This is a simplified summary of the last two posts.
Polyunsaturated fats in the diet are mostly omega-6 or omega-3. These get converted into a diverse and influential class of signaling molecules in the body called eicosanoids. On their way to becoming eicosanoids, they get elongated. These elongated versions can be measured in tissue, and the higher the proportion of elongated omega-6 in the total pool, the higher the risk of a heart attack.
Eicosanoids are either omega-6 or omega-3-derived. Omega-6 eicosanoids, in general, are very potent and participate in inflammatory processes and blood clotting. Omega-3 eicosanoids are less potent, less inflammatory, less clot-forming, and participate in long-term repair processes. This is a simplification, as there are exceptions, but in a broad sense seems to be true.
In the modern U.S. and most other affluent nations, we eat so much omega-6 (mostly in the form of liquid industrial vegetable oils), and so little omega-3, that we create a very inflammatory and pro-clotting environment, probably contributing to a number of chronic diseases including cardiovascular disease.
There are two ways to stay in balance: reduce omega-6, and increase omega-3. In my opinion, the former is more important than the latter, but only if you can reduce omega-6 to below 4% of calories. If you're above 4%, the only way to reduce your risk is to outcompete the omega-6 with additional omega-3. Keeping omega-6 below 4% and ensuring a modest but regular intake of omega-3, such as from wild-caught fish, will probably substantially reduce the risk of cardiovascular disease and other chronic illnesses.
Bottom line: ditch industrial vegetable oils such as corn, soybean, safflower and sunflower oil, and everything that contains them. This includes most processed foods, especially mayonnaise, grocery store salad dressings, and fried foods. We aren't meant to eat those foods and they derail our metabolism on a fundamental level. I also believe it's a good idea to have a regular source of omega-3, whether it comes from seafood, small doses of cod liver oil, or small doses of flax.
Minggu, 31 Mei 2009
Available Home Care Services
The desire to live an independent life is very strong in older adults. They want to lead a full and dignified life. Self-respect becomes more important for a person when he/she transitions into the older stage of life. As people grow old they need help to perform various tasks. One must assist them without hurting their self-respect or dignity.This is the principal factor behind the development
Sabtu, 30 Mei 2009
Volcanic eruption nearly ended all life on earth
A volcanic eruption nearly obliterated all life on earth 260 million years ago, new research has revealed.The blast was on a scale that has never been seen by humans and happened even before dinosaurs came along when Earth teemed with creatures which are now extinct.Lava and ash spewed up from beneath a shallow ocean that once covered Emeishan in southwestern China and rained down on primitive
Jumat, 29 Mei 2009
IT Companies firing employees
Day by day news about the giant IT companies in the financial sector is probably true ,a bad news is unfortunate for the employees. With most of the Indian companies having the peak financial corporate as their big customers and with these big customers like Merrill Lynch, Lehman, Bear Sterns and other Financial Institutes landing in big trouble due to the financial sector melt down - the Indian
Rabu, 27 Mei 2009
Eicosanoids and Ischemic Heart Disease, Part II
Here's where it gets more complicated and more interesting. The ratio of omega-6 to omega-3 matters, but so does the total amount of each. This is a graph from a 1992 paper by Dr. Lands:
Allow me to explain. These lines are based on values predicted by a formula developed by Dr. Lands that determines the proportion of omega-6 in tissue HUFA (highly unsaturated fatty acids; includes 20- to 22-carbon omega-6 and omega-3 fats), based on dietary intake of omega-6 and omega-3 fats. This formula seems to be quite accurate, and has been validated both in rodents and humans. As a tissue's arachidonic acid content increases, its EPA and DHA content decreases proportionally.
On the Y-axis (vertical), we have the proportion of omega-6 HUFA in tissue. On the X-axis (horizontal), we have the proportion of omega-6 in the diet as a percentage of energy. Each line represents the relationship between dietary omega-6 and tissue HUFA at a given level of dietary omega-3.
Let's start at the top. The first line is the predicted proportion of omega-6 HUFA in the tissue of a person eating virtually no omega-3. You can see that it maxes out around 4% of calories from omega-6, but it can actually be fairly low if omega-6 is kept very low. The next line down is what happens when your omega-3 intake is 0.1% of calories. You can see that the proportion of omega-6 HUFA is lower than the curve above it at all omega-6 intakes, but it still maxes out around 4% omega-6. As omega-3 intake increases, the proportion of omega-6 HUFA decreases at all levels of dietary omega-6 because it has to compete with omega-3 HUFA for space in the membrane.
In the U.S., we get a small proportion of our calories from omega-3. The horizontal line marks our average tissue HUFA composition, which is about 75% omega-6. We get more than 7% of our calories from omega-6. This means our tissue contains nearly the maximum proportion of omega-6 HUFA, creating a potently inflammatory and thrombotic environment! This is a very significant fact, because it explains three major observations:
But the trend didn't continue into later trials. This makes perfect sense in light of the rising omega-6 intake over the course of the 20th century in the U.S. and other affluent nations. Once our omega-6 intake crossed the 4% threshold, more omega-6 had very little effect on the proportion of omega-6 HUFA in tissue. This may be why some of the very first PUFA diet trials caused increased mortality: there was a proportion of the population that was still getting less than 4% omega-6 in its regular diet at that time. By the 1980s, virtually everyone in the U.S. (and many other affluent nations) was eating more than 4% omega-6, and thus adding more did not significantly affect tissue HUFA or heart attack mortality.
