors connected via nitric oxide (NO) signaling release, adjusted by light energy.
An issue the body encounters when trying to heal a wound is low oxygen flow, and red light increases the flow of oxygen, speeding up the natural healing process. By reducing inflammation and increasing oxygenation of the wounded area, blood vessels can form, rapidly repairing the area, lessening pain and scarring.
By reducing pain, red light therapy eliminates the reliant on pharmaceutical painkillers during the healing process.
The human body receives energy on the cellular level, maintaining communication between organs and ensuring disease resistance.
A strong immune system works to protect the body from harmful bacteria and viruses at all times. With red light therapy, the body receives a boost of support as it releases nitric oxide and melatonin, two components involved in DNA repair and antimicrobial.
This process is called hormesis. Red and near-infrared wavelengths penetrate through the skin into the cells, causing mild metabolic stress, which stimulates cells to activate their anti-inflammatory and antioxidant response.
With the support of red light therapy, the body is better prepared to fight infections. Numerous studies have proven red light therapy to have the following effects on the immune system:
Inflammation in the body can be acute and topical (short-term, resulting from sprains, infections, and accidents) or chronic and general (long-term, caused by ongoing conditions).
Acute inflammation is a healthy bodily response; however, chronic and general inflammation can negatively impact long-term health.
As of today, the current treatment for inflammation is NSAID or steroid drugs, both having a detrimental effect on the healing process and long-term health. Red light therapy stimulates the body to activate its natural healing mechanism, reducing the health risks of long-term drug use.
Red light therapy decreases the number of inflammatory cells, increases fibroblast proliferation (cells that synthesize collagen and other matrix macromolecules), stimulates angiogenesis (creation of new blood vessels), and activates the body’s anti-inflammatory, antioxidant response.
The following conditions are connected with chronic and acute inflammation, all proving promising results with red light therapy treatment:
Red light therapy is extremely popular in competitive sports and performance. It offers natural and non-pharmaceutical treatment, which applies to many areas of the body.
Aside from the overwhelming benefits on overall health, red light therapy encourages muscles growth and repair by stimulating the production of ATP, which aids in faster recovery and better performance.
Red light therapy used before training prepares and strengthens the body while aiding muscle recovery after training.
Here are the scientifically documented effects of red light therapy:
Seasonal affective disorder (SAD) is a form of depressions, impacting 5% of Americans, specifically during the winter when there’s less natural sunlight. SAD is also known as seasonal depression or winter blues.
Many people treat SAD symptoms via bright white light treatment, mimicking the sun’s light daily. However, researchers recommend natural light treatment, like red light therapy, to help with light deficiency. Over recent years, physicians recommend red light therapy alongside psychotherapy and medication.
While many people are using red light therapy devices for at-home treatment, red light therapy systems are found in many clinical and professional settings:
Skincare Professionals: Red light therapy is a popular skincare treatment among Hollywood celebrities, including Kourtney Kardashian, Julia Roberts, and Emma Stone. Leading skincare professionals like dermatologists and aestheticians use red light therapy to help promote collagen production, reduce wrinkles, and treat skin conditions.
Health Practitioners: Health practitioners from all specialties are incorporating red light therapy into their practice. Dentists use it to reduce inflammation, physicians for mental health conditions, and oncologists for cancer side effects.
Natural Health Experts: Leading voices in the health and wellness industry such as Dr. Sarah Ballantyne, Ben Greenfield, and Dave Asprey strongly support the use of red light therapy. Paleo and Keto health experts like Robb Wolf, Mark Sisson, Luke Story, and Dr. Anthony Gustin also support red light therapy.
Sports Medicine Pros: The National Sports Association of Sports Medicine (NASM) adopted red light therapy to treat sports injuries. Top trainers and doctors, including Dr. Troy Van Biezen and Dr. Ara Suppiah, use red light therapy to heal their athletes.
