Approximately half of all adults snore at least occasionally, and you may do, or you may know someone who does. Snoring can be a nuisance and, in some cases, can be an indicator of a more serious health issue such as obstructive sleep apnea.
In many cases, snoring can be easily remedied using simple devices such as nasal strips, mouthpieces, or even pillows. Other remedies include losing weight, sleeping on your side, avoiding alcohol, stopping smoking, and getting enough sleep. Another option is Light Therapy.
Light therapy has shown to be the most successful way to alter one’s sleeping schedule. It is used to regularly expose the eyes to extreme but safe amounts of light for a specific amount of time. The easiest way is to get exposed to a bright light first thing in the morning. This can be done by going out into the sun as soon as you wake in the morning or sitting in front of a bright light designed for this purpose.
Unfortunately, in many areas, sunlight is not available at the right time. Artificial light is used to adjust the internal clock in the same way sunlight would.
Disorders of the circadian rhythm can cause irregular sleep and wake patterns, resulting in snoring. The objective of treating people who have snoring problems due to circadian rhythm issues is to obtain a healthy sleeping pattern with an internal clock set to the right time. light therapycan help reset that clock.
Light therapy is basically just the exercise of sitting in front of a light therapy device. This will activate your serotonin levels, which is the hormone responsible for feeling relaxed and happy.
Timing is critical. There is a point during the sleeping period that exposure to the light could delay the sleep cycle even more, for example, in the evening. However, exposure after that specific time (in the morning) will advance or move earlier. Basically, you should sit in front of the light immediately after you wake up in the morning.
Many people have reported a significant improvement in sleeping and a reduction in snoring and can function well in a typical 9-to-5 work schedule. Some have combined the light therapy with other non-snoring devices and have significantly alleviated or remedied their snoring issues.
During the sleep cycle, the muscles in the throat, tongue, and roof of the mouth relax. This causes the tongue to move backward and loose tissue in the throat to droop. While breathing, this loose tissue flaps, leading to obstruction or narrowing of the airways. When the airways are obstructed or narrow, the vibration becomes greater, and the snoring becomes louder.
Often, the snoring will disrupt your circadian rhythm and cause you to wake up. This is irregular sleep-wake pattern can turn into a vicious cycle. Continually waking up during the night causes you to get less sleep. Less sleep means long days, and you are overly tired when you go to bed at night. When you are overtired, you tend to sleep hard and deep, and the muscles become floppier, thus creating more snoring.
Other causes that can disrupt the circadian rhythm are delayed sleep phase syndrome, jet lag, shift work sleep disorder, rapid time zone change, and non-24-hour sleep-wake disorder.
“Circadia” refers to biological activities that occur within a 24-hour cycle. The oldest circadian cycle is our relationship with light and dark and sleep and wake.
All plants, animals, and insects show changes in behavior with the light and dark. This is what is considered “circadian rhythm.” Your mind has an internal clock that tells it when it is time to sleep and when it should be awake. This clock is located in the brain and is responsible for maintaining the circadian rhythms taking its signals from the darkness and the daylight. This cycle is genetic and varies from person to person.
Written by the best, for the best.
Do you feel like you only slept for two hours when you wake up in the morning? Does it take you forever to fall asleep? Though you may think you’re alone in this, you’re not; millions of Americans suffer from sleep deprivation and other sleep conditions.
You may be doing everything right. You go to bed early, you have a healthy diet, you stay away from your phone before bed. And yet, nothing seems to work. You still wake up every morning feeling fatigued and exhausted.
So what's causing your poor sleep quality, and how do you improve it? Well, we're going to discuss the causes of poor sleep and also the various remedies available.
There are a few reasons why you may not be getting a good night’s sleep. The reasons can include:
How to improve the quality of your sleep
While we showed you the reasons for what’s causing your poor sleep quality, it’s time we gave you the ways on how you can improve your quality of sleep. That’s where light therapy comes in.
How can light therapy improve sleep?
