I often focus on the bigger facets of the disease of civilization. Things like cardiovascular disease and cancer, which are major killers and the subject of intensive research. But the disease of civilization is a spectrum of disorders that affects the body in countless ways, large and small.
I recently read an interesting paper written by an all-star cast, including Loren Cordain, Staffan Lindeberg and Boyd Eaton. It's titled "Acne Vulgaris: A Disease of Western Civilization". The paper presents data from two different groups, the Kitavans of Papua New Guinea and the Ache hunter-gatherers of Paraguay. Both were systematically examined by doctors trained to diagnose acne. Out of 1,200 Kitavans and 115 Ache of all ages, not a single case of acne was observed. Hunter-gatherers and other healthy non-industrial cultures have nice skin. I dare you to find a pimple in Nutrition and Physical Degeneration.
In Western societies, acne is a fact of life. The paper states that 79 to 95% of modern adolescents suffer from some degree of acne, along with about 50% of young adults. That's an enormous difference.
The paper presents a very Cordain-esque hypothesis to explain the high incidence of acne in Western societies. In sum, they state that the Western diet causes hyperinsulinemia, which is thought to promote acne. This is due to insulin's effects on skin cell proliferation, its interference with the retinoid (vitamin A) signaling pathway, and its effect on sebum production.
They then proceed to point the finger at the glycemic index/load of the Western diet as the culprit behind hyperinsulinemia. It's an unsatisfying explanation because the Kitavans eat a diet that has a high glycemic load due to its high carbohydrate content, low fat content, and relatively high-glycemic index foods. I think the answer is more likely to reside in the specific types of carbohydrate (processed wheat) rather than their speed of digestion, with possible contributions from refined vegetable oil and an excessive sugar intake.
Showing posts sorted by date for query skin. Sort by relevance Show all posts
Showing posts sorted by date for query skin. Sort by relevance Show all posts
Monday, September 29, 2008
Wednesday, August 13, 2008
The Kitavans: Wisdom from the Pacific Islands
There are very few cultures left on this planet that have not been affected by modern food habits. There are even fewer that have been studied thoroughly. The island of Kitava in Papua New Guinea is host to one such culture, and its inhabitants have many profound things to teach us about diet and health.
The Kitava study, a series of papers produced primarily by Dr. Staffan Lindeberg and his collaborators, offers a glimpse into the nutrition and health of an ancient society, using modern scientific methods. This study is one of the most complete and useful characterizations of the diet and health of a non-industrial society I have come across. It's also the study that created, and ultimately resolved, my cognitive dissonance over the health effects of carbohydrate.
From the photos I've seen, the Kitavans are beautiful people. They have the broad, attractive faces, smooth skin and excellent teeth typical of healthy non-industrial peoples.
Like the Kuna, Kitavans straddle the line between agricultural and hunter-gatherer lifestyles. They eat a diet primarily composed of tubers (yam, sweet potato, taro and cassava), fruit, vegetables, coconut and fish, in order of calories. This is typical of traditional Pacific island cultures, although the relative amounts differ.
Grains, refined sugar, vegetable oils and other processed foods are virtually nonexistent on Kitava. They get an estimated 69% of their calories from carbohydrate, 21% from fat, 17% from saturated fat and 10% from protein. Most of their fat intake is saturated because it comes from coconuts. They have an omega-6 : omega-3 ratio of approximately 1:2. Average caloric intake is 2,200 calories per day (9,200 kJ). By Western standards, their diet is high in carbohydrate, high in saturated fat, low in total fat, a bit low in protein and high in calories.
Now for a few relevant facts before we really start diving in:
Overall, Kitavans possess a resistance to degenerative diseases that is baffling to industrialized societies. Not only is this typical of non-industrial cultures, I believe it represents the natural state of existence for Homo sapiens. Like all other animals, humans are healthy and robust when occupying their preferred ecological niche. Our niche happens to be a particularly broad one, ranging from near-complete carnivory to plant-rich omnivory. But it does not include large amounts of industrial foods.
In the next few posts, I'll discuss more specific data about the health of the Kitavans.
The Kitava study, a series of papers produced primarily by Dr. Staffan Lindeberg and his collaborators, offers a glimpse into the nutrition and health of an ancient society, using modern scientific methods. This study is one of the most complete and useful characterizations of the diet and health of a non-industrial society I have come across. It's also the study that created, and ultimately resolved, my cognitive dissonance over the health effects of carbohydrate.