Elite Pro Athletes: Professional athletes worldwide, including NFL stars like Patrick Peterson, UFC champion Anthony Pettis, and gold medal gymnast Sanne Weavers use red light therapy to enhance performance and quicken recovery.
Fitness & Training: World-renown fitness trainers, including Lacey Stone and Jorge Cruise, use red light therapy to enhance athletic performance and muscle recovery.
Supportive Cancer Care: The Multinational Association of Supportive Care in Cancer (MASCC) recommends the treatment of red light therapy for oral mucositis (OM), a common symptom of cancer treatment.
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If you’re one of the 35 million men or 21 million women in the United States who are losing their hair, you know how hard it can be to slow down getting bald. Creams, pills, and other treatments are often touted as solutions, but even if they do work, they come with side effects. Meanwhile, hair loss takes a tremendous mental toll. Among the most common effects are diminished self-esteem and confidence, as you notice others wearing hairstyles you couldn’t possibly pull off. And while some people rock the bald look, it’s not for every guy suffering from male pattern baldness and it’s rarely an option for women.
If this sounds like you, red light therapy is worth a look. Red light therapy for hair loss is backed by research, is completely natural, and can slow–or in some cases, reverse–hair loss without disruptive side effects. If you’re curious how this is possible, what the most relevant studies say, and–more importantly–if it will work, this article is for you. From cellular growth to the proper how-to steps, read on to uncover how red light can help you get your hair back.
According to the International Society of Hair Restoration Surgery, almost half of men show noticeable hair loss by reading middle age. Surprisingly, the numbers are even higher among women: by the age of 60, nearly 80 percent of women show noticeable hair loss.
So, why do we lose hair? Briefly, losing hair helps us making room for new growth. A typical human will have up to 100,000 hairs on their head, and it’s only normal to lose 50–100 every day. After that, that causes get more complicated.
A few of the most common causes include:
Genetics
The most common cause of hair loss is hereditary hair loss or androgenetic alopecia. Male pattern baldness is characterized by M-shaped hair loss that begins at the temples and a bald spot in the back. It can begin as early as puberty or later in life. Female pattern baldness generally manifests as thinning on the head's top and crown, widening the center part but not affecting the front hairline.
Stress
Both acute and chronic stress contribute to hair loss in men and women. In acute stress, hair loss is often tied to a specific cause such as a sudden loss of a loved one, an accident, illness, or surgery; this hair loss may be temporary. Chronic stress, including job stress, relationship stress, and financial stress, also appears to accelerate hair loss.
Poor Nutrition
Specifically, inadequate protein intake affects hair follicles and contributes to hair loss. While over 40 million Americans are malnourished due to poverty, easy accessibility of junk food means that while many Americans get enough calories in their diets, they do not necessarily get the nutrition they need.
Given the side effects, cost, limited success, and ongoing hassles of these common hair restoration treatments, it makes sense to look at an alternative that is painless, non-invasive, has no side effects, and can actually enhance your health in a variety of different ways at the same time. Red light therapy is that option. Also red light therapy can help improve various other conditions, including joint pain from arthritis, sun damage, and nerve damage, to name a few. In fact, it can even treat one of the root causes of hair loss: thyroid problems.
Red light therapy is a phototherapy that uses specific wavelengths of light to reduce inflammation, accelerate healing, and promote a healthy skin tone. Red light is part of the visible light spectrum (not to be confused with infrared light or ultraviolet light, invisible to the human eye) and is bioactive in humans. This means that our bodies respond to it beneficially in much the same way that plants respond to sunlight: by creating more energy at the cellular level.
Red light (also called low-level light therapy or LLLT) for hair loss was discovered somewhat by accident in the 1960s when mice were given chemotherapy. The chemotherapy-induced hair loss, but when the mice were irradiated with red light, the fur grew back thicker than before. Modern red light therapy works similarly, using high-power LEDs to saturate your body with wavelengths of therapeutic light. It typically uses visible light in various colors, but the red and infrared ranges are best for a wide variety of conditions, including hair loss. While sunlight provides a complete spectrum of wavelengths (including red light), it also contains harmful UVA and UVB wavelengths. Using the red light frequency alone has no side effects, such as burning or skin damage.
