Understanding The Connection Between Sleep And Diabetes
One of the most serious health consequences that comes from disrupted, poor quality sleep is a significantly increased risk for diabetes. The relationship between sleep and diabetes is complicated, and scientists are still working to understand all the ways that sleep and circadian rhythms (also known as your internal biological clock) affect this disease. That said, we have some hints, since we know sleep has a powerful connection to metabolism (how our body uses food for energy), to hormones that regulate appetite and eating patterns, and to the body’s use of blood sugar and insulin.
Sleep is essential for metabolic health
Sleep is an important time for restoration and repair of the body at a cellular level. That includes maintenance of the immune system (which keeps us from getting sick) and of the body’s metabolic functions. Stages 3 & 4 called deep or, slow-wave sleep — appear be especially important to the body’s ability to use insulin to regulate blood sugar.
Poor sleep affects diabetes both directly and indirectly, by triggering changes to hormones, contributing to weight gain and obesity, and causing changes to behavior and lifestyle.
- Sleep disruption increases the risks for type 2 diabetes
- People with diabetes are much more likely to have obstructive sleep apnea and other sleep disorders
- The more severe sleep problems are, the more severe—and less well controlled—diabetes is likely to be
There’s a lot of attention paid to short sleep and its risks. And rightly so. At middle age and during older adulthood, people who report not getting enough sleep are roughly twice as likely to be diagnosed with type 2 diabetes, according to several large-scale studies.
Over the past several decades, we’ve seen a rise in the number of people with chronic sleep deprivation, obesity, and diabetes. That’s not coincidental, the rises in these serious public health problems—sleep deprivation, obesity, and diabetes—appear to be connected.
- According to Centers for Disease control figures released in 2017, more than 100 million Americans currently have diabetes or prediabetes. That’s close to a third of the population. Nearly 1 in 4 people with diabetes don’t know they have it, according to the CDC report. And almost 90 percent of people with prediabetes aren’t aware of their condition.
- At the same time, more than a third of Americans are routinely getting less sleep than they need. For most of us, that’s in the neighborhood of 7 hours a night.
- And currently, more than 36 percent of adults in the US are obese. Obesity is a prime risk factor for diabetes—and overwhelming scientific evidence shows poor sleep contributes to obesity. Obesity has doubled worldwide over the past nearly four decades, and during that same period, rates of insufficient sleep have increased.
But not sleeping enough isn’t the only sleep problem that can increase risk for diabetes, and compromise its effective management. We know from scientific research that in addition to a lack of quantity, poor sleep quality can also interfere with the body’s metabolic functioning and elevate risks for the disease. It comes as a surprise to many of my patients, but there’s also increasing evidence that sleeping too much can also raise risks for diabetes.
And scientists are increasingly investigating the role circadian rhythms (your biological clock) play in the development of diabetes. Circadian rhythms affect so many areas of your health, many of which you might not be aware of. In addition to sleep-wake cycles, circadian rhythms also regulate hormones that affect metabolism, appetite, insulin, and blood glucose. When circadian rhythms are out of sync, the body’s metabolic health can decline—and a risk for diabetes can increase.
When we think about sleep and its influence over diabetes, it’s important to consider not only amounts of sleep, but sleep quality, sleep habits and sleep patterns.
Despite the increasingly strong evidence linking sleep to diabetes, sleep problems remain an overlooked factor in the risks for, and management of, the disease. Let’s take a closer look at the ways poor sleep can affect the development of diabetes, and the health of people who are living with the condition.
Poor sleep interferes with insulin and blood glucose
Among the more recent discoveries scientists have made about the sleep and diabetes connection is this important one: poor sleep changes how the body produces and uses insulin.
Insulin is a hormone produced by the pancreas that enables cells in muscles and tissues of the body to absorb glucose from the bloodstream, to be used for energy. In this way, insulin regulates blood glucose—or blood sugar–helping maintain a glucose homeostasis that is neither too high (hyperglycemia) nor too low (hypoglycemia). I often tell my patients to think of insulin like the key to a lock, or the doorman to a hotel, allowing glucose to exit the blood and enter cells.
Cells can become resistant to insulin, making them less able to absorb glucose from the blood. In this case our “key” may not be working as smoothly as we would like. This leads to persistently high levels of glucose (i.e., sugar) in the blood—which, in turn, triggers the body to increase production of insulin, because of high blood sugar. Sometimes, the body under-produces insulin, which also results in high blood sugar. Over time, this dynamic of high blood sugar and insulin resistance (or lack of sufficient insulin production), can lead to the development of type 2 diabetes. In type 1 diabetes, a person’s body can’t make insulin naturally (very different, but also affected by sleep).
