Choline and Fatty Liver

I've been writing about non-alcoholic fatty liver disorder (NAFLD) since the early days of this blog, because it's an alarmingly common disorder (roughly a quarter of Americans affected) that is typically undiagnosed. It often progresses into its more serious cousin non-alcoholic steatohepatitis (NASH), an inflammatory condition that causes liver damage and can progress to cancer. In a number of previous posts, I pinpointed excess sugar and seed oil consumption as culprits in NAFLD and NASH (1, 2, 3, 4, 5).

Chris Masterjohn recently published two very informative posts on NAFLD/NASH that add a major additional factor to the equation: choline (6, 7). Choline is an essential nutrient that's required for the transport of fat out of the liver (8). NAFLD can be caused, and cured, simply by removing or adding dietary choline, and it appears to be dominant over other dietary factors including fat, sugar and alcohol. Apparently, certain researchers have been aware of this for some time, but it hasn't entered into the mainstream consciousness.

Could that be because the richest dietary sources are liver and eggs*? Choline is also found in smaller amounts in a variety of whole animal and plant foods. Most people don't get the officially recommended amount. From a recent review article (9):

Mean choline intakes for older children, men, women, and pregnant women are far below the adequate intake level established by the [Institute of Medicine]. Given the importance of choline in a wide range of critical functions in the human body, coupled with less-than-optimal intakes among the population, dietary guidance should be developed to encourage the intake of choline-rich foods.

I've dubbed beef liver the Most Nutritious Food in the World, Nature's Multivitamin, and I'll probably invent other titles for it in the future. Add yours to the comments. Learn to love liver! I think it's an excellent food to eat on a weekly basis.

Head over to Chris's blog and read about the classic studies he unearthed. And add The Daily Lipid to your RSS reader, because there's more interesting material to come!

The Sweet Truth about Liver and Egg Yolks
Does Choline Deficiency Contribute to Fatty Liver in Humans?


* For the brave: brain is actually the richest source of choline.

Choline and Fatty Liver

I've been writing about non-alcoholic fatty liver disorder (NAFLD) since the early days of this blog, because it's an alarmingly common disorder (roughly a quarter of Americans affected) that is typically undiagnosed. It often progresses into its more serious cousin non-alcoholic steatohepatitis (NASH), an inflammatory condition that causes liver damage and can progress to cancer. In a number of previous posts, I pinpointed excess sugar and seed oil consumption as culprits in NAFLD and NASH (1, 2, 3, 4, 5).

Chris Masterjohn recently published two very informative posts on NAFLD/NASH that add a major additional factor to the equation: choline (6, 7). Choline is an essential nutrient that's required for the transport of fat out of the liver (8). NAFLD can be caused, and cured, simply by removing or adding dietary choline, and it appears to be dominant over other dietary factors including fat, sugar and alcohol. Apparently, certain researchers have been aware of this for some time, but it hasn't entered into the mainstream consciousness.

Could that be because the richest dietary sources are liver and eggs*? Choline is also found in smaller amounts in a variety of whole animal and plant foods. Most people don't get the officially recommended amount. From a recent review article (9):

Mean choline intakes for older children, men, women, and pregnant women are far below the adequate intake level established by the [Institute of Medicine]. Given the importance of choline in a wide range of critical functions in the human body, coupled with less-than-optimal intakes among the population, dietary guidance should be developed to encourage the intake of choline-rich foods.

I've dubbed beef liver the Most Nutritious Food in the World, Nature's Multivitamin, and I'll probably invent other titles for it in the future. Add yours to the comments. Learn to love liver! I think it's an excellent food to eat on a weekly basis.

Head over to Chris's blog and read about the classic studies he unearthed. And add The Daily Lipid to your RSS reader, because there's more interesting material to come!

The Sweet Truth about Liver and Egg Yolks
Does Choline Deficiency Contribute to Fatty Liver in Humans?


* For the brave: brain is actually the richest source of choline.