Red light is especially effective at treating hair loss; specifically, light in the 620nm (nanometer) to 660nm wavelengths work best. It works by increasing blood flow in the scalp; this stimulates the metabolism in hair follicles, resulting in more hair production.
You lose hair during hair loss but not the follicles–the tube-like formations that anchor hair to the skin. At the base of each follicle is the hair bulb (the whole thing looks somewhat like a tall vase). At the bulbous part of the vase are the papilla and the matrix; this is where hair begins to grow. We see as “hair” mostly a protein called keratin that makes up the hair shaft. When the hair follicles and the papilla and matrix cells are not functioning properly, they cannot support hair growth,, causing it to slow or cease altogether.
Red light penetrates the skin to the base of the hair follicles, stimulating the cells, papilla,, and matrix to produce more energy, which results in these cells replicating more successfully. This replication leads to new hair growth from these previously-dormant follicles. Red light also:
Stimulates Adenosine Triphosphate (ATP) production, a coenzyme responsible for fueling cellular structures. Increases in ATP cause individual cells within the hair follicle to increase their activity, including the rate at which they replicate. Restoring the energy of the hair follicles' cellular structures means the papilla creates more keratin, which results in hair growth.
Increases collagen production. Hair is primarily made up of a protein called keratin. While collagen — another type of protein — isn’t present in hair, it acts as an antioxidant to fight damage caused by free radicals (compounds that develop in the body during stress, environmental pollutants, poor nutrition, etc.). Free radicals damage hair follicles, which contributes to their inability to grow hair. Increased collagen means less oxidative damage, which can lead to increased hair growth.
Increases the creation of new capillaries, which improves blood flow to the scalp and brings oxygen and nutrients to hair follicles,, and removes waste that can lead to hair follicle damage. One study linked improved blood flow to the growth of thicker, healthier hair. Barbers have long encouraged men to massage their scalps to increase blood flow, but increasing blood flow using red light is generally more effective.
It’s important to note that while red light therapy is effective for many types of hair loss (especially alopecia or temporary hair loss due to hormonal imbalances or illness), it’s not effective 100% of the time. For example, hair loss due to chemotherapy will continue until the treatment is stopped. The same applies to hair loss due to the side effects of other medications. Also, any hair follicles that have been destroyed due to injury, surgery, burns, or other permanent injuries will not grow back. And remember, please see your doctor if you experience sudden or dramatic hair loss, which can signal a serious underlying condition. Red and Near-Infrared Light: a Potent Combination
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We can usually identify inflammation when we see it. The inflamed part of the body looks red and swollen, and it feels hot and painful. But in this article, we’ll find out why we experience inflammation, as well as its causes, risk factors, and how red light therapy devices can help reduce it.
Inflammation is our body’s natural response to pain, irritation, damaged cells, exposure to germs, and potential danger. There are two types of inflammation:
1. Acute inflammation
This type of inflammation happens as our body’s healthy response to injury or stress. We mean “healthy” because it helps the body recover faster. The inflammation happens only for a few hours and then starts to repair the damaged tissue.
2. Chronic inflammation
On the other hand, chronic inflammation can be excruciating and may cause discomfort or inconvenience. It causes an imbalance in the body, making it operate inefficiently over time. Chronic inflammation can be caused by viral infections, repetitive tissue damage, autoimmune reactions, and persistent and recurring acute inflammation. At its worse, this type of inflammation may lead to more serious diseases and/or conditions such as cancer, stroke, depression, and heart disorder.
Common Causes of Inflammation
Anything that causes stress on your body may lead to inflammation. These include:
Signs of Inflammation
There are five common signs of inflammation:
For acute inflammation, doctors normally recommend nonsteroidal anti-inflammatory drugs (NSAIDs) such as ibuprofen and paracetamol. Meanwhile, chronic inflammation may also be prescribed with NSAIDs, along with steroids and supplements.