From the photos I've seen, the Kitavans are beautiful people. They have the broad, attractive faces, smooth skin and excellent teeth typical of healthy non-industrial peoples.
Like the Kuna, Kitavans straddle the line between agricultural and hunter-gatherer lifestyles. They eat a diet primarily composed of tubers (yam, sweet potato, taro and cassava), fruit, vegetables, coconut and fish, in order of calories. This is typical of traditional Pacific island cultures, although the relative amounts differ.
Grains, refined sugar, vegetable oils and other processed foods are virtually nonexistent on Kitava. They get an estimated 69% of their calories from carbohydrate, 21% from fat, 17% from saturated fat and 10% from protein. Most of their fat intake is saturated because it comes from coconuts. They have an omega-6 : omega-3 ratio of approximately 1:2. Average caloric intake is 2,200 calories per day (9,200 kJ). By Western standards, their diet is high in carbohydrate, high in saturated fat, low in total fat, a bit low in protein and high in calories.
Now for a few relevant facts before we really start diving in:
- Kitavans are moderately active. They have an activity level comparable to a moderately active Swede, the population to which Dr. Lindeberg draws frequent comparisons.
- They have abundant food, and shortage is uncommon.
- Their good health is probably not related to genetics, since genetically similar groups in the same region are exquisitely sensitive to the ravages of industrial food. Furthermore, the only Kitavan who moved away from the island to live a modern life is also the only fat Kitavan.
- Their life expectancy at birth is estimated at 45 years (includes infant mortality), and life expectancy at age 50 is an additional 25 years. This is remarkable for a culture with limited access to modern medicine.
- Over 75% of Kitavans smoke cigarettes, although in small amounts. Even the most isolated societies have their modern vices.
For the whole of PNG, no case of IHD or atherothrombotic stroke has been reported in clinical investigations and autopsy studies among traditionally living Melanesians for more than seven decades, though an increasing number of myocardial infarctions [heart attacks] and angina pectoris in urbanized populations have been reported since the 1960s.Dementia was not found except in in two young Kitavans, who were born handicapped. The elderly remained sharp until death, including one man who reached 100 years of age. Kitavans are also unfamiliar with external cancers, with the exception of one possible case of breast cancer in an elderly woman.
Overall, Kitavans possess a resistance to degenerative diseases that is baffling to industrialized societies. Not only is this typical of non-industrial cultures, I believe it represents the natural state of existence for Homo sapiens. Like all other animals, humans are healthy and robust when occupying their preferred ecological niche. Our niche happens to be a particularly broad one, ranging from near-complete carnivory to plant-rich omnivory. But it does not include large amounts of industrial foods.
In the next few posts, I'll discuss more specific data about the health of the Kitavans.
Wednesday, July 16, 2008
Sunscreen and Melanoma
Melanoma is the most deadly type of skin cancer, accounting for most skin cancer deaths in the US. As Ross pointed out in the comments section of the last post, there is an association between severe sunburn at a young age and later development of melanoma. Darker-skinned people are also more resistant to melanoma. The association isn't complete, however, since melanoma sometimes occurs on the soles of the feet and even in the intestine. This may be due to the fact that there are several types of melanoma, potentially with different causes.
Another thing that associates with melanoma is the use of sunscreen above a latitude of 40 degrees from the equator. In the Northern hemisphere, 40 degrees draws a line between New York city and Beijing. A recent meta-analysis found consistently that sunscreen users above 40 degrees are at a higher risk of melanoma than people who don't use sunscreen, even when differences in skin color are taken into account. Wearing sunscreen decreased melanoma risk in studies closer to the equator. It sounds confusing, but it makes sense once you know a little bit more about UV rays, sunscreen and the biology of melanoma.
The UV light that reaches the Earth's surface is composed of UVA (longer) and UVB (shorter) wavelengths. UVB causes sunburn, while they both cause tanning. Sunscreen blocks UVB, preventing burns, but most brands only weakly block UVA. Sunscreen allows a person to spend more time in the sun than they would otherwise, and attenuates tanning. Tanning is a protective response (among several) by the skin that protects it against both UVA and UVB. Burning is a protective response that tells you to get out of the sun. The result of diminishing both is that sunblock tends to increase a person's exposure to UVA rays.