Recent research indicates that insulin—like many other hormones and body systems—operates on a daily cycle. Scientists now think the body’s circadian clock directs this cycle by affecting the timing of the production and release of insulin from the pancreas. And there also appear to be certain times of the day when cells are more, and less, sensitive to insulin. Disruptions to circadian clocks—which often go hand-in-hand with sleep problems—appear to reduce the effectiveness of insulin and, over time, contribute to insulin resistance. Because insulin’s job is to regulate blood glucose, changes to insulin create changes to blood sugar.
Circadian rhythms can be thrown off sync by:
- Irregular sleep schedules (like shift work, being a new parent, etc.),
- Patterns of poor quality, restless sleep (from the effects of your environment or use of caffeine)
- The presence of sleep disorders, (insomnia and sleep apnea),
- Too much or too little sleep
Lack of sleep also appears to affect the health of cells in the pancreas, where insulin is made and released. In a study using mice, scientists recently investigated the effects of sleep deprivation on cell function, and found that insufficient sleep created stress in pancreatic cells, and also disrupted blood glucose levels. Both the cellular stress and the disruptions to blood sugar were more pronounced in older mice, suggesting the body becomes less adept at coping with the impact of sleep deprivation over time.
Sleep itself affects insulin activity and blood sugar
According to a growing body of research, insufficient and poor-quality sleep can decrease insulin sensitivity and decrease glucose tolerance (a measurement of how quickly and effectively the body removes glucose from the bloodstream). And it doesn’t take months or years for these negative effects to kick in.
A single night of total sleep deprivation decreased insulin sensitivity more than 6 months of a high-fat diet, according to a 2016 study.
Partial sleep deprivation—the kind of chronic sleep debt many people experience on a routine basis—decreases the body’s ability to use insulin effectively, and keep blood sugar balanced. After a week of sleeping 5 hours a night, a group of healthy men saw significant reductions to insulin sensitivity, reported scientists in a 2010 study.
Living with a chronic sleep loss also diminishes glucose tolerance, making the body less effective at converting glucose to energy. And disrupted sleep interferes with the body’s ability to regulate glucose throughout the day and night.
Sleep affects other hormones that influence metabolic health
Sleep deprivation also increases production of cortisol, which can make cells more resistant to insulin. Lack of sleep also triggers changes to other hormones, including thyroid stimulating hormone (TSH) and testosterone, which can lead to decreased insulin sensitivity and higher blood glucose.
Melatonin, which plays such a critical role in maintaining regular sleep patterns in keeping our circadian clocks synchronized, also appears to affect insulin. We’ve known for several years that certain gene variants associated with melatonin receptors are strongly linked to higher risks for type 2 diabetes. Recent research has shown higher levels of melatonin reduce the ability of insulin-making cells in the pancreas to release insulin—and that people with those genetic variants experience this insulin-suppressing effect more strongly.
All these changes sleep and circadian-related changes—to insulin and blood sugar, and other hormones that affect metabolism occur in healthy and non-diabetic people, bringing them closer to prediabetes and eventually diabetes. These sleep-related changes also happen in people who have diabetes, making the condition harder to treat and control effectively.
Sleep’s role in diet and weight raise risks for diabetes
Obesity is the single most important predictor in the development of type 2 diabetes. More than 90 percent of people with type 2 diabetes are overweight or obese. Scientists have referred to the simultaneous rise of obesity and diabetes as “twin epidemics.”
Sleep has a strong influence over appetite and eating patterns, exercise habits, and the hormones that regulate hunger and the feeling of fullness. In all these ways, sleep plays a powerful role in risks for obesity. You’ve seen how sleep can affect diabetes directly through its effects on insulin and blood sugar. Sleep also affects diabetes indirectly, because of its impact on body weight.
Poor quality and insufficient sleep alter hunger hormones. When we don’t get enough high-quality sleep, levels of the hormone leptin go down. Leptin is a hormone that helps maintain energy balance in the body. It curbs appetite, sending signals that you’ve consumed enough energy through calorie intake—signals that translate into feelings of fullness. Leptin also helps regulate metabolism and the rate at which the body burns fat. Lower leptin levels slow metabolism down. Poor sleep may also make the body resistant to leptin’s appetite-curbing effects. And recent research indicates leptin plays a direct role in regulating blood glucose. Scientists are looking at leptin—not for the first time—as a possible treatment for obesity and diabetes. Sleeping well is one way to keep your body supplied with leptin naturally.
At the same time poor sleep lowers leptin, it also increases levels of another hormone important to energy balance and weight: ghrelin. Sometimes referred to as the “hunger hormone,” ghrelin stimulates appetite, increasing hunger and the desire to eat, and throwing the body’s energy balance off kilter, with more calories being consumed than burned.