Choline and Fatty Liver

I've been writing about non-alcoholic fatty liver disorder (NAFLD) since the early days of this blog, because it's an alarmingly common disorder (roughly a quarter of Americans affected) that is typically undiagnosed. It often progresses into its more serious cousin non-alcoholic steatohepatitis (NASH), an inflammatory condition that causes liver damage and can progress to cancer. In a number of previous posts, I pinpointed excess sugar and seed oil consumption as culprits in NAFLD and NASH (1, 2, 3, 4, 5).

Chris Masterjohn recently published two very informative posts on NAFLD/NASH that add a major additional factor to the equation: choline (6, 7). Choline is an essential nutrient that's required for the transport of fat out of the liver (8). NAFLD can be caused, and cured, simply by removing or adding dietary choline, and it appears to be dominant over other dietary factors including fat, sugar and alcohol. Apparently, certain researchers have been aware of this for some time, but it hasn't entered into the mainstream consciousness.

Could that be because the richest dietary sources are liver and eggs*? Choline is also found in smaller amounts in a variety of whole animal and plant foods. Most people don't get the officially recommended amount. From a recent review article (9):

Mean choline intakes for older children, men, women, and pregnant women are far below the adequate intake level established by the [Institute of Medicine]. Given the importance of choline in a wide range of critical functions in the human body, coupled with less-than-optimal intakes among the population, dietary guidance should be developed to encourage the intake of choline-rich foods.

I've dubbed beef liver the Most Nutritious Food in the World, Nature's Multivitamin, and I'll probably invent other titles for it in the future. Add yours to the comments. Learn to love liver! I think it's an excellent food to eat on a weekly basis.

Head over to Chris's blog and read about the classic studies he unearthed. And add The Daily Lipid to your RSS reader, because there's more interesting material to come!

The Sweet Truth about Liver and Egg Yolks
Does Choline Deficiency Contribute to Fatty Liver in Humans?


* For the brave: brain is actually the richest source of choline.

Choline and Fatty Liver

I've been writing about non-alcoholic fatty liver disorder (NAFLD) since the early days of this blog, because it's an alarmingly common disorder (roughly a quarter of Americans affected) that is typically undiagnosed. It often progresses into its more serious cousin non-alcoholic steatohepatitis (NASH), an inflammatory condition that causes liver damage and can progress to cancer. In a number of previous posts, I pinpointed excess sugar and seed oil consumption as culprits in NAFLD and NASH (1, 2, 3, 4, 5).

Chris Masterjohn recently published two very informative posts on NAFLD/NASH that add a major additional factor to the equation: choline (6, 7). Choline is an essential nutrient that's required for the transport of fat out of the liver (8). NAFLD can be caused, and cured, simply by removing or adding dietary choline, and it appears to be dominant over other dietary factors including fat, sugar and alcohol. Apparently, certain researchers have been aware of this for some time, but it hasn't entered into the mainstream consciousness.

Could that be because the richest dietary sources are liver and eggs*? Choline is also found in smaller amounts in a variety of whole animal and plant foods. Most people don't get the officially recommended amount. From a recent review article (9):

Mean choline intakes for older children, men, women, and pregnant women are far below the adequate intake level established by the [Institute of Medicine]. Given the importance of choline in a wide range of critical functions in the human body, coupled with less-than-optimal intakes among the population, dietary guidance should be developed to encourage the intake of choline-rich foods.

I've dubbed beef liver the Most Nutritious Food in the World, Nature's Multivitamin, and I'll probably invent other titles for it in the future. Add yours to the comments. Learn to love liver! I think it's an excellent food to eat on a weekly basis.

Head over to Chris's blog and read about the classic studies he unearthed. And add The Daily Lipid to your RSS reader, because there's more interesting material to come!

The Sweet Truth about Liver and Egg Yolks
Does Choline Deficiency Contribute to Fatty Liver in Humans?


* For the brave: brain is actually the richest source of choline.

