intestine | The Paleo Mom

The Hormones of Hunger

January 29, 2013 in Hormone Regulation

I want to delve into the effects of diet and lifestyle on hunger and satiety signals in a series of upcoming posts. I am mostly interested in the hormone dysregulation that occurs during metabolic syndrome, but also in how to optimize diet, exercise, sleep and stress management to achieve an ideal weight.

The feeling of hunger is regulated by a complex system of hormones that interact with neurotransmitters and neurotransmitter receptors within the hypothalamus region of the brain. These hormones essentially activate or deactivate specific neurons in the hypothalamus that control hunger. These neurons have receptors to Neuropeptide Y (NPY), the essential neurotransmitter in regulating hunger. The hormones can increase or decrease hunger either through binding the receptors for NPY or increasing or decreasing NPY itself. Essentially a hormone will increase hunger if its expression activates these NPY neurons whereas you will feel satiated if a hormone’s expression deactivates the NPY neurons. The interplay between these hormones and your brain is complex and only partially understood. However, what scientists do know about these hormones can help inform our decisions and compulsions regarding diet and other lifestyle factors.

New hormones continue to be discovered and their roles in regulating appetite, satiety, metabolism and digestion continue to be studied. As the full list of hunger hormones grows, understanding the complex interplay between these hormones, the types of food you eat, and the amount of muscle and fat on your body quickly becomes overwhelming. I have tried to summarize the key players (at least as scientists currently understand them):

Hormones that tell your body you’re satiated:

Cholecystokinin (CCK) is secreted by the cells that line the duodenum (the first segment of the small intestine) when they detect the presence of fat. This causes the release of digestive enzymes from the pancreas and bile from the gallbladder. Increased levels of CCK signals to the stomach to slow down the speed of digestion so the small intestine can effectively digest the fats. CKK is also a neuropeptide similar to NPY and has a direct action on neurons in the brain to signal satiety. This is the most immediate hunger suppressing signal and is the reason why eating fat with your meals is so important.

Oxyntomodulin is released in response to protein and carbohydrates in the stomach and signals a change in energy status to the brain. Oxyntomodulin enhances digestion by delaying gastric emptying and decreasing gastric acid secretion.

Peptide YY (PYY) is released by cells that line the jejunum, ileum (the next two segments of the small intestine) and colon in response to feeding and is especially sensitive to protein. PYY signals to the gallbladder and pancreas to stop producing digestive enzymes. PYY is important in increasing the efficiency of digestion and nutrient absorption after meal by slowing down gastric emptying, slowing down the speed of digestion, and increasing water and electrolyte absorption in the colon. PYY interacts directly with NPY receptors in the hypothalamus in an inhibitory fashion, thereby turning off hunger signals.

Glucagon-Like Peptide-1 (GLP-1) is secreted in the ileum in response to carbohydrate, protein and fat. It rapidly enters the circulation and is one of the fastest and shortest-lived satiety signals. It inhibits acid secretion and gastric emptying in the stomach. GLP-1 also increases insulin secretion and decreases glucagon secretion. GLP-1 decreases hunger signals by reducing the amount of NPY.

Leptin plays a key role in regulating energy intake and energy expenditure, including appetite and metabolism. Leptin is released both by adipocytes (fat cells) and by the cells that line the stomach, so it signals both that the body is fed and that there is sufficient energy storage. This appetite inhibition is long-term, in contrast to the rapid inhibition of eating by CCK and the slower suppression of hunger between meals mediated by PYY. Leptin both rapidly inhibits NPY production and deactivates NPY neurons in the brain to signal that the body has had enough to eat, producing a feeling of satiety. It is one of the most important adipose derived hormones (read more in this post).

Adiponectin is secreted from adipose tissue into the bloodstream where it signals decreased gluconeogenesis (when the body converts fats and proteins into glucose for energy), increased glucose uptake, lipid catabolism (breaking down of fats), triglyceride clearance (storage of fats), increased insulin sensitivity, and control of energy metabolism. Adiponectin acts directly on NPY neurons similarly to leptin but with additive effects.

