Have you heard of summertime sadness before? Better yet, have you experienced it yourself?
Many of us might assume that seasonal affective disorder is a condition that only happens during the gloomy winter months. However, it can actually happen any time of the year. Before we go into more detail, it’s important to know what seasonal affective disorder (SAD) is.
The American Psychiatric Association refers to seasonal affective disorder as a form of depression. People who experience SAD experience frequent mood changes and symptoms that are similar to depression. While SAD typically occurs during the fall and winter months due to the lack of sunlight, this condition can occur year-round. Usually, the hardest months for people who have SAD are between January and February.
While SAD is known as the “winter blues,” the symptoms can greatly affect one’s everyday life. Symptoms can include:
As we said before, seasonal affective disorder doesn’t only happen during the winter and fall seasons, though. It can also occur during the spring and summer months. We refer to this as reverse seasonal affective disorder. Clinical psychologist Dr. Meghan Marcum, chief psychologist at premier mental health treatment facility A Mission for Michael says, "about one in 10 cases of the Seasonal Affective Disorder are contributed to the summer months (or winter, for those living in the southern hemisphere).
Certain aspects of the summer contribute to reverse seasonal affective disorder, including the lack of routine, fear of missing out, financial issues around traveling, increased alcohol consumption, and body image concerns. These propel the symptoms of reverse SAD and can significantly affect someone struggling with the stated symptoms.
While people worldwide suffer from reverse seasonal affective disorder, light therapy has been able to alleviate seasonal affective disorder symptoms and bring back the sunlight in people’s lives – literally.
Light therapy and seasonal affective disorder
If you’ve been wondering, “Does red light therapy help seasonal affective disorder?” then we have the answer for you.
The answer is, ‘Yes!’ Light therapy and seasonal affective disorder are a great match to help move forward from the condition and go back to living a healthy and happy life.
Red light therapy for seasonal depression works very specifically by focusing on the body’s circadian rhythm, also known as our sleep-wake cycle. It’s the body’s natural cycle that functions on a 24-hour basis. When experiencing SAD, the body isn’t living in its typical sleep-wake cycle. In other words, it’s out of sync. Light therapy helps aid the body’s melatonin and serotonin production. Melatonin helps the body control the sleep-wake cycle, and serotonin regulates your mood by transmitting signals in your brain.
One study found that light therapy in relation to SAD shows extremely promising results, particularly with symptoms such as delayed circadian phase and depression. With an MDA-approved and FDA-certified red light therapy device, you can focus on reducing your SAD symptoms from the comfort of your home. By sitting in front of the light therapy device in the morning and night, you can regulate your sleep-wake cycle and begin to heal from within.
At Kayian, we’re one step ahead and have produced MDA-certified and FDA-approved light therapy devices that are ideal for at-home or clinical use. Whether you’re looking to private label your own light therapy products or to relieve your own symptoms from the comfort of your home, contact our team for more information. We would love to get you started on your light therapy journey.
Written by the best, for the best.
The first formal description of Seasonal Affective Disorder (SAD), the most well-known psychiatric condition associated with seasonality in humans, was introduced in the mid-1980s by Rosenthal, who described a group of 29 patients living in a temperate climate who experienced depressive episodes characterized by hypersomnia, hyperphagia, and weight gain in the fall or winter, and whose symptoms remitted by the next spring or summer.
SAD was incorporated into the Diagnostic and Statistical Manual (DSM) of Mental Disorders III-R when “seasonal pattern” was introduced as a specifier for Major Depression and Bipolar Disorders. Subsequent revision in DSM-IV described SAD as “a regular temporal relationship between the onset of Major Depressive Episodes in Bipolar I (BPI) or Bipolar II (BPII) Disorder or Major Depressive Disorder (MDD), recurrent, and a particular time of the year.”
Today, SAD, or MDD with seasonal pattern, is defined as recurrent episodes of major depression that meet the following criteria: at least two consecutive years where the onset and offset of depressive symptoms occur at characteristic times with no non-seasonal episodes, a temporal relationship between onset of symptoms and time of year, a temporal relationship between remission of symptoms and time of year, and an outnumbering of seasonal compared to non-seasonal episodes throughout the lifetime of the patient.
To date, the pathophysiology of SAD is unclear. Early research into the mechanism of SAD focused on day length or photoperiod. This hypothesis posited that shorter days in winter, possibly mediated by a longer duration of nocturnal melatonin secretion, leads to depressed mood in susceptible individuals. To date, there is little data to support this hypothesis. Furthermore, given that bright light in the evening has not been as effective as that given in the morning, it now seems unlikely that the photoperiod is the underlying pathological mechanism of SAD.