Copper in Food

Sources of Copper

It isn't hard to get enough copper-- unless you live in an industrial nation. I've compiled a chart showing the copper content of various refined and unrefined foods to illustrate the point. The left side shows industrial staple foods, while the right side shows whole foods. I've incorporated a few that would have been typical of Polynesian and Melanesian cultures apparently free of cardiovascular disease. The serving sizes are what one might reasonably eat at a meal: roughly 200 calories for grains, tubers and whole coconut; 1/4 pound for animal products; 1/2 teaspoon for salt; 1 cup for raw kale; 1 oz for sugar.

Note that beef liver is off the chart at 488 percent of the USDA recommended daily allowance. I don't know if you'd want to sit down and eat a quarter pound of beef liver, but you get the picture. Beef liver is nature's multivitamin: hands down the Most Nutritious Food in the World. That's because it acts as a storage depot for a number of important micronutrients, as well as being a biochemical factory that requires a large amount of B vitamins to function. You can see that muscle tissue isn't a great source of copper compared to other organs, and this holds true for other micronutrients as well.

Beef liver is so full of micronutrients, it shouldn't be eaten every day. Think of it in terms of the composition of a cow's body. The edible carcass is mostly muscle, but a significant portion is liver. I think it makes sense to eat some form of liver about once per week.

Modern Agriculture Produces Micronutrient-poor Foods

The numbers in the graph above come from NutritionData, my main source of food nutrient composition. The problem with relying on this kind of information is it ignores the variability in micronutrient content due to plant strain, soil quality, et cetera.

The unfortunate fact is that micronutrient levels have declined substantially over the course of the 20th century, even in whole foods. Dr. Donald R. Davis has documented the substantial decline in copper and other micronutrients in American foods over the second half of the last century (1). An even more marked decrease has occurred in the UK (2), with similar trends worldwide. On average, the copper content of vegetables in the UK has declined 76 percent since 1940. Most of the decrease has taken place since 1978. Fruits are down 20 percent and meats are down 24 percent.

I find this extremely disturbing, as it will affect even people eating whole food diets. This is yet another reason to buy from artisanal producers, who are likely to use more traditional plant varieties and grow in richer soil. Grass-fed beef should be just as nutritious as it has always been. Some people may also wish to grow, hunt or fish their own food.

Copper in Food

Sources of Copper

It isn't hard to get enough copper-- unless you live in an industrial nation. I've compiled a chart showing the copper content of various refined and unrefined foods to illustrate the point. The left side shows industrial staple foods, while the right side shows whole foods. I've incorporated a few that would have been typical of Polynesian and Melanesian cultures apparently free of cardiovascular disease. The serving sizes are what one might reasonably eat at a meal: roughly 200 calories for grains, tubers and whole coconut; 1/4 pound for animal products; 1/2 teaspoon for salt; 1 cup for raw kale; 1 oz for sugar.

Note that beef liver is off the chart at 488 percent of the USDA recommended daily allowance. I don't know if you'd want to sit down and eat a quarter pound of beef liver, but you get the picture. Beef liver is nature's multivitamin: hands down the Most Nutritious Food in the World. That's because it acts as a storage depot for a number of important micronutrients, as well as being a biochemical factory that requires a large amount of B vitamins to function. You can see that muscle tissue isn't a great source of copper compared to other organs, and this holds true for other micronutrients as well.

Beef liver is so full of micronutrients, it shouldn't be eaten every day. Think of it in terms of the composition of a cow's body. The edible carcass is mostly muscle, but a significant portion is liver. I think it makes sense to eat some form of liver about once per week.

Modern Agriculture Produces Micronutrient-poor Foods

The numbers in the graph above come from NutritionData, my main source of food nutrient composition. The problem with relying on this kind of information is it ignores the variability in micronutrient content due to plant strain, soil quality, et cetera.