Light therapy is a non-invasive, non pharmacological treatment that can aid with sleep disorders such as insomnia, circadian rhythm sleep disorders, jet lag, seasonal affective disorder, and depression. But how?
Individuals can use light therapy devices that emit a specific amount of light therapy colors for sleep. The light mimics outdoor light, however, without harmful UV rays. It improves sleep conditions as it helps sync the circadian rhythm. Everyone has a circadian rhythm that dictates when we feel tired, alert, and hungry. Our circadian rhythm follows the 24-cycle of the sun.
Exposing ourselves to light therapy helps realign the circadian rhythm, syncing it with the sun's cycle. As a result, you feel tired during the evening and more awake in the morning due to the chemicals released in your brain, melatonin, and serotonin—both playing a major role in your sleep-wake cycle.
If individuals undergo at-home light therapy treatments daily in the morning, they'll notice their internal clock improve and experience a good night's sleep.
Kaiyan Medical produces FDA-approved and MDA-approved red light therapy devices for clinical or at-home treatments for the best light therapy for sleep. They're non-invasive and non-pharmaceutical, meaning you'll get the treatment you need without side effects. Kaiyan's red light therapy devices are easy to use and help you take charge of your sleep.
Proper sleep is crucial for health and balance, and light therapy can play a big role in your sleep cycle and your circadian rhythms. If you want to get the best of your sleep time, here are 5 tips:
Caffeine is a powerful stimulant that you should avoid beyond the early afternoon. Most people need hours to process caffeine and overcome the jolt it gives you. Try to avoid caffeinated drinks afternoon if you can, but definitely lay off the coffee and soda at night. Drinking alcohol at night can make it seem easier to fall asleep, but in reality, it’s closer to sedation. Try to have your last drink of the evening with dinner, so your body has a few hours to process it before hitting the proverbial sack.
Our body’s activity level has its own circadian rhythm. When we’re awake, we’re designed to move. Exercise, especially in the morning or early afternoon, can help you sleep better at night. Regular exercise raises your body temperature, and the cooldown period has a relaxing effect that promotes better sleep. By contrast, exercising later in the evening can make it more difficult to sleep because your body hasn’t fully recovered from activity mode.
The research is detailed: high amounts of stress throughout the day make it more difficult for our brains to relax and sleep at night. If you have a stressful day, be mindful about claiming some relaxation in the evening with meditation, reading, walking, or whatever works for you. Bottom line: prioritize your peace of mind before getting into bed.
The human body decreases in temperature while we sleep. Our heart rate and breathing slow down to help regulate this temperature drop. You can give your body a better sleep environment if your bedroom is in the 18–24 degrees range. Hot rooms make it harder to get to sleep and stay asleep. Avoid waking up in sweat by keeping your bedroom cooler. It’s better for your sleeping rhythm if you don’t wake up several times in the night because you’re hot. These small disruptions can build up and lead to larger sleep problems.
Don’t overlook the importance of light for your sleep quality. Your body and brain respond to the light you’re exposed to during the day, and some kinds of light are better than others when it comes to your sleep quality. You should absolutely try to get outside every day and take in natural sunlight. However, blue light from screens is extremely bright and can trick your brain and disrupt your sleep hormones, especially at night.
Blue light has been a big advancement for screen technology that’s made our phones and computers so powerful. But this bright, artificial light can have major negative effects on our sleep quality. Blue light is so bright that it can trick our brains and bodies into thinking it’s time to be alert and awake. Blue light from a screen has a very high color temperature. It’s even brighter than standing outside on a sunny day. If you look at your phone in bed, your brain is getting the message that it needs to be alert.
Sleep Foundation. How Exercise Impacts Sleep Quality
Healthline. What Is The Best Temperature for Sleep?
Konturek PC, Brzozowski T, Konturek SJ. Gut clock: implication of circadian rhythms in the gastrointestinal tract. J Physiol Pharmacol. 2011 Apr.
St-Onge AP, Mikic A, and Pietrolungo C. Effects of Diet on Sleep Quality. Advances in Nutrition. 2016 Sept.
Sleep Foundation. Stress and Insomnia.