If omega-3 intake is low, whether omega-6 intake is 5% or 10% doesn't matter much for heart disease. At that point, the only way to reduce tissue HUFA without cutting back on omega-6 consumption is to outcompete it with additional omega-3. That's what the Japanese do, and it's also what happened in several clinical trials including the DART trial.
This neatly explains why the French, Japanese and Kitavans have low rates of ischemic heart disease, despite the prevalence of smoking cigarettes in all three cultures. The French diet traditionally focuses on animal fats, eschews industrial vegetable oils, and includes seafood. They eat less omega-6 and more omega-3 than Americans. They have the lowest heart attack mortality rate of any affluent Western nation. The Japanese are known for their high intake of seafood. They also eat less omega-6 than Americans. They have the lowest heart attack death rate of any affluent nation. The traditional Kitavan diet contains very little omega-6 (probably less than 1% of calories), and a significant amount of omega-3 from seafood (about one teaspoon of fish fat per day). They have an undetectable incidence of heart attack and stroke.
In sum, this suggests that an effective way to avoid a heart attack is to reduce omega-6 consumption and ensure an adequate source of omega-3. The lower the omega-6, the less the omega-3 matters. This is a nice theory, but where's the direct evidence? In the next post, I'll discuss the controlled trial that proved this concept once and for all: the Lyon diet-heart trial.
Allow me to explain. These lines are based on values predicted by a formula developed by Dr. Lands that determines the proportion of omega-6 in tissue HUFA (highly unsaturated fatty acids; includes 20- to 22-carbon omega-6 and omega-3 fats), based on dietary intake of omega-6 and omega-3 fats. This formula seems to be quite accurate, and has been validated both in rodents and humans. As a tissue's arachidonic acid content increases, its EPA and DHA content decreases proportionally.On the Y-axis (vertical), we have the proportion of omega-6 HUFA in tissue. On the X-axis (horizontal), we have the proportion of omega-6 in the diet as a percentage of energy. Each line represents the relationship between dietary omega-6 and tissue HUFA at a given level of dietary omega-3.
Let's start at the top. The first line is the predicted proportion of omega-6 HUFA in the tissue of a person eating virtually no omega-3. You can see that it maxes out around 4% of calories from omega-6, but it can actually be fairly low if omega-6 is kept very low. The next line down is what happens when your omega-3 intake is 0.1% of calories. You can see that the proportion of omega-6 HUFA is lower than the curve above it at all omega-6 intakes, but it still maxes out around 4% omega-6. As omega-3 intake increases, the proportion of omega-6 HUFA decreases at all levels of dietary omega-6 because it has to compete with omega-3 HUFA for space in the membrane.
In the U.S., we get a small proportion of our calories from omega-3. The horizontal line marks our average tissue HUFA composition, which is about 75% omega-6. We get more than 7% of our calories from omega-6. This means our tissue contains nearly the maximum proportion of omega-6 HUFA, creating a potently inflammatory and thrombotic environment! This is a very significant fact, because it explains three major observations:
- The U.S has a very high rate of heart attack mortality.
- Recent diet trials in which saturated fat was replaced with omega-6-rich vegetable oils didn't cause an increase in mortality, although some of the very first trials in the 1960s did.
- Diet trials that increased omega-3 decreased mortality.
But the trend didn't continue into later trials. This makes perfect sense in light of the rising omega-6 intake over the course of the 20th century in the U.S. and other affluent nations. Once our omega-6 intake crossed the 4% threshold, more omega-6 had very little effect on the proportion of omega-6 HUFA in tissue. This may be why some of the very first PUFA diet trials caused increased mortality: there was a proportion of the population that was still getting less than 4% omega-6 in its regular diet at that time. By the 1980s, virtually everyone in the U.S. (and many other affluent nations) was eating more than 4% omega-6, and thus adding more did not significantly affect tissue HUFA or heart attack mortality.
If omega-3 intake is low, whether omega-6 intake is 5% or 10% doesn't matter much for heart disease. At that point, the only way to reduce tissue HUFA without cutting back on omega-6 consumption is to outcompete it with additional omega-3. That's what the Japanese do, and it's also what happened in several clinical trials including the DART trial.
This neatly explains why the French, Japanese and Kitavans have low rates of ischemic heart disease, despite the prevalence of smoking cigarettes in all three cultures. The French diet traditionally focuses on animal fats, eschews industrial vegetable oils, and includes seafood. They eat less omega-6 and more omega-3 than Americans. They have the lowest heart attack mortality rate of any affluent Western nation. The Japanese are known for their high intake of seafood. They also eat less omega-6 than Americans. They have the lowest heart attack death rate of any affluent nation. The traditional Kitavan diet contains very little omega-6 (probably less than 1% of calories), and a significant amount of omega-3 from seafood (about one teaspoon of fish fat per day). They have an undetectable incidence of heart attack and stroke.
In sum, this suggests that an effective way to avoid a heart attack is to reduce omega-6 consumption and ensure an adequate source of omega-3. The lower the omega-6, the less the omega-3 matters. This is a nice theory, but where's the direct evidence? In the next post, I'll discuss the controlled trial that proved this concept once and for all: the Lyon diet-heart trial.