This double-hit of hormone imbalance—reduced leptin and increased ghrelin—can make it difficult to maintain a healthy weight, leading to weight gain, and an elevated risk for diabetes. It also makes weight harder to control in people with prediabetes and diabetes.
Poor sleep makes us more sedentary. When you’re not rested—whether because you’re not getting enough sleep, or sleep is restless and disrupted—you tend to expend less energy in physical activity. Regular exercise is one important way to lower risk for diabetes, and manage the condition more effectively if you have it.
We eat the wrong things at the wrong times. Lack of sleep creates cravings for high-fat and high-sugar foods—the type of diet that, over time, can lead to diabetes, and also makes diabetes more difficult to control. When we’re sleep deprived, our brain’s reward centers go into overdrive. We also become more impulsive, and less able to execute complex judgment and decision making, the cognitive functions that enable us to make healthful, moderate food decisions. This makes us more likely to overeat.
Sleep deprivation can make us eat more overall (one analysis suggests an additional 385 calories a day!), and cause us to eat less healthfully. Poor sleep also shifts a larger share of daily calorie intake to the evening hours. People who sleep poorly also tend to consume more of their calories later in the day. Nighttime eating disrupts circadian function, contributing to weight gain and also to problems with insulin and blood sugar. Nighttime eating also disrupts sleep itself, setting up a vicious cycle of disrupted sleep and eating habits.
Next, we’ll look at the specific sleep problems and sleep disorders linked to diabetes, including the close connection between sleep apnea and diabetes. I’ll also talk about how the symptoms of diabetes can interfere with sleep.
Michael J. Breus, PhD, DABSM
The Sleep Doctor™
AL Khatib, HK et al. (2017). The effects of partial sleep deprivation on energy balance: a systematic review and meta-analysis. European Journal of Clinical Nutrition, 71: 614-624. Retrieved from: https://www.nature.com/articles/ejcn2016201
American Diabetes Association. What can physical activity do for me? Retrieved from: http://www.diabetes.org/are-you-at-risk/lower-your-risk/activity.html
American Society for Metabolic and Bariatric Surgery. (2013 November). Type 2 diabetes and obesity: twin epidemics. Retrieved from: https://asmbs.org/resources/weight-and-type-2-diabetes-after-bariatric-surgery-fact-sheet
Anwar, Y. (2013, August 6) Sleep deprivation linked to junk food cravings. UC Berkeley News. Retrieved from: http://news.berkeley.edu/2013/08/06/poor-sleep-junk-food/
Beccuti, G and Pannain, S. (2011). Sleep and Obesity. Current Opinion in Clinical Nutrition and Metabolic Care, 14(4): 402-412. Retrieved from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3632337/
Bloomgarden, Z.T. (2004, June 18). The twin epidemics of obesity and diabetes. Medscape. Retrieved from: https://www.medscape.com/viewarticle/480752
Breus, MJ. (2015, July 29). Eating at night disrupts sleep. Huffington Post. Retrieved from: https://www.huffingtonpost.com/dr-michael-j-breus/eating-at-night-disrupts-sleep_b_7867760.html
Breus, MJ. (2018, April 10). Here’s what really happens when you’re sleep deprived. Retrieved from: https://www.thesleepdoctor.com/2018/04/10/sleep-deprivation/
Buxton, O.M. (2010). Sleep restriction for 1 week reduces insulin sensitivity in healthy men. Diabetes, 59(9): 2126-2133. Retrieved from: http://diabetes.diabetesjournals.org/content/59/9/2126
Centers for Disease Control and Prevention. (2017, July 17). More than 100 million Americans have diabetes or prediabetes. Retrived from: https://www.cdc.gov/media/releases/2017/p0718-diabetes-report.html
Centers for Disease Control and Prevention. (2016, February 19). Prevalence of Healthy Sleep Duration among Adults — United States, 2014. Retrieved from: https://www.cdc.gov/mmwr/volumes/65/wr/mm6506a1.htm
Centers for Disease Control and Prevention. Adult Obesity Facts. Retrieved from: https://www.cdc.gov/obesity/data/adult.html
Fennell, D. (2015, November 27). Sleep well to avoid insulin resistance, study suggests. Diabetes Self-Management. Retrieved from: https://www.diabetesselfmanagement.com/blog/sleep-well-to-avoid-insulin-resistance-study-suggests/
Fetters, K.A. (2015, June 6). Will eating at night really make you gain weight? US News & World Report. Retrieved from: https://health.usnews.com/health-news/health-wellness/articles/2015/06/26/will-eating-at-night-really-make-you-gain-weight