Lack of sleep is a villain in America and Europe. Light intake is a big part of the problem. Over 65% of adults say they don’t get enough good sleep every week. Most people also don’t get nearly enough natural light for optimal health: the average American spends over 90% of their time indoors.
In addition to not getting enough natural light, people today are surrounded by artificial blue light from screens and overhead lighting. An overload of artificial blue light can cause headaches and make it harder to get to sleep and stay asleep. When we take in all that bright blue light from laptops, TVs, and phones, especially before we go to bed, our bodies get the signal that it's time to be awake, even if we're tired.
Melatonin is the naturally-occurring hormone that regulates sleep and wakefulness. Emerging research is showing that red light therapy treatments can help people produce more of their own, natural melatonin than exposure to other light sources like blue light. Red light therapy is natural light. It’s much less bright than blue light, with a lower color temperature than daytime sun, as the image above shows. Research has shown that red light doesn’t upset your sleep cycle like bright blue light. Red light therapy is showing great clinical results for people with insomnia and sleep disorders.
The light therapy is a simple, non-invasive treatment that delivers concentrated natural light to your skin and cells. Clinical research is showing that red light therapy can improve sleep quality and duration, and help people produce more of their own melatonin.
Light plays a major role in your sleep cycle. The body’s circadian clock interprets light as a sign of when to sleep and when to be awake. Artificial blue light from phones, computers, and other screens is extremely bright and can knock your circadian rhythm out of whack. Red light has the opposite effect: it’s ideal for evenings because it has a low color temperature—far lower than blue light and much closer to the natural sunset.
Red light therapy treatments are quick and simple: you just sit or stand in natural light for 5 to 15 minutes, ideally every day. This stimulates your mitochondria and gives your cells the natural light they need to make energy.
Natural light is a key ingredient for a healthy circadian rhythm and restful sleep. If you struggle to sleep, your light intake could be a big factor. Red light therapy delivers natural light like you’d get from the sun, but without UV rays, excess heat, or the need for sunny weather.
Red light therapy treatments supercharge your cells with the natural light they need to make more core ATP (adenosine triphosphate) energy. This helps your body run more efficiently, heal faster, and has shown great results for producing more natural melatonin and improving sleep disorders like insomnia.
Red light therapy treatments have shown great sleep results in a range of peer-reviewed clinical studies. One study on the sleep of pro basketball players showed that a 2-week course of red light therapy in the evening improved players’ sleep quality in the short term. Based on the results, the researchers suggested red light therapy would be a good non-invasive, drug-free solution to sleep struggles.
Kaiyan's light therapy products are registered with the FDA as class II medical devices for the treatment of pain, strain, and inflammation. While the existing clinical research has been very positive for red light therapy and sleep, keep in mind that Kaiyan's devices are not cleared with the FDA for the treatment of various sleep disorders or melatonin.
Recent research on sleep disorders among people with migraine headaches has shown that red light therapy both decreased headache frequency, and was the only treatment that improved patients’ sleep disorders.
A 2014 study on cognitive function and traumatic brain injury (TBI) recorded that participants had significantly decreased episodes of post-traumatic stress disorder (PTSD), and improved sleep.
Analyzing patients’ electrical brain activity, a 2013 sleep study concluded that red light therapy was especially effective at helping people with sleep disorders fall asleep.
When I’m indoors training under the buzz of artificial lights, my body doesn’t get the natural light it needs. Add computers, cell phones, televisions, etc. and it’s easy to overload yourself with blue light. I used to have trouble sleeping after long training days, but since adding more natural light to my routine with red light therapy, I’ve been falling asleep as soon as I lie down, and I’ve been staying asleep all night.*
Sanne Wevers
Gold-Medal Winning Dutch Gymnast
Research is showing how closely mood and sleep disorders are interconnected. Parts of the brain that regulate sleep have also been found to closely affect mood. A 2013 review concluded that “nearly all people suffering from mood disorders have significant disruptions in circadian rhythms and the sleep/wake cycle.”