It turns out that UVA rays are more closely associated with melanoma than UVB rays, and typical sunscreen fails to prevent melanoma in laboratory animals. It's also worth mentioning that sunscreen does prevent more common (and less lethal) types of skin cancer.
Modern tanning beds produce a lot of UVA and not much UVB, in an attempt to deliver the maximum tan without causing a burn. Putting on sunscreen essentially does the same thing: gives you a large dose of UVA without much UVB.
The authors of the meta-analysis suggest an explanation for the fact that the association changes at 40 degrees of latitude: populations further from the equator tend to have lighter skin. Melanin blocks UVA very effectively, and the pre-tan melanin of someone with olive skin is enough to block most of the UVA that sunscreen lets through. The fair-skinned among us don't have that luxury, so our melanocytes get bombarded by UVA, leading to melanoma. This may explain the incredible rise in melanoma incidence in the US in the last 35 years, as people have also increased the use of sunscreen. It may also have to do with tanning beds, since melanoma incidence has risen particularly in women.
In my opinion, the best way to treat your skin is to tan gradually, without burning. Use clothing and a wide-brimmed hat if you think you'll be in the sun past your burn threshold. If you want to use sunscreen, make sure it blocks UVA effectively. Don't rely on the manufacturer's word; look at the ingredients list. It should contain at least one of the following: titanium dioxide, zinc oxide, avobenzone (Parsol 1789), Mexoryl SX (Tinosorb). It's best if it's also paraben-free.
Fortunately, as an external cancer, melanoma is easy to diagnose. If caught early, it can be removed without any trouble. If caught a bit later, surgeons may have to remove lymph nodes, which makes your face look like John McCain's. Later than that and you're probably a goner. If you have any questions about a growth, especially one with irregular borders that's getting larger, ask your doctor about it immediately!
Another thing that associates with melanoma is the use of sunscreen above a latitude of 40 degrees from the equator. In the Northern hemisphere, 40 degrees draws a line between New York city and Beijing. A recent meta-analysis found consistently that sunscreen users above 40 degrees are at a higher risk of melanoma than people who don't use sunscreen, even when differences in skin color are taken into account. Wearing sunscreen decreased melanoma risk in studies closer to the equator. It sounds confusing, but it makes sense once you know a little bit more about UV rays, sunscreen and the biology of melanoma.
The UV light that reaches the Earth's surface is composed of UVA (longer) and UVB (shorter) wavelengths. UVB causes sunburn, while they both cause tanning. Sunscreen blocks UVB, preventing burns, but most brands only weakly block UVA. Sunscreen allows a person to spend more time in the sun than they would otherwise, and attenuates tanning. Tanning is a protective response (among several) by the skin that protects it against both UVA and UVB. Burning is a protective response that tells you to get out of the sun. The result of diminishing both is that sunblock tends to increase a person's exposure to UVA rays.
It turns out that UVA rays are more closely associated with melanoma than UVB rays, and typical sunscreen fails to prevent melanoma in laboratory animals. It's also worth mentioning that sunscreen does prevent more common (and less lethal) types of skin cancer.
Modern tanning beds produce a lot of UVA and not much UVB, in an attempt to deliver the maximum tan without causing a burn. Putting on sunscreen essentially does the same thing: gives you a large dose of UVA without much UVB.
The authors of the meta-analysis suggest an explanation for the fact that the association changes at 40 degrees of latitude: populations further from the equator tend to have lighter skin. Melanin blocks UVA very effectively, and the pre-tan melanin of someone with olive skin is enough to block most of the UVA that sunscreen lets through. The fair-skinned among us don't have that luxury, so our melanocytes get bombarded by UVA, leading to melanoma. This may explain the incredible rise in melanoma incidence in the US in the last 35 years, as people have also increased the use of sunscreen. It may also have to do with tanning beds, since melanoma incidence has risen particularly in women.
In my opinion, the best way to treat your skin is to tan gradually, without burning. Use clothing and a wide-brimmed hat if you think you'll be in the sun past your burn threshold. If you want to use sunscreen, make sure it blocks UVA effectively. Don't rely on the manufacturer's word; look at the ingredients list. It should contain at least one of the following: titanium dioxide, zinc oxide, avobenzone (Parsol 1789), Mexoryl SX (Tinosorb). It's best if it's also paraben-free.