Fischl-Hess, A. (2017, April 7). What is insulin? Retrieved from: https://www.endocrineweb.com/conditions/type-1-diabetes/what-insulin
Gangwisch, JE. (2009). Epidemiological evidence for the links between sleep, circadian rhythms and metabolism. Obesity reviews, 10 Suppl 2: 37-45. Retrieved from: https://www.ncbi.nlm.nih.gov/pubmed/19849800
Greer, SM et al. (2013). The impact of sleep deprivation on food desire in the human brain. Nature Communications, 4: 2259. Retrieved from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3763921/
Harvard T.H. Chan School of Public Health. Too little or too much sleep may raise diabetes risk in women. Retrieved from: https://www.hsph.harvard.edu/news/hsph-in-the-news/too-little-or-too-much-sleep-may-raise-diabetes-risk-in-women/
Heisman Saey, T. (2013, February 22). Insulin levels wax and wane daily. Science News. Retrieved from: https://www.sciencenews.org/article/insulin-levels-wax-and-wane-daily
Holmang A and Bjorntorp, P. (1992). The effects of cortisol on insulin sensitivity in muscle. Acta Physiologica Scandinavica, 144(4): 425-61. Retrieved from: https://www.ncbi.nlm.nih.gov/pubmed/1605044
Joslin Diabetes Center. (n.d.) What is insulin resistance? Retrieved from: http://www.joslin.org/info/what_is_insulin_resistance.html
Lee, JA et al. (2016). The Effect of Sleep Quality on the Development of Type 2 Diabetes in Primary Care Patients. Journal of Korean Medical Science, 31(2): 240-246. Retrieved from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4729504/
Meek, TH and Morton GJ. (2016). The role of leptin in diabetes: metabolic effects. Diabetologia, 59(5): 928-32. Retrieved from: https://www.ncbi.nlm.nih.gov/pubmed/26969486
Mesarwi, O. et al. (2013). Sleep disorders and the development of insulin resistance and obesity. Endocrinology and Metabolic Clinics of North America, 42(3): 617-634. Retrieved from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3767932/
Northwestern Now. (2015, November 6). Circadian clock controls insulin and blood sugar in pancreas. Retrieved from: https://news.northwestern.edu/stories/2015/11/circadian-clock-controls-insulin-and-blood-sugar-in-pancreas
Paddock, C. (2016, May 17). Type 2 diabetes: study explains link to sleep hormone melatonin. Medical News Today. Retrieved from: https://www.medicalnewstoday.com/articles/310321.php
Quarta, C. et al. (2016). Renaissance of leptin for obesity therapy. Diabetologia, 59(5): 920-7. Retrieved from: https://www.ncbi.nlm.nih.gov/pubmed/26983921
Rappaport, Lisa. (2016, July 15). More evidence poor sleep habits may raise diabetes risk. Reuters. Retrieved from: https://www.reuters.com/article/us-health-sleep-insulin-resistance/more-evidence-poor-sleep-habits-may-raise-diabetes-risk-idUSKCN0ZV2A3
Rosenbaum, M and Liebel, RL (2014). Role of leptin in energy homeostasis in humans. Journal of Endocrinology, 223(1): T83-T96. Retrieved from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4454393/
Russell, P. (2016, July 1). Does too much sleep increase diabetes risk? WebMD Health News. Retrieved from: https://www.medscape.com/viewarticle/865647
Scheen, AJ et al. (1996). Relationships between sleep quality and glucose regulation in normal humans. The American Journal of Physiology, 271(2 Pt 1): E261-70. Retrieved from: https://www.ncbi.nlm.nih.gov/pubmed/8770019
Schmid, SM et al. (2008). A single night of sleep deprivation increases ghrelin levels and feelings of hunger in normal-weight healthy men. Journal of Sleep Research, 17(3): 331-4. Retrieved from: https://www.ncbi.nlm.nih.gov/pubmed/18564298
Spiegel, K. et al. (1999). Impact of sleep debt on metabolic and endocrine function. Lancet, 354(9188): 1435-9. Retrieved from: https://www.ncbi.nlm.nih.gov/pubmed/10543671
Taheri, S. et al. (2004). Short Sleep Duration Is Associated with Reduced Leptin, Elevated Ghrelin, and Increased Body Mass Index. PLoS Medicine, 1(3): e62. Retrieved from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC535701/
Tan, E and Scott EM. (2017). Circadian rhythms, insulin action, and glucose homeostasis. Current Opinion in Clinical Nutrition and Metabolic Care, 17(4): 343-8. Retrieved from: https://www.ncbi.nlm.nih.gov/pubmed/24810916
University of Cambridge. (2012, February 2). Genetic link between melatonin and diabetes. Retrieved from: http://www.phgfoundation.org/news/genetic-link-between-melatonin-and-diabetes
Weber, Belinda. (2013, December 16). Sleep deprivation and increased age linked to diabetes. Medical News Today. Retrieved from: https://www.medicalnewstoday.com/articles/270120.php