Although some animal studies have implicated a direct effect of light on the midbrain (Miller, Miller, Obermeyer, Behan, & Benca, 1999; Miller, Obermeyer, Behan, & Benca, 1998), the most prominent hypothesis driving human studies involves disruption of circadian rhythms. Research on the role of serotonin is also active.
A circadian rhythm refers to the approximately 24-hour cycle of physiological processes present in humans and other animals. This cycle is governed via clock gene expression by the suprachiasmatic nucleus (SCN), the master pacemaker located within the anterior hypothalamus. Though the SCN endogenously generates circadian oscillations, SCN endogenously generates circadian oscillations, and they need to be entrained to the 24-hour day by external cues. Light exposure is the most important synchronizing agent of endogenous circadian rhythms.
Downstream of the SCN, a collection of systemically active neurohumoral networks transduce circadian information to the rest of the body. For instance, via projections to the hypothalamus's paraventricular nucleus, the activation of the SCN leads to autonomic changes, including cardiovascular modulation, and together the central, peripheral, and autonomic nervous systems collaborate to affect systemic changes. Thus, the SCN receives information about the external day-night cycle directly through retinofugal pathways and indirectly through neuromodulatory signaling. Circadian information is then relayed systemically through neurohumoral networks.
The current primary hypothesis for the pathophysiology of SAD, known as the “phase-shift hypothesis,” posits that there is an optimal relationship in the alignment of the sleep-wake cycle and the endogenous circadian rhythm. During the fall and winter, as day length shortens, the circadian rhythm begins to drift later concerning clock time and the sleep-wake cycle. This phase delay is hypothesized to bring about mood symptoms. A pulse of morning bright light generates a circadian phase advance, which is thought to correct the discordance between sleep and circadian phase, thereby ameliorating depressive symptoms. However, the phase-shift hypothesis would predict that the amount of phase correction required for each patient would depend on an individual’s PAD, which has not yet been proven.
Several studies have also proposed that serotonin is implicated in the pathophysiology of SAD, as selective serotonin reuptake inhibitors (SSRIs) appear to be effective in the treatment of SAD. Supporting this hypothesis, one study used Positron Emission Tomography (PET) imaging to look at binding probability at synaptic serotonin transporters in 88 normal individuals living in the temperate climate of Toronto, Canada (Praschak-Rieder, Willeit, Wilson, Houle, & Meyer, 2008). The binding probability was increased during fall and winter compared to warmer months, thus eliciting an inverse correlation between binding potential and sunlight durationsunlight duration. Of note, the largest difference in transporter binding was found in the mesencephalon, a finding consistent with animal studies demonstrating the importance of direct effects of light to the midbrain on behavior. If increased transporter activity indicated greater reuptake of serotonin during the fall/winter, and if this resulted in a lower density of cleft serotonin, then the seasonal variation in transporter activity (i.e., higher transporter efficiency in the winter) would seem to leave susceptible individuals particularly prone to mood symptoms during the darker seasons. Moreover, following BLT and during periods of remission in the summer months, the synaptic transporter activity was shown to be reduced to control levels in these patients.
BLT has also been investigated to a lesser extent in eating disorders. Because binge eating episodes have been observed to increase in fall and winter in some patients, BLT has been examined as a treatment modality for anorexia nervosa (AN) and bulimia nervosa (BN). Thus, BLT's effects on patients with eating disorders remain enigmatic. Additional studies, including larger, randomized, blinded, and controlled trials, are needed to elucidate further the role of BLT in treating this patient population. Further research might also determine whether BLT would be a useful treatment in Binge-Eating Disorder, a diagnosis new to DSM-5.
Additionally, BLT has been studied in the context of adult Attention-Deficit/Hyperactivity Disorder (ADHD), where, in addition to normal ADHD symptoms, patients often have depressed mood and difficulties falling asleep, awakening on time, and maintaining arousal (Brown & McMullen, 2001). These symptoms are indicative of a possible delay in the circadian rhythm. A case report of symptom improvement following BLT in a child with ADHD who displayed signs of delayed sleep phase also supports the idea that BLT may be useful in treating symptoms of ADHD (Gruber, Grizenko, & Joober, 2007). Whether the pathways that subserve the improvement of mood symptoms in response to BLT are the same pathways that underlie the seemingly beneficial effects of BLT in ADHD remains to be studied. While these results are promising, further studies, preferably in randomized, blinded, and controlled studies will need to be performed.