This Greatist post on natural light and serotonin gives good background on the connections between natural light intake, mental health, and sleep. It also mentions using Kaiyan's red light therapy devices to get more natural light, even when you can’t get more sunlight.
Trouble sleeping is one of the most common symptoms of seasonal affective disorder, a type of depression most common in the darker winter months. Some physicians treating patients with mental health disorders have said red light therapy both improves mood, and helps people with depression get better sleep.
Sources and References:
Morita T., Tokura H. “ Effects of lights of different color temperature on the nocturnal changes in core temperature and melatonin in humans” Journal of Physiological Anthropology. 1996, September
Lirong Z., Phyllis Z. “Circadian Rhythm Sleep Disorders” Neurologic Clinics. 2012, November.
Color Temperature
The State of Sleep Health in America.
Klepeis N., Nelson W., et al. “The National Human Activity Pattern Survey (NHAPS): a resource for assessing exposure to environmental pollutants”. Journal of Exposure Analysis and Environmental Epidemiology 2001.
Sheppard A and Wolffsohn J. “Digital eye strain: prevalence, measurement and amelioration.” BMJ Open Ophthalmology. 2018 April.
Gooley, J., Chamberlain, K., Smith, K., Khalsa, S., et al. “Exposure to Room Light before Bedtime Suppresses Melatonin Onset and Shortens Melatonin Duration in Humans” J Clin Endocrinol Metab. 2011 Mar.
Hamblin M. “Mechanisms and applications of the anti-inflammatory effects of photobiomodulation”. AIMS Biophys. 2017.
Zhao J., Tian Y., Nie J., Xu J., Liu D. “Red light and the sleep quality and endurance performance of Chinese female basketball players” Journal of Athletic Training. 2012, November-December.
Loeb LM, Amorim RP, et al. “Botulinum toxin A (BT-A) versus low-level laser therapy (LLLT) in chronic migraine treatment: a comparison.” Arquivos de neuro-psiquiatria. 2018 Oct;76(10):663-667.
Naeser MA, Zafonte R, et al. “Significant improvements in cognitive performance post-transcranial, red/near-infrared light-emitting diode treatments in chronic, mild traumatic brain injury: open-protocol study.” Journal of Neurotrauma. 2014 Jun 1;31(11):1008-17.
Wu JH, Chang YC. Effect of low-level laser stimulation on EEG power in normal subjects with closed eyes. Evidence Based Complementary and Alternative Medicine. 2013; 2013:476565.
Vadnie C, and McClung C. Circadian Rhythm Disturbances in Mood Disorders: Insights into the Role of the Suprachiasmatic Nucleus. Neural Plasticity. 2017 November.
McClung C. How might circadian rhythms control mood? Let me count the ways. Biological Psychiatry. 2013 April.
Nutt D, Wilson S, et al. Sleep disorders as core symptoms of depression. Dialogues in Clinical Neuroscience. 2008 September.
Avci P, Gupta A, et al. Low-level laser (light) therapy (LLLT) in skin: stimulating, healing, restoring. Seminars in Cutaneous Medicine and Surgery. Mar 2013.
Good sleep is a prerequisite for optimal performance. Given that people spend about one-third of their lives asleep, sleep has substantial development, daily functioning, and health. Perhaps no daytime behavior has been associated more closely with improved sleep than exercise. Researchers have shown that exercise serves as a positive function for sleep. Regular exercise consistently has been associated with better sleep. Moreover, the American Academy of Sleep Medicine considers physical exercise a modality of nonpharmacologic treatment for sleep disorders. When studying the influence of exercise on sleep, most investigators have compared acute and sedentary control treatments. In the study of regular moderate-intensity endurance exercise, researchers also provided compelling evidence that exercise promotes sleep.
However, exercise can negatively affect sleep quality. Exercising immediately before going to sleep is detrimental to sleep quality. Athletes train very hard to improve their on-field performances, but excessive training may decrease performance, known as overtraining syndrome. Researchers have shown that symptoms of overtraining indicate poor-quality sleep. Good sleep is an important recovery method for the prevention and treatment of overtraining in sports practice.