However, these common treatment options help prevent inflammation symptoms but do not deal with the root cause, including improper cellular function, biological imbalance, and damaged tissues. This is also why lifestyle changes (improved diet, regular exercises, and high-quality sleep) and red light therapy could be of great help.
Red light therapy, also referred to as low-level laser therapy (LLLT) or photobiomodulation (PBM), is a non-invasive treatment option. This kind of therapy delivers wavelengths of red and near-infrared (NIR) light to your skin and cells for multiple benefits. When it comes to inflammation, it can help cut down oxidative stress and activate protective cellular mechanisms to boost your immune system and protect you from diseases that may cause inflammation. It can also boost the generation of healing agents and antioxidants in the body to speed up damaged tissues' healing process.
Red light therapy can give your body the light exposure needed to function more efficiently, improve blood flow, and limit inflammation.
Inflammation is a natural part of our biological processes, but chronic cases may also lead to serious health risks that can affect the quality of your life. Therefore, if you’re experiencing signs of inflammation, regardless if it’s acute or chronic, please schedule an appointment with your doctor to get the care and treatment you need as early as possible.
In the meantime, to protect your body from the stress that may cause inflammation, you can do red light therapy either through a health provider or from the comfort of your home. If you need to purchase red light therapy devices, you can browse through our catalog to see the brands and products that we offer.
The one thing we have in common with animals, plants, and other living organisms is that we are all made of tiny little cells. The intricate human body in itself houses trillions of cells. Without cells, there wouldn’t be any life on Earth at all.
In this article, we discuss cellular anatomy and cellular function. Here, we understand how light plays a role in the support and acceleration of cellular respiration.
Think of cells as the basic building block of all living organisms. As the smallest unit of life, cells contain many parts, each with a different and specific function. The command center of the cell is called the nucleus that contains the human DNA.
As these cells combine to form into an organism, they become responsible for vital activities like nutrient intake, energy production, structure building, and hereditary material processing. They make sure that your body gets enough energy and nutrients to function 24/7.
One essential activity that our cells do for us is by taking in oxygen and nutrients to fuel body energy. This energy unit that is converted by the cells is called Adenosine Triphosphate (ATP) Energy.
The ATP itself is a molecule packed with high energy that empowers cellular function. ATP is required by the body to do every activity. Other cells that do more strenuous activities like muscle cells would need more ATP than others. The ideal optimal cellular function would allow cells to produce and use enough energy to achieve body balance or homeostasis.
The mitochondria are the powerhouses of the cell. They are responsible for the production of ATP. Aside from cellular energy, this double-membrane powerhouse does protein synthesis, cell signaling, and cell apoptosis. ATP is produced with oxygen (aerobic) or without oxygen (anaerobic), the former being more beneficial because it converts more energy. Thus, 95% of cellular energy goes through an aerobic process.
Our cells go through a process called Aerobic cellular respiration to convert oxygen, food, and water into the body’s energy currency, which is ATP. This process is a well-organized metabolic pathway that consists of four stages. Our bodies take in nutrients from the food we eat for the first two stages to convert them into carbon compounds. Then for the next steps, these carbon compounds are transformed into the energy that our cells use.
Light can sometimes be less attributed to improve our body’s physiology. However, light has benefits that go beyond aesthetic and technological purposes. Just like how light plays a role in plants' photosynthesis, it also benefits human cellular function.
Red light therapy from Kaiyan Medical composes of Red and Near-Infrared Wavelengths that aid in the Mitochondria's function to produce more ATP energy. It works by increasing the number of Mitochondria in our cells and by boosting their function.
The electron transport chain heavily governs the cellular respiration process. Red Light therapy has photons that can boost the mitochondria to function better through the Cytochrome C Oxidase. It plays an essential role in the cellular respiration process by improving the cell's electron transfer process. In this way, more ATP can be produced by the body for an enhanced cellular function.