The unfortunate fact is that micronutrient levels have declined substantially over the course of the 20th century, even in whole foods. Dr. Donald R. Davis has documented the substantial decline in copper and other micronutrients in American foods over the second half of the last century (1). An even more marked decrease has occurred in the UK (2), with similar trends worldwide. On average, the copper content of vegetables in the UK has declined 76 percent since 1940. Most of the decrease has taken place since 1978. Fruits are down 20 percent and meats are down 24 percent.

I find this extremely disturbing, as it will affect even people eating whole food diets. This is yet another reason to buy from artisanal producers, who are likely to use more traditional plant varieties and grow in richer soil. Grass-fed beef should be just as nutritious as it has always been. Some people may also wish to grow, hunt or fish their own food.

Copper in Food

Sources of Copper

It isn't hard to get enough copper-- unless you live in an industrial nation. I've compiled a chart showing the copper content of various refined and unrefined foods to illustrate the point. The left side shows industrial staple foods, while the right side shows whole foods. I've incorporated a few that would have been typical of Polynesian and Melanesian cultures apparently free of cardiovascular disease. The serving sizes are what one might reasonably eat at a meal: roughly 200 calories for grains, tubers and whole coconut; 1/4 pound for animal products; 1/2 teaspoon for salt; 1 cup for raw kale; 1 oz for sugar.

Note that beef liver is off the chart at 488 percent of the USDA recommended daily allowance. I don't know if you'd want to sit down and eat a quarter pound of beef liver, but you get the picture. Beef liver is nature's multivitamin: hands down the Most Nutritious Food in the World. That's because it acts as a storage depot for a number of important micronutrients, as well as being a biochemical factory that requires a large amount of B vitamins to function. You can see that muscle tissue isn't a great source of copper compared to other organs, and this holds true for other micronutrients as well.

Beef liver is so full of micronutrients, it shouldn't be eaten every day. Think of it in terms of the composition of a cow's body. The edible carcass is mostly muscle, but a significant portion is liver. I think it makes sense to eat some form of liver about once per week.

Modern Agriculture Produces Micronutrient-poor Foods

The numbers in the graph above come from NutritionData, my main source of food nutrient composition. The problem with relying on this kind of information is it ignores the variability in micronutrient content due to plant strain, soil quality, et cetera.

The unfortunate fact is that micronutrient levels have declined substantially over the course of the 20th century, even in whole foods. Dr. Donald R. Davis has documented the substantial decline in copper and other micronutrients in American foods over the second half of the last century (1). An even more marked decrease has occurred in the UK (2), with similar trends worldwide. On average, the copper content of vegetables in the UK has declined 76 percent since 1940. Most of the decrease has taken place since 1978. Fruits are down 20 percent and meats are down 24 percent.

I find this extremely disturbing, as it will affect even people eating whole food diets. This is yet another reason to buy from artisanal producers, who are likely to use more traditional plant varieties and grow in richer soil. Grass-fed beef should be just as nutritious as it has always been. Some people may also wish to grow, hunt or fish their own food.

Copper in Food

Sources of Copper

It isn't hard to get enough copper-- unless you live in an industrial nation. I've compiled a chart showing the copper content of various refined and unrefined foods to illustrate the point. The left side shows industrial staple foods, while the right side shows whole foods. I've incorporated a few that would have been typical of Polynesian and Melanesian cultures apparently free of cardiovascular disease. The serving sizes are what one might reasonably eat at a meal: roughly 200 calories for grains, tubers and whole coconut; 1/4 pound for animal products; 1/2 teaspoon for salt; 1 cup for raw kale; 1 oz for sugar.

Note that beef liver is off the chart at 488 percent of the USDA recommended daily allowance. I don't know if you'd want to sit down and eat a quarter pound of beef liver, but you get the picture. Beef liver is nature's multivitamin: hands down the Most Nutritious Food in the World. That's because it acts as a storage depot for a number of important micronutrients, as well as being a biochemical factory that requires a large amount of B vitamins to function. You can see that muscle tissue isn't a great source of copper compared to other organs, and this holds true for other micronutrients as well.