In a recent study in which red-light therapy (wavelength = 670 nm, light dose = 4 J/cm2) was used, researchers indicated that red light could restore glutathione redox balance upon toxicologic insult enhance both cytochrome c oxidase and energy production, all of which may be affected by melatonin. Melatonin is a neurohormone that is produced by the pineal gland and regulates sleep and circadian functions. No one knows whether sleep is regulated by melatonin after red-light irradiation in athletes. Researchers have demonstrated that phototherapy improves muscle regeneration after exercise. A red light could protect human erythrocytes in preserved diluted whole blood from the damage caused by experimental artificial heart-lung machines.
Twenty female athletes of the Chinese People’s Liberation Army team (age = 18.60 ± 3.60 years) participated in the study. All participants were healthy and were not using medications regularly or temporarily during the measurements. Athletes were excluded if they had participated in less than 80% of the scheduled team physical training and basketball sessions for the last 3 months or used any nutritional supplements or pharmacologic agents. All participants provided written informed consent, and the Ethical Committee approved the China Institute of Sport Science study.
Participants were assigned randomly to either a red-light therapy intervention group (n = 10) or non–red-light therapy intervention group (placebo group, n = 10). Measurements were collected at preintervention (baseline) and postintervention (14 days). The exercise training schedule of the 2 groups was unchanged during the 14 days; the red-light treatment group used a red-light therapy instrument every night for total body irradiation for 30 minutes. The training routine of the athletes during the 14 intervention days included 12 exercise sessions with the following specifications: 2 hours of morning training, 2 hours of afternoon training, and no training on Sunday.
The red-light treatment participants lay in the supine position. Continuous illumination was performed using noncoherent red light from a whole-body red-light treatment machine-like Kaiyan’s red light therapy bed, with an average wavelength of 658 nm and a light dose of 30 J/cm2. The whole body received the phototherapy treatment. The placebo participants also lay in the supine position under the red-light device but did not receive any light illumination. All participants wore swimsuits to enhance irradiation from the device and were blind to the treatment.
The Chinese version of the PSQI measured sleep quality. The 19-item measure assesses sleep quality and disturbances over a half-month time interval. The total PSQI score ranges from 0 to 21, and higher scores reflect poorer-quality sleep. The 7 items of this instrument measure several aspects of insomnia: difficulties with onset and maintenance of sleep, satisfaction with the current sleep pattern, interference with daily functioning, noticeable impairment attributed to sleep problems, degree of distress, and concern caused by any sleeping problems.
Participants were instructed to complete as many laps as possible on a 400-m outdoor track during the 12-minute test period. Emphasis was placed on pacing oneself throughout the test. The test administrators counted the laps completed during the 12-minute test period while calling out the time elapsed at 3, 6, and 9 minutes and orally encouraging the participants. At the end of the 12-minute period, the test administrator instructed the participants to stop and used a measuring wheel to determine the fraction of the last lap completed by each participant. This distance was added to the distance determined by the number of laps completed to give the total distance covered during the test.
In humans, the serum level of melatonin, derived mainly from the pineal gland, demonstrates a clear increase at night and a decrease during the day. Given that the masking effects of activities (e.g., exercise, sleep, and food intake) have little effect on the circulating melatonin level's daily pattern, melatonin secretion appears to directly reflect the function of the biological clock as a specific marker of the circadian rhythm.
The study has demonstrated that red-light illumination positively affected sleep quality and endurance performance variables in Chinese female basketball players. Based on previous studies, we can infer that red-light treatment contributes to increased melatonin secretion in the pineal gland and muscle regeneration. Although more studies involving phototherapy, sleep, and exercise performance need to be performed, red-light treatment is a possible nonpharmacologic and noninvasive therapy to prevent sleep disorders after training.
This research project was supported by the National Key Technologies R&D Program Fund of China (2006BAK37B06).