As mentioned earlier, oxygen plays an essential role in the cellular respiration process. The infamous Nitric Oxide can take the rightful place of oxygen to limit ATP production that causes stress and cellular death. Red light therapy also gets rid of a harmful roadblock to ATP in the dissociation of Nitric Oxide and the Cox. The photons from Red light therapy prohibits the production of nitric oxide.
The effect that Red Light therapy does on our body is that by improving cellular function, our body can achieve these benefits:
As you do daily activities such as eating, drinking, walking, or working out, think of the massive role that your cellular system plays to make these activities possible. In this way, you can put conscious efforts into improving your cellular system through a healthy diet and lifestyle and by integrating Red Light Therapy.
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5215870/
https://www.medicalnewstoday.com/articles/325884
https://www.britannica.com/science/cell-biology
https://www.britannica.com/science/mitochondrion
As the most accessible element in the globe, hydrogen plays a huge role in our biological processes. However, you may not know that hydrogen usually brings an uninvited guest in your body, and we call it deuterium. Having high deuterium levels may change the chemical reactions in your cells and affect your bodily functions and metabolism, leading to unwanted health consequences.
Deuterium is also known as a “heavy hydrogen” and is one of the two stable hydrogen isotopes. We commonly have it in our bodies — in fact, it helps children grow. However, adults may have too much deuterium because of dietary and environmental factors. As mentioned above, this may lead to chemical reactions at a cellular level and lead to health risks.
Hydrogen is necessary for our day-to-day bodily functions. Our biological processes require it, and we usually get it from what we eat or drink. Upon intake, hydrogen goes to the mitochondria, also known as the powerhouse of the cells.
Our mitochondria can be compared to thousands of engines that continually run to produce the ATP energy we need to survive daily. The majority of people eat only three to five pounds of food each day, but we usually make more than 170 pounds of ATP energy at the same time.
On the other hand, deuterium is like hydrogen’s “evil” sibling. And we repeat, excess deuterium is harmful to our bodies. Because it is twice as heavy and large as hydrogen, it may damage the nanomotors in your mitochondria and slow down ATP energy production. As time goes by, the wear and tear on your nanomotors caused by the heavy hydrogen atoms may completely break your nanomotors. This damage may cause muscle pain, dehydration, impaired memory, poor sleep, headaches, and lymph nodes.
Two “D-terminator” diagnostic tests can help measure the deuterium levels in your body. Advanced technology, such as magnetic resonance imaging (MRI), can also be used to visualize and track deuterium patterns in your body, whether it’s in your bodily fluids, DNA, or even your hair and nails. Based on these tests, your doctor will be able to determine your deuterium levels. And when it shows to be excessive, he/she may come up with a plan to deplete deuterium in your body.
We experience high deuterium levels because of what we eat or drink and some other environmental factors. For instance, carbohydrates, processed foods, and synthetic supplements contain high levels of deuterium. Tap, ocean, and river water also have high deuterium levels, so when you’re exposed to these things regularly, you may experience an overload of this hydrogen isotope.
Nutrition is the baseline of depleting deuterium. Based on your test results, your doctor may recommend consuming food groups that contain lower levels of deuterium, such as proteins, green vegetables, and healthy fats. You may also be advised to drink deuterium-depleted water to lower your deuterium levels.
Health experts say that a body that functions properly can naturally regulate deuterium levels and produce healthy amounts of ATP energy.
Red and near-infrared light can affect our body’s hydrogen bonds in a process quite similar to photosynthesis. The water inside our cells usually becomes less harmful when our bodies absorb wavelengths of red and near-infrared light between 600–950 nanometers. This helps with proper cellular respiration and helps increase ATP energy production in your body.
Changing the water's resistance in your body, red, and near-infrared light can help reduce the amount of friction at the cellular level, promote cellular longevity, and lead to higher outputs of good energy.
To learn more about the benefits of red light therapy or to see what kind of red and near light therapy devices you can use to lower your deuterium levels, click here.