Fortunately, as an external cancer, melanoma is easy to diagnose. If caught early, it can be removed without any trouble. If caught a bit later, surgeons may have to remove lymph nodes, which makes your face look like John McCain's. Later than that and you're probably a goner. If you have any questions about a growth, especially one with irregular borders that's getting larger, ask your doctor about it immediately!
Tuesday, June 17, 2008
Vitamin K2, menatetrenone (MK-4)
Weston Price established the importance of the MK-4 isoform of vitamin K2 (hereafter, K2) with a series of interesting experiments. He showed in chickens that blood levels of calcium and phosphorus depended both on vitamin A and K2, and that the two had synergistic effects on mineral absorption. He also showed that chickens preferred eating butter that was rich in K2 over butter low in K2, even when the investigators couldn't distinguish between them. Young turkeys fed K2-containing butter oil along with cod liver oil (A and D) also grew at a much faster rate than turkeys fed cod liver oil alone.
He hypothesized that vitamin A, vitamin D and vitamin K2 were synergistic and essential for proper growth and subsequent health. He particularly felt that the combination was important for proper mineral absorption and metabolism. He used a combination of high-vitamin cod liver oil and high-vitamin butter oil to heal cavities, reduce oral bacteria counts, and cure numerous other afflictions in his patients. He also showed that the healthy non-industrial groups he studied had a much higher intake of these fat-soluble, animal-derived vitamins than more modern cultures.
Price found an inverse correlation between the levels of K2 in butter and mortality from cardiovascular disease and pneumonia in a number of different regions. A recent study examined the relationship between K2 (MK-4 through 10) consumption and heart attack risk in 4,600 Dutch men. They found a strong inverse association between K2 consumption and heart attack mortality risk. Men with the highest K2 consumption had a whopping 51% lower risk of heart attack mortality and a 26% lower risk of death from all causes compared to men eating the least K2! Their sources of K2 MK-4 were eggs, meats and dairy. They obtained MK-5 through MK-10 from fermented foods and fish. The investigators found no association with K1, the form found in plants.
Perigord, France is the world's capital of foie gras, or fatty goose liver. Good news for the bon vivants: foie gras turns out to be the richest known source of K2. Perigord also has the lowest rate of cardiovascular mortality in France, a country already noted for its low CVD mortality.
Rats fed warfarin, a drug that inhibits K2 recycling, develop arterial calcification. Feeding the rats K2 completely inhibits this effect. Mice lacking matrix Gla protein (MGP), a vitamin K-dependent protein that guards against arterial calcification, develop heavily calcified aortas and die prematurely. So the link between K2 and cardiovascular disease is a very strong one.
Mammals can synthesize K2 MK-4 from K1 to some degree, so dietary K1 and other forms of vitamin K may contribute to K2 MK-4 status.
The synergism Weston Price observed between vitamins A, D and K2 now has a solid mechanism. In a nutshell, vitamins A and D signal the production of some very important proteins, and K2 is required to activate them once they are made. Many of these proteins are involved in mineral metabolism, thus the effects Price saw in his experiments and observations in non-industrialized cultures. For example, osteocalcin is a protein that organizes calcium and phosphorus deposition in the bones and teeth. It's produced by cells in response to vitamins A and D, but requires K2 to perform its function. This suggests that the effects of vitamin D on bone health could be amplified greatly if it were administered along with K2. By itself, K2 is already highly protective against fractures in the elderly. It works out perfectly, since K2 also protects against vitamin D toxicity.
I'm not going to go through all the other data on K2 in detail, but suffice it to say it's very very important. I believe that K2 is a 'missing link' that explains many of our modern ills, just as Weston Price wrote. Here are a few more tidbits to whet your appetite: K2 may affect glucose control and insulin release (1, 2). It's concentrated in the brain, serving an as yet unknown function.
Hunter-gatherers didn't have multivitamins, they had nutrient-dense food. As long as you eat a natural diet containing some vegetables and some animal products, and lay off the processed grains, sugar and vegetable oil, the micronutrients will take care of themselves.