A significant immediate reduction of depression scores with light treatment can be identified after 20 minutes and reaches the maximum at 40 minutes, with no additional benefit at 60 minutes. The rate of change is steepest during the first 20 minutes of light as compared with longer intervals. Comparing the clinical impact of these durations of administration may yield different results when measured after several daily sessions. The overnight effect on circadian rhythms and sleep was not assessed in our study and is thought to impact mood regulation in SAD. Larger, prospective, controlled, and hypothesis-driven studies in more naturalistic conditions would be desirable to replicate our study results and our study results and analyze the temporal dynamic of the persistence of the immediate mood-improvement effects. Besides, in larger samples, one could define early responders and nonresponders, analyze genetic (e.g., melanopsin related genes), demographic (children, adolescents, adults, elderly, gender), physiological (e.g., pupillary responses), and clinical (e.g., abundant atypical symptoms) predictors for early response. If proven effective and efficacious, shorter exposures to bright light could become a feasible and broadly employed intervention for immediate mood improvement as an early step on the road toward full antidepressant response and remission.
The life of a college student is taxing, to say the least. It's likely the first time you're doing something on your own, and are responsible for yourself, your schedule and lifestyle. For some, this is the most liberating time; for others, it’s incredibly overwhelming. However, there's a general agreement that college students all go through difficult times.
Whether still living with parents or sharing a dorm or space with roommates, college students are immersed in an entirely new life experience. Classes are challenging and students struggle with getting their work done while maintaining a social life, and perhaps a job. The level of pressure to succeed is very demanding, and this can cause negatively associated thoughts, leading to stress. Eating habits change and alter, usually for the worst, not to mention that the new sense of freedom can be chaotic for many young adults.
Taking care of yourself is the number one priority, and when learning to deal with the new load of responsibility, college students often get sidetracked. Health and self-care get only an ounce of attention and not nearly as much as it should. While many students think it takes a lot of effort, just starting small shows results.
Stress is the precursor of everything in our body, and leads to all sorts of illness and disorders. It's pretty common for college students to experience stress; more than 40% of students claimed to have experienced above-average stress levels, with it getting worse during exam periods and the winter season, when even more time is spent indoors. All of this, compounded by a pandemic and social distancing, makes for extremely challenging circumstances for college students today.
Now, colleges such as the University of Iowa are turning to light therapy to help get students the light they need to continue thriving.
Seasonal affective disorder (SAD) is a mood disorder that occurs annually, generally in fall and early winter, and ends in sunnier and warmer months of spring and early summer. However, it’s worth noting that it’s not a perfect formula; there have been reported cases of the opposite, where a person starts experiencing the disorder spring or summer, and it only ends with the arrival of fall/winter.
SAD can affect 11 million people in the U.S. each year, and 25 million more may have a milder form of the same disorder, also known as winter blues. Depression and anxiety affect 40 million adults in America, while only 36.9% receive the proper care for these mental health conditions.
And, SAD’s symptoms can look and feel much like depression. It causes you to sleep more and gives you symptoms that look like other disorders such as chronic fatigue syndrome, under-active thyroid, low blood sugar, viral illnesses, or other mood disorders.
Seasonal affective disorder is linked to a lack of sunlight. The winter days are shorter, and that itself our circadian rhythm, or internal body clock. Everyone has a specific sensitivity to sunlight, and our bodies take a cue from the morning sunlight each day. In the winter time, the lack of sunlight creates perfect circumstances to experience SAD.
Light therapy, by definition, gives you a healthy supply of what you lack in winter months, often leading to SAD. But light therapy is much more than that. Light therapy’s uses and benefits are many, so while treating SAD, you could also be treating other problems you may not even know of – it’s like killing multiple birds with one stone, and that stone happens to be safe, non-invasive, and non-pharmaceutical.
Light therapy mimics the positive effects produced by exposure to the sun. It reproduces the effects the sun provides us with, and can solve numerous symptoms of SAD through the use of ultraviolet rays. You may be wondering if red light therapy is safe for skin: yes, it is entirely safe. Specifically, with Kayian's light therapy devices, which are FDA-approved and MDASAP-certified.
With light therapy, you're able to stimulate your cells into rejuvenation. The light works directly at the cellular level and triggers the reproduction of ATP, the fuel our system needs to function properly.
Light therapy helps with SAD by causing our brain to believe it's getting more sunlight. Even though the light is fabricated, it's still light. We still reap all of the benefits as we do from sun exposure. Melatonin and serotonin are what affects the impact; they too, are triggered by our light therapy devices, which is what battles SAD.