Originally from:
Red Light and the Sleep Quality and Endurance Performance of Chinese Female Basketball Players
Jiexiu Zhao, Ye Tian, Jinlei Nie, Jincheng Xu, Dongsen Liu
J Athl Train. 2012 Nov-Dec; 47(6): 673–678. doi: 10.4085/1062-6050-47.6.08
PMCID: PMC3499892
Skein M, Duffield R, Edge J, Short MJ, Mundel T. Intermittent-sprint performance and muscle glycogen after 30 h of sleep deprivation. Med Sci Sports Exerc. 2011;43(7):1301–1311. [PubMed] [Google Scholar]
Gerber M, Brand S, Holsboer-Trachsler E, Puhse U. Fitness and exercise as correlates of sleep complaints: is it all in our minds? Med Sci Sports Exerc. 2010;42(5):893–901. [PubMed] [Google Scholar]
Youngstedt SD. Effects of exercise on sleep. Clin Sports Med. 2005;24(2):355–365. xi. [PubMed] [Google Scholar]
Myllymaki T, Kyrolainen H, Savolainen K et al. Effects of vigorous late-night exercise on sleep quality and cardiac autonomic activity. J Sleep Res. 2011;20(1 pt 2):146–153. [PubMed] [Google Scholar]
Youngstedt SD, Kripke DF, Elliott JA. Is sleep disturbed by vigorous late-night exercise? Med Sci Sports Exerc. 1999;31(6):864–869. [PubMed] [Google Scholar]
Driver HS, Taylor SR. Exercise and sleep. Sleep Med Rev. 2000;4(4):387–402. [PubMed] [Google Scholar]
van Straten A, Cuijpers P. Self-help therapy for insomnia: a meta-analysis. Sleep Med Rev. 2009;13(1):61–71. [PubMed] [Google Scholar]
Tanskanen M, Atalay M, Uusitalo A. Altered oxidative stress in overtrained athletes. J Sports Sci. 2010;28(3):309–317. [PubMed] [Google Scholar]
Roose J, de Vries WR, Schmikli SL, Backx FJ, van Doornen LJ. Evaluation and opportunities in overtraining approaches. Res Q Exerc Sport. 2009;80(4):756–764. [PubMed] [Google Scholar]
Campbell SS, Dawson D, Anderson MW. Alleviation of sleep maintenance insomnia with timed exposure to bright light. J Am Geriatr Soc. 1993;41(8):829–836. [PubMed] [Google Scholar]
Guilleminault C, Clerk A, Black J, Labanowski M, Pelayo R, Claman D. Nondrug treatment trials in psychophysiologic insomnia. Arch Intern Med. 1995;155(8):838–844. [PubMed] [Google Scholar]
Yeager RL, Oleske DA, Sanders RA, Watkins JB, III, Eells JT, Henshel DS. Melatonin as a principal component of red light therapy. Med Hypotheses. 2007;69(2):372–376. [PubMed] [Google Scholar]
Radogna F, Diederich M, Ghibelli L. Melatonin: a pleiotropic molecule regulating inflammation. Biochem Pharmacol. 2010;80(12):1844–1852. [PubMed] [Google Scholar]
Leal Junior EC, Lopes-Martins RA, Rossi RP et al. Effect of cluster multi-diode light emitting diode therapy (LEDT) on exercise-induced skeletal muscle fatigue and skeletal muscle recovery in humans. Lasers Surg Med. 2009;41(8):572–577. [PubMed] [Google Scholar]
Leal Junior EC, Lopes-Martins RA, Baroni BM et al. Comparison between single-diode low-level laser therapy (LLLT) and LED multi-diode (cluster) therapy (LEDT) applications before high-intensity exercise. Photomed Laser Surg. 2009;27(4):617–623. [PubMed] [Google Scholar]
Itoh T, Murakami H, Orihashi K et al. Low power laser protects human erythrocytes in an in vitro model of artificial heart-lung machines. Artif Organs. 2000;24(11):870–873. [PubMed] [Google Scholar]
Buysse DJ, Reynolds CF, III, Monk TH, Berman SR, Kupfer DJ. The Pittsburgh Sleep Quality Index: a new instrument for psychiatric practice and research. Psychiatry Res. 1989;28(2):193–213. [PubMed] [Google Scholar]