Hormones that tell your body you’re hungry:

Ghrelin is considered the main hunger hormone. It is secreted by the cells that line the stomach when the stomach is empty and also by the pancreas when it detects low blood sugar. Also, the liver secretes ghrelin when its glycogen storage runs low (and glucagon is high). When ghrelin is released into the circulation, it directly activates NPY neurons to stimulate appetite. Increased levels of ghrelin are directly associated with the sensation of hunger. It is considered the counterpart of the hormone leptin. Importantly, ghrelin is a potent stimulator of growth hormone (GH) secretion and regulates nutrient storage, thereby linking nutrient partitioning with growth and repair processes. Ghrelin activates several anti-inflammatory pathways in the body and promotes cell regeneration thereby promoting healing, especially within the gastrointestinal tract. Ghrelin regulates glucose homeostasis through a direct action on the pancreatic islet cells (the cells that secrete insulin). It is also important for memory function and gastrointestinal motility.

Cortisol is well-known as a stress hormone, but it has key roles in regulating metabolism and hunger. Cortisol levels determine whether the body uses glycogen stores or triglyceride stores for energy (stored carbohydrate or stored fat). Cortisol can also stimulate gluconeogenesis, the process of converting amino acids (proteins) and lipids (fats) into glucose in the liver. It is believed that cortisol directly influences food consumption by acting on NPY neurons in the brain as well as affecting the levels of NPY and leptin. Cortisol seems to have a particular effect on the desire to eat foods high in fat and sugar. This is why stress management (which really means controlling any factor that might mess with your natural cortisol levels) is so important.

Glucagon is a hormone secreted by the pancreas when it detects low blood glucose levels (typically between meals, but this can also happen as part of that “sugar crash” after eating something very high carbohydrate). Glucagon signals the liver to convert stored glycogen into glucose, which is released into the bloodstream, a process known as glycogenolysis. When glycogen stores are low, high glucagon levels drive gluconeogenesis, the process of creating glucose from amino acids and fatty acids. Increased glucagon amplifies the hunger sensation.

Insulin is secreted by the pancreas in reaction to high blood glucose levels (for more on insulin, see this post). Insulin causes cells in the liver, muscle, and fat tissue to take up glucose (and fatty acids in the case of adipocytes) from the blood, storing it as glycogen. While insulin is released as a result of eating carbohydrates, it paradoxically increases hunger as opposed to decreasing it. This is caused by direct action on the NPY neurons and is the reason why eating a carbohydrate-rich meal is not as satiating as eating a meal that includes fats and proteins. It also explains how quickly we feel hungry again after a high-sugar snack.

These hormones have important roles both in regulating aspects of digestion and signaling to the brain whether or not you need to eat. Many of these hormones are also critical in regulating your blood sugar both after a meal and between meals (fed and fasted states). Some of these hormones also affect other systems in the body, for example, interacting with the immune system and controlling inflammation. Understanding how your diet and lifestyle affect these hormones will help you make choices that regulate these hormones properly, allowing yourself to listen to your hunger cues and trust that your body knows what it’s doing. And regulating hunger hormones is a key part of healing and being healthy.

Tags: adiponectin, amino acid, appetite, carbohydrate, cholecystokinin, CKK, colon, cortisol, digestion, duedenum, eat, Fat, full, ghrelin, GLP-1, glucagon, glucgon-like, gut, hormone, hunger, hungry, ileum, insulin, intestine, jejunum, leptin, lipid, meal, metabolism, oxyntomodulin, paleo, Paleolithic, peptide, peptide-1, Protein, PYY, satiety, stomach, Sugar, why, YY
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How Long Does it Take the Gut to Repair after Gluten Exposure?