Vitamin K2, MK-4 is only found in animal products. The best sources known are grass-fed butter from cows eating rapidly growing grass, and foie gras. K2 tends to associate with beta-carotene in butter, so the darker the color, the more K2 it contains (also, the better it tastes). Fish eggs, other grass-fed dairy, shellfish, insects and other organ meats are also good sources. Chris Masterjohn compiled a list of food sources in his excellent article on the Weston Price foundation website. I highly recommend reading it if you want more detail. K2 MK-7 is found abundantly in natto, a type of fermented soybean, and it may be partially converted to MK-4.
Finally, you can also buy K2 supplements. The best one is butter oil, the very same stuff Price used to treat his patients. I have used this one personally, and I noticed positive effects on my skin overnight. Thorne research makes a synthetic liquid K2 MK-4 supplement that is easy to dose drop-wise to get natural amounts of it. Other K2 MK-4 supplements are much more concentrated than what you could get from food so I recommend avoiding them. I am generally against supplements, but I've ordered the Thorne product for a little self-experimentation. I want to see if it has the same effect on my skin as the butter oil (update- it does).
He hypothesized that vitamin A, vitamin D and vitamin K2 were synergistic and essential for proper growth and subsequent health. He particularly felt that the combination was important for proper mineral absorption and metabolism. He used a combination of high-vitamin cod liver oil and high-vitamin butter oil to heal cavities, reduce oral bacteria counts, and cure numerous other afflictions in his patients. He also showed that the healthy non-industrial groups he studied had a much higher intake of these fat-soluble, animal-derived vitamins than more modern cultures.
Price found an inverse correlation between the levels of K2 in butter and mortality from cardiovascular disease and pneumonia in a number of different regions. A recent study examined the relationship between K2 (MK-4 through 10) consumption and heart attack risk in 4,600 Dutch men. They found a strong inverse association between K2 consumption and heart attack mortality risk. Men with the highest K2 consumption had a whopping 51% lower risk of heart attack mortality and a 26% lower risk of death from all causes compared to men eating the least K2! Their sources of K2 MK-4 were eggs, meats and dairy. They obtained MK-5 through MK-10 from fermented foods and fish. The investigators found no association with K1, the form found in plants.
Perigord, France is the world's capital of foie gras, or fatty goose liver. Good news for the bon vivants: foie gras turns out to be the richest known source of K2. Perigord also has the lowest rate of cardiovascular mortality in France, a country already noted for its low CVD mortality.
Rats fed warfarin, a drug that inhibits K2 recycling, develop arterial calcification. Feeding the rats K2 completely inhibits this effect. Mice lacking matrix Gla protein (MGP), a vitamin K-dependent protein that guards against arterial calcification, develop heavily calcified aortas and die prematurely. So the link between K2 and cardiovascular disease is a very strong one.
Mammals can synthesize K2 MK-4 from K1 to some degree, so dietary K1 and other forms of vitamin K may contribute to K2 MK-4 status.
The synergism Weston Price observed between vitamins A, D and K2 now has a solid mechanism. In a nutshell, vitamins A and D signal the production of some very important proteins, and K2 is required to activate them once they are made. Many of these proteins are involved in mineral metabolism, thus the effects Price saw in his experiments and observations in non-industrialized cultures. For example, osteocalcin is a protein that organizes calcium and phosphorus deposition in the bones and teeth. It's produced by cells in response to vitamins A and D, but requires K2 to perform its function. This suggests that the effects of vitamin D on bone health could be amplified greatly if it were administered along with K2. By itself, K2 is already highly protective against fractures in the elderly. It works out perfectly, since K2 also protects against vitamin D toxicity.
I'm not going to go through all the other data on K2 in detail, but suffice it to say it's very very important. I believe that K2 is a 'missing link' that explains many of our modern ills, just as Weston Price wrote. Here are a few more tidbits to whet your appetite: K2 may affect glucose control and insulin release (1, 2). It's concentrated in the brain, serving an as yet unknown function.
Hunter-gatherers didn't have multivitamins, they had nutrient-dense food. As long as you eat a natural diet containing some vegetables and some animal products, and lay off the processed grains, sugar and vegetable oil, the micronutrients will take care of themselves.