Buysse DJ, Ancoli-Israel S, Edinger JD, Lichstein KL, Morin CM. Recommendations for a standard research assessment of insomnia. Sleep. 2006;29(9):1155–1173. [PubMed] [Google Scholar]
Barclay NL, Eley TC, Buysse DJ, Rijsdijk FV, Gregory AM. Genetic and environmental influences on different components of the Pittsburgh Sleep Quality Index and their overlap. Sleep. 2010;33(5):659–668. [PMC free article] [PubMed] [Google Scholar]
Desmet KD, Paz DA, Corry JJ et al. Clinical and experimental applications of NIR-LED photobiomodulation. Photomed Laser Surg. 2006;24(2):121–128. [PubMed] [Google Scholar]
Whelan HT, Connelly JF, Hodgson BD et al. NASA light-emitting diodes to prevent oral mucositis in pediatric bone marrow transplant patients. J Clin Laser Med Surg. 2002;20(6):319–324. [PubMed] [Google Scholar]
Figueiro MG, Rea MS. The effects of red and blue lights on circadian variations in cortisol, alpha amylase, and melatonin. Int J Endocrinol. 2010;2010:829351. [PMC free article] [PubMed] [Google Scholar]
Lynch HJ, Wurtman RJ, Moskowitz MA, Archer MC, Ho MH. Daily rhythm in human urinary melatonin. Science. 1975;187(4172):169–171. [PubMed] [Google Scholar]
Miles A, Philbrick DR. Melatonin and psychiatry. Biol Psychiatry. 1988;23(4):405–425. [PubMed] [Google Scholar]
Lynch HJ, Jimerson DC, Ozaki Y, Post RM, Bunney WE, Jr, Wurtman RJ. Entrainment of rhythmic melatonin secretion in man to a 12-hour phase shift in the light/dark cycle. Life Sci. 1978;23(15):1557–1563. [PubMed] [Google Scholar]
Vaughan GM, Allen JP, Tullis W, Siler-Khodr TM, de la Pena A, Sackman JW. Overnight plasma profiles of melatonin and certain adenohypophyseal hormones in men. J Clin Endocrinol Metab. 1978;47(3):566–571. [PubMed] [Google Scholar]
Gastel JA, Roseboom PH, Rinaldi PA, Weller JL, Klein DC. Melatonin production: proteasomal proteolysis in serotonin N-acetyltransferase regulation. Science. 1998;279(5355):1358–1360. [PubMed] [Google Scholar]
Sack RL, Hughes RJ, Edgar DM, Lewy AJ. Sleep-promoting effects of melatonin: at what dose, in whom, under what conditions, and by what mechanisms? Sleep. 1997;20(10):908–915. [PubMed] [Google Scholar]
Wright HR, Lack LC. Effect of light wavelength on suppression and phase delay of the melatonin rhythm. Chronobiol Int. 2001;18(5):801–808. [PubMed] [Google Scholar]
Lack L, Wright H, Kemp K, Gibbon S. The treatment of early-morning awakening insomnia with 2 evenings of bright light. Sleep. 2005;28(5):616–623. [PubMed] [Google Scholar]
Baroni BM, Leal Junior EC, Geremia JM, Diefenthaeler F, Vaz MA. Effect of light-emitting diodes therapy (LEDT) on knee extensor muscle fatigue. Photomed Laser Surg. 2010;28(5):653–658. [PubMed] [Google Scholar]
Ihsan FR. Low-level laser therapy accelerates collateral circulation and enhances microcirculation. Photomed Laser Surg. 2005;23(3):289–294. [PubMed] [Google Scholar]
Baroni BM, Leal Junior EC, De Marchi T, Lopes AL, Salvador M, Vaz MA. Low level laser therapy before eccentric exercise reduces muscle damage markers in humans. Eur J Appl Physiol. 2010;110(4):789–796. [PubMed] [Google Scholar]
Hynynen E, Uusitalo A, Konttinen N, Rusko H. Heart rate variability during night sleep and after awakening in overtrained athletes. Med Sci Sports Exerc. 2006;38(2):313–317. [PubMed] [Google Scholar]
Sleep is big business these days — one in three people are believed to experience sleep deprivation — and everyone is keen to rely on the latest fashionable theory.