September 27, 2012 in FAQ, FAQ, Featured Posts, Gut Health

This is a very relevant question for those who are just embarking on their gluten-free journey. But, it’s also extremely important for anyone who has been following a paleo/primal/gluten-free diet for a while, but has been inadvertently exposed to gluten. It sometimes feels as though the longer we avoid gluten, the more sick we feel after accidentally eating some. This is in large part because the body stops protecting itself from gluten (for example, there may be less mucus in the gut) so when we do consume some, we are defenseless. It may also be because we forget how we used to feel and are so used to feeling so much healthier. Whether you are new to paleo or have been eating this way for a while, a common question is: how long does it take the gut to heal after gluten exposure?

I have talked about the irritation, inflammation and damage to the lining of the small intestine that can be caused gluten (I promise I will go back and add references to this post soon) and I have mentioned that it can take up to 6 months for the body to fully heal after a single gluten exposure. After delving into the research more thoroughly, I have discovered that this statement is simultaneously a gross understatement and an overstatement. Just like the extent of damage that gluten causes varies from individual to individual (see this post for a little bit more on variability in tolerance), so does the length of time it takes to recover. And it’s not as simple as the more damage you have, the longer it takes to recover. There are factors that control how sensitive you are (genetics, overall health, diet, stress, nutritional-deficiencies, gut microflora) and there are factors that affect how quickly you heal (okay, it’s the same list of factors, but it’s more complicated than A+B=C).

The cells that line the gut, called enterocytes or gut epithelial cells are organized into hills and valleys (to help maximize the surface area of the gut), forming finger-like columns of cells called villi separated by valleys called crypts. The enterocytes are constantly regenerating themselves (a pool or resident stem cells supplies the new enterocytes). As the cells age, they migrate higher up the villi and are eventually shed into the gut to be redigested (yes, we are constantly cannibalizing ourselves). This is called the “turnover” of the gut epithelium. In the normal healthy gut, the enterocytes migrate to the top of the villi in in 1-4 days, meaning that all of the villi cells are replaced with new cells every 3-5 days (this gets slower as we age) ^1,2,3. The cells that migrate toward the bottom of the crypts have a longer lifespan of 2-3 weeks. What does this mean? A healthy person has an entirely new intestinal lining every 2-3 weeks.

Repairing the intestine following injury (whether that is caused by ingested toxins, infection, or some other injury) is a more involved and complex process that is tightly regulated and controlled by the body (for a detailed understanding of this process, see reference 4). The healing time varies depending on the extent of injury and studies trying to understand the role of the resident stem cells of the gut show that repair of the crypt and villi structure of the intestinal wall after injury can take anywhere from 2 to 12 weeks (depending on whether the stem cells themselves are injured) in the absence of confounding factors ^4,5.

What does this mean? For healthy individuals without celiac disease or gluten sensitivity (where their bodies are producing antibodies against gluten), the damage to individual cells and the junctions between them that can be caused by gluten is relatively fast to heal, anywhere from a few days to 3 weeks. For these healthy individuals, most of this time is likely asymptomatic. Many people report symptoms that only last from a couple of hours to a couple of days after gluten exposure. This also means that healthy individuals should be able to heal their guts completely after following a 30-day paleo challenge such as a Whole30.

For those with confounding factors, healing is slower. Confounding factors are numerous and include gluten sensitivity (where the body is producing antibodies against gluten which increases inflammation and slows healing), celiac disease (an autoimmune condition), uncontrolled inflammation in the gut (which could be caused by food allergies, food sensitivities or diseases such as Inflammatory Bowel Disease), nutritional deficiencies (which can be caused by having a very inflamed and damaged gut, but slows healing because not all of the raw materials needed to repair are available), gut dysbiosis (the wrong type, amount and/or location of microorganisms in the gut), infections, stress, body-wide inflammation, and chronically elevated insulin.