Vitamin K2, MK-4 is only found in animal products. The best sources known are grass-fed butter from cows eating rapidly growing grass, and foie gras. K2 tends to associate with beta-carotene in butter, so the darker the color, the more K2 it contains (also, the better it tastes). Fish eggs, other grass-fed dairy, shellfish, insects and other organ meats are also good sources. Chris Masterjohn compiled a list of food sources in his excellent article on the Weston Price foundation website. I highly recommend reading it if you want more detail. K2 MK-7 is found abundantly in natto, a type of fermented soybean, and it may be partially converted to MK-4.
Finally, you can also buy K2 supplements. The best one is butter oil, the very same stuff Price used to treat his patients. I have used this one personally, and I noticed positive effects on my skin overnight. Thorne research makes a synthetic liquid K2 MK-4 supplement that is easy to dose drop-wise to get natural amounts of it. Other K2 MK-4 supplements are much more concentrated than what you could get from food so I recommend avoiding them. I am generally against supplements, but I've ordered the Thorne product for a little self-experimentation. I want to see if it has the same effect on my skin as the butter oil (update- it does).
Wednesday, March 26, 2008
Visceral Fat
This week, I stumbled upon a very interesting series of articles from the lab of Dr. Nir Barzilai.
The first article I came across showed that surgical removal of the visceral fat deposit of rats increased their lifespan. Visceral fat (VF) is the "beer belly", and consists of the perinephratic fat around the kidneys and the omental fat in front of the intestines. It doesn't include subcutaneous fat, the fat layer under the skin.
VF is tightly associated with the metabolic syndrome, the quintessential "disease of civilization" that affects 24% of Americans (NHANES III). It's defined by three or more of the following criteria: high blood pressure, large waist circumference, low HDL cholesterol, high triglycerides, and high fasting glucose. The metabolic syndrome is associated with a 3-4-fold increase in the risk of death from cardiovascular disease, and a 6-fold increase in the risk of developing type II diabetes. From a review on the metabolic syndrome (parentheses mine):
This is all well and good, but who cares? What's to say VF plays any role other than as a simple marker for overweight?
The longevity paper led me to Dr. Barzilai's previous papers, which answered this question rather thoroughly. Rats raised on standard rat chow, which is a sad little compressed pellet made of grains and added nutrients, develop elevated insulin and insulin resistance with age, just like humans. Unless they don't have VF. Rats that had their VF surgically removed did not develop insulin resistance or elevated insulin with age, despite rebounding to their original total fat mass rather quickly (VF accounts for ~18% of total fat in these rats). These parameters are unaffected by removing an equal amount of subcutaneous fat, which has been shown in human liposuction patients as well.
Removing VF also improved diabetes-prone Zucker rats, which are profoundly insulin-resistant (leptin receptor loss-of-function). It kept wild-type rats just as insulin-sensitive as calorically restricted controls, which had a small amount of VF. This shows that VF isn't just a passive player; it's essential for the development of insulin resistance. It also shows, along with human studies, that insulin resistance is not an inevitable consequence of aging.
Adipose (fat) tissue is being increasingly recognized as an important endocrine (hormone-secreting) organ. It produces many different hormones that affect insulin sensitivity and appetite regulation, among other things. These hormones are collectively known as fat-derived peptides (FDPs). At least one of these FDPs, TNF-alpha, promotes insulin resistance.
Dr. Barzilai's group went on to explore the mechanism of VF contributing to insulin resistance. They increased the rate of glucose flux into the fat tissue of rats by infusing either glucose or insulin into the bloodstream. These treatments both cause increased glucose uptake by fat cells. What they saw when they dissected the rats was striking. The VF had ramped up its production of FDPs from 2- to 15-fold, while the subcutaneous fat had barely changed. Incidentally, insulin increased glucose uptake by VF twice as much as subcutaneous fat.
I'll say this again, because it's important. They forced glucose into VF cells, and those cells dramatically upregulated FDP production. And again, no visceral fat, no FDPs.
In earlier papers, he also showed that the removal of VF dramatically reduces the expression of TNF-alpha and leptin (two FDPs) in subcutaneous fat on a longer timescale, showing that VF and subcutaneous fat communicate to alter the metabolism. Again, TNF-alpha promotes insulin resistance, making it a possible link between the fat tissue and peripheral effects. VF removal had no effect on triglycerides, suggesting that they're only a marker of insulin dysfunction rather than a cause.