For years, sleep cycles were divided into two categories. People who enjoy mornings were known as “early birds.” And those of us who prefer staying up late were labeled “night owls.”
Well, step-aside birds. Mammals are the new name of the game. That’s right; scientists now believe there are four ways to classify sleep/wake cycles. In the science world, these classifications are known as chronotypes.
Chronotypes describe the periods when your body wants to sleep and when it wants to be awake. And to make it easier, the chronotype categories are named after animals. Our natural sleep tendencies are now categorized as bear, wolf, lion, and dolphin.
It is crucial to understand your animal chronotype. Once you do, you can start to schedule your life around your body’s natural cycles. Kaiyan Medical suggests that this may help you sleep better and feel more productive at work.
People have different circadian rhythms. That’s just a fact of life.
Science shows that:
“The human circadian system actively synchronizes to the 24-h day via environmental signals of light and darkness.”
Circadian? A 24-hour cycle. It’s your body clock. Sleep psychologists reckon they can determine our natural sleeping patterns. By understanding our own, we can have a happier, more productive life.
Now, Chronotype is a term that describes a person’s natural rhythm. And it doesn’t only relate to sleep. Chronotypes influence all primal instincts.
Author Michael Breus, Ph.D., recently suggested that there are 4 natural chronotypes. And he named these after 4 animals that follow similar sleep/wake patterns. So, say goodbye to night owls and early birds. Wolves, lions, bears, and dolphins are the new circadian rhythm mascots.
Check out the chronotypes below and let us know in the comment section which one sounds like you!
Alright, night owls, this is your group. Just like these nocturnal creatures, you are most alert at night. Wolves tend to stay up later and struggle with waking up early.
Only about 15% of the population falls into this group. Wolves are more productive in the later afternoon and evening.
Sleep experts recommend that wolves set their alarm for 7 a.m. (snooze for 30 minutes) and go to sleep by midnight.
Lions are the new early birds. Like these wild cats, you are most alert in the morning. You have no trouble waking up and getting to work. But, lions tend to feel the afternoon slump. And by the evening, they feel drained.
About 15% of the population identifies as a lion. Sleep experts recommend that lions wake up around 5:30 a.m. and go to sleep by 10:30 p.m.
No, you don’t need to hibernate. But, like these diurnal (awake during the day, asleep at night) creatures, you follow the solar cycle. Bears generally feel awake during the day and need 8-hours of solid sleep at night.
About 50% of the population falls into this category. This group is productive in the morning and struggles with the mid-afternoon slump. Sleep experts recommend that bears wake up around 7 a.m. and go to sleep by 11 p.m.
Dolphins “only sleep with half of their brain at a time?” Sound familiar? Well, this is the insomniac (often self-diagnosed) group. You might be anxious and have trouble turning your brain off at night. Dolphins usually don’t get a complete night’s sleep.
About 10% of the population falls in this category. And even though they wake-up tired, dolphins are most productive by mid-morning.
Sleep experts recommend that dolphins get up around 6 a.m. and try to sleep around midnight.
Who doesn’t want a better night’s sleep and a more productive day? Start scheduling your days based on your chronotypes! Once you know more about your chronotype, you can form sleep patterns that work with (not against!) your body’s natural rhythms.
So what are you waiting for? Here in Kaiyan, we are embracing our inner animals and start following our optimal sleep schedule.
www.ncbi.nlm.nih.gov/pmc/articles/PMC5479630/
Bellis, Rich. "How To Design Your Ideal Workday Based On Your Sleep Habits." Fast Company, 26 Nov. 2017,
Levi, Anthea. "This Is the Best Time of Day to Do Everything, According to Your Chronotype." Health.com, 31 Oct. 2016