The scientific evidence on light therapy and SAD says that even within the first hour, you may experience positive results. With daily use of light therapy, thousands of people have overcome the debilitating symptoms of SAD and other disorders, and now even college students can turn to the holistic treatment to replenish the light they’re lacking. For more information, contact our team.
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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Now, you don’t often hear about cats getting depressed. In fact, most people don’t even know if depression is possible in animals.
A typical morning for cats usually involves purring, meowing, and stretching alongside family members. Then they’ll go to their favorite place to settle down in, and you continue with your day.
While we become comfortable with our cat’s daily routine, do we actually know our feline pets? What if your cat is depressed? Could you understand why? How can you help your cat overcome winter blues?
Cats are extremely sensitive to changes in light, more than humans. If there’s less light, a decrease in brain chemicals, including serotonin, can occur. When the weather changes to rain or snow, it’s not unusual for cats to feel the shift in sunlight.
Your cat, whether indoor or outdoor, may become depressed during the winter months. The lack of sunlight, less physical activity, and more time alone can contribute to feelings of restlessness or seasonal affective disorder (SAD).
SAD in felines occurs similar to humans, and it’s highly influenced by the amount of sunlight they’re exposed to daily.
If your cat has SAD, you may notice them behaving gloomy and moving slower than usual during the winter. However, when April and May roll around, they have more energy and appear happier.
The lack of sunlight is a serious problem as it reduces melatonin production, which results in depression, lethargicness, and anxiety. It also creates low levels of serotonin which acts as a neurotransmitter. With low serotonin, your cat may show signs of aggression, mood swings, and depression.
Achieving chemical balance is not easy, especially since serotonin cannot be given in a shot or pill. While your vet may prescribe a serotonin reuptake inhibitor (SRI), it comes with its side effects. A natural and non-invasive treatment option is light therapy, which adds natural sunlight into your cat’s environment to restore their chemical balance.
You’ll often heart veterinarians recommend light therapy as a treatment for SAD. Light therapy is an affordable, natural, and non-invasive treatment option that can help stabilize your animal’s emotional highs and lows. And it costs less than a year’s supply of pet food.
At Kaiyan Medical, we recommend treating your animal for 30 minutes every day with red light therapy. Cat and dogs suffer from many conditions such as inflammation, arthritis, and infections. Light therapy gives you the chance to help treat your pet and reduce their pain and suffering.
How does red light therapy actually help to treat animals? While you may think the answer is complex, it’s not. Red light therapy delivers red and infrared light into the animal’s cells, boosting the body’s natural ability to heal.
Using either LEDs or LASER diodes, light penetrates through the skin, entering the body’s cells. Photoreceptors in your animal’s cells absorb the light’s energy, enhancing the natural healing process by stimulating the cells’ energy production.
The use of varying lights helps treat different areas of the body. For example, red light is easily absorbed by tissue rich in hemoglobin, helping to heal surface wounds.
Near-infrared light penetrated into deeper tissues within the body, entering muscles, joints, bones, tendons, and ligaments for extensive treatment. Combing red, green, and near-infrared light offers a well-rounded treatment for your animal.
The way light therapy stimulates cells can help treat several conditions in animals, including:
Clinical data has supported and proven light therapy’s effectiveness in treating animals. In one study, horses suffering from chronic back pain responded to red light therapy in less than three months of therapy, with 70% gaining the ability to train and compete. Other studies have also proven that horses treated with red light therapy experience faster tissue healing times.
If you’re considering treating your dog or cat with light therapy, the first thing you need to do is consult your veterinarian, ensuring it’s the right treatment option for your pet.
Light therapy treats various conditions; however, if your pet is experiencing severe SAD, they may need an extensive treatment plan. At Kayian Medical, we love our animals and want to provide them with the best support possible.
Low-Intensity Light Therapy: Exploring the Role of Redox Mechanisms. Joseph Tafur, M.D. and Paul J. Mills, Ph.D.
Effect of NASA light-emitting diode irradiation on wound healing. J Clin Laser Med Surg. 2001
Treatment of chronic back pain in horses. Stimulation of acupuncture points with a low-powered infrared laser. Martin BB Jr. 1987.
Equine wound healing: influence of low-level laser therapy on an equine metacarpal wound healing model. Jann. 2012.
Effect of light-emitting diode (LED) therapy on the development of osteoarthritis (OA) in a rabbit model. Biomed Pharmacother. 2011
Low-level laser therapy reduces time to ambulation in dogs after hemilaminectomy: a preliminary study. Draper WE. 2012