Now to take this research to its logical conclusion. Here's a plausible sequence of events leading up to the metabolic syndrome:
The first article I came across showed that surgical removal of the visceral fat deposit of rats increased their lifespan. Visceral fat (VF) is the "beer belly", and consists of the perinephratic fat around the kidneys and the omental fat in front of the intestines. It doesn't include subcutaneous fat, the fat layer under the skin.
VF is tightly associated with the metabolic syndrome, the quintessential "disease of civilization" that affects 24% of Americans (NHANES III). It's defined by three or more of the following criteria: high blood pressure, large waist circumference, low HDL cholesterol, high triglycerides, and high fasting glucose. The metabolic syndrome is associated with a 3-4-fold increase in the risk of death from cardiovascular disease, and a 6-fold increase in the risk of developing type II diabetes. From a review on the metabolic syndrome (parentheses mine):
The most common alteration related to the impaired glucose metabolism with aging is the progressively increased fasting and postprandial [post-meal] plasma insulin levels, suggesting an insulin-resistant state.
This is all well and good, but who cares? What's to say VF plays any role other than as a simple marker for overweight?
The longevity paper led me to Dr. Barzilai's previous papers, which answered this question rather thoroughly. Rats raised on standard rat chow, which is a sad little compressed pellet made of grains and added nutrients, develop elevated insulin and insulin resistance with age, just like humans. Unless they don't have VF. Rats that had their VF surgically removed did not develop insulin resistance or elevated insulin with age, despite rebounding to their original total fat mass rather quickly (VF accounts for ~18% of total fat in these rats). These parameters are unaffected by removing an equal amount of subcutaneous fat, which has been shown in human liposuction patients as well.
Removing VF also improved diabetes-prone Zucker rats, which are profoundly insulin-resistant (leptin receptor loss-of-function). It kept wild-type rats just as insulin-sensitive as calorically restricted controls, which had a small amount of VF. This shows that VF isn't just a passive player; it's essential for the development of insulin resistance. It also shows, along with human studies, that insulin resistance is not an inevitable consequence of aging.
Adipose (fat) tissue is being increasingly recognized as an important endocrine (hormone-secreting) organ. It produces many different hormones that affect insulin sensitivity and appetite regulation, among other things. These hormones are collectively known as fat-derived peptides (FDPs). At least one of these FDPs, TNF-alpha, promotes insulin resistance.
Dr. Barzilai's group went on to explore the mechanism of VF contributing to insulin resistance. They increased the rate of glucose flux into the fat tissue of rats by infusing either glucose or insulin into the bloodstream. These treatments both cause increased glucose uptake by fat cells. What they saw when they dissected the rats was striking. The VF had ramped up its production of FDPs from 2- to 15-fold, while the subcutaneous fat had barely changed. Incidentally, insulin increased glucose uptake by VF twice as much as subcutaneous fat.
I'll say this again, because it's important. They forced glucose into VF cells, and those cells dramatically upregulated FDP production. And again, no visceral fat, no FDPs.
In earlier papers, he also showed that the removal of VF dramatically reduces the expression of TNF-alpha and leptin (two FDPs) in subcutaneous fat on a longer timescale, showing that VF and subcutaneous fat communicate to alter the metabolism. Again, TNF-alpha promotes insulin resistance, making it a possible link between the fat tissue and peripheral effects. VF removal had no effect on triglycerides, suggesting that they're only a marker of insulin dysfunction rather than a cause.
Now to take this research to its logical conclusion. Here's a plausible sequence of events leading up to the metabolic syndrome:
- A meal high in quickly digested carbohydrate elevates blood glucose. OR, excessive fructose causes insulin resistance in the liver which leads to high fasting glucose.
- Visceral fat responds by increasing production of FDPs.
- FDPs, directly and/or indirectly, cause insulin resistance in the liver, muscle and other tissue. Liver insulin resistance causes alterations in lipoprotein ("cholesterol") profile (more on this in another post). Fat tissue remains insulin-sensitive.
- The vicious cycle continues, with increased visceral fat size and glucose uptake increasing FDP production, which makes the liver more insulin resistant, which increases glucose production by the liver, etc.
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