How much do these confounding factors slow healing? The extreme end of the spectrum is those with Celiac Disease, an autoimmune condition triggered by gluten exposure. One hallmark of Celiac Disease is a shortening or blunting of the intestinal villi which is observed by performing a biopsy of the small intestine (they are typically 3-5 times longer in healthy individuals than those with Celiac Disease). For those with celiac disease, one study showed that only 66% of patients had a normal intestinal biopsy after 5 years on a gluten-free diet ⁶. This means that even after 5 years, 34% of Celiac Disease sufferers had not recovered. There are no good similar studies evaluating intestinal repair in people with non-celiac gluten-sensitivity, but medical professionals who specialize in treating gluten-sensitivity report time frames of approximately 1½-2 years ⁷.

It’s probably worth mentioning here that current reports suggest that both Celiac Disease and gluten-sensitivity are ridiculously underdiagnosed. It is estimated that 1 in every 100 Americans suffer from Celiac Disease but only 5% are ever diagnosed ⁸. This means that there is something like 2.5-3 million Americans with celiac disease that have no idea that they have it (when you extrapolate this statistic globally, it’s even scarier!). Gluten intolerance is estimated to affect 15-20% of the population ⁹. The take home message here? Even if you have never been diagnosed with celiac disease or gluten intolerance, you may have one of these conditions which could be contributing to slowed intestinal repair after switching to a paleo diet or after accidental gluten exposure.

How much gluten can cause a problem? This is highly individual. For those with Celiac disease (whether confirmed or undiagnosed), even a minute amount of gluten can cause significant damage to the small intestine in the majority of sufferers ¹⁰. Interestingly, a not unsubstantial percentage of these people (22%) will have significant damage to their small intestine but not suffer any gastrointestinal symptoms. For healthy individuals, the threshold amount to suffer symptoms is highly variable. Unfortunately, you don’t know until you test it on yourself.

So, how long does it take the gut to repair after gluten exposure? Once again, like so many topics I cover on this blog, the answer is “it depends”. For healthy individuals, healing likely takes only a couple of weeks. For those with celiac disease (and perhaps autoimmune diseases in general), fully healing the lining of the small intestine may take years. The rest of us can be anywhere in between.

1 Creamer B et al. “The turnover and shedding of epithelial cells–Part I The turnover in the gastro-intestinal tract”. Gut 1961 2: 110-116

2 Lipkin M et al. “Cell Proliferation Kinetics In The Gastrointestinal Tract Of Man. I. Cell Renewal In Colon And Rectum” J Clin Invest. 1963 June; 42(6): 767–776.

3 Godlewski MM et al “Into the Unknown–The Death Pathways in the Neonatal Gut Epithelium” Current Pediatric Reviews. 2011. 7(4):337-345

4 Blikslager AT et al. “Restoration of Barrier Function in Injured Intestinal Mucosa” Physiol Rev 87:545-564, 2007.

5 Booth C and Potten CS “Gut instincts: thoughts on intestinal epithelial stem cells” J Clin Invest. 2000;105(11):1493–1499.

6 Rubio-Tapia A “Mucosal recovery and mortality in adults with celiac disease after treatment with a gluten-free diet.” Am J Gastroenterol. 2010 Jun;105(6):1412-20.

7 http://glutendoctors.blogspot.com/2010/04/healing-time-after-removing-gluten.html

8 Lohi S et al. “Increasing prevalence of coeliac disease over time.” Aliment Pharmacol Ther. 2007 Nov 1;26(9):1217-25.

9 http://www.gastroendonews.com/ViewArticle.aspx?d=In%2Bthe%2BNews&d_id=187&i=October%2B2010&i_id=672&a_id=16015

10 Lähdeaho ML et al. “Small- bowel mucosal changes and antibody responses after low- and moderate-dose gluten challenge in celiac disease.” BMC Gastroenterol. 2011 Nov 24;11:129.

Tags: ancestral, celiac, crypt, damage, Diet, disease, enterocyte, epithelial, epithelium, Gluten, gut, heal, how long, inflammation, intestinal permeability, intestine, intolerance, leaky, paleo, Paleolithic, prevalence, primal, rate, Repair, sensitivity, tight junction, time, turnover, villi, villus
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