Beef liver is so full of micronutrients, it shouldn't be eaten every day. Think of it in terms of the composition of a cow's body. The edible carcass is mostly muscle, but a significant portion is liver. I think it makes sense to eat some form of liver about once per week.

Modern Agriculture Produces Micronutrient-poor Foods

The numbers in the graph above come from NutritionData, my main source of food nutrient composition. The problem with relying on this kind of information is it ignores the variability in micronutrient content due to plant strain, soil quality, et cetera.

The unfortunate fact is that micronutrient levels have declined substantially over the course of the 20th century, even in whole foods. Dr. Donald R. Davis has documented the substantial decline in copper and other micronutrients in American foods over the second half of the last century (1). An even more marked decrease has occurred in the UK (2), with similar trends worldwide. On average, the copper content of vegetables in the UK has declined 76 percent since 1940. Most of the decrease has taken place since 1978. Fruits are down 20 percent and meats are down 24 percent.

I find this extremely disturbing, as it will affect even people eating whole food diets. This is yet another reason to buy from artisanal producers, who are likely to use more traditional plant varieties and grow in richer soil. Grass-fed beef should be just as nutritious as it has always been. Some people may also wish to grow, hunt or fish their own food.

Fatty Liver: It's not Just for Grown-ups Anymore

The epidemic of non-alcoholic fatty liver disease (NAFLD) is one of my favorite topics on this blog, due to the liver's role as the body's metabolic "grand central station", as Dr. Philip Wood puts it. The liver plays a critical part in the regulation of sugar, insulin, and lipid levels in the blood. Many of the routine blood tests administered in the doctor's office (blood glucose, cholesterol, etc.) partially reflect liver function.

NAFLD is an excessive accumulation of fat in the liver that impairs its function and can lead to severe liver inflammation (NASH), and in a small percentage of people, liver cancer. An estimated 20-30% of people in industrial nations suffer from NAFLD, a shockingly high prevalence (1).

I previously posted on dietary factors I believe are involved in NAFLD. In rodents, feeding a large amount of sugar or industrial seed oils (corn oil, etc.) promotes NAFLD, whereas fats such as butter and coconut oil do not (2). In human infants, enteric feeding with industrial seed oils causes severe liver damage, whereas the same amount of fat from fish oil doesn't, and can even reverse the damage done by seed oils (3).

So basically, I think sugar and industrial oils are major contributors to NAFLD, and if you look at diet trends in the US over the last 40 years, they're consistent with the idea. Industrial oils are harmful due (at least in part) to their high omega-6 content, which is problematic partially because it disturbs normal omega-3 metabolism. A potential solution to fatty liver is to reduce sugar, replace industrial oils with natural fats, and ensure a regular source of omega-3. I've posted two anecdotes of people rapidly healing their fatty livers using diet changes* (4, 5).

I recently came across a study that examined the diet of Canadian children with NAFLD (6). The children had a high sugar intake, a typical (i.e., high) omega-6 intake, and a low omega-3 intake. The authors claimed that the children also had a high saturated fat intake, but at 10.5% of calories, they were almost eating to the American Heart Association's "Step I" diet recommendations**. Busted! Total fat intake was also low.

High sugar consumption was associated with a larger waist circumference, insulin resistance, lower adiponectin and elevated markers of inflammation. High omega-6 intake was associated with markers of inflammation. Low omega-3 intake was associated with insulin resistance and elevated liver enzymes. Saturated fat intake presumably had no relation to any of these markers, since they didn't mention it in the text.

These children with NAFLD, who were all insulin resistant and mostly obese, had diets high in omega-6, high in sugar, and low in omega-3. This is consistent with the idea that these three factors, which have all been moving in the wrong direction in the last 40 years, contribute to NAFLD.


* Fatty liver was assessed by liver enzymes, admittedly not a perfect test. However, elevated liver enzymes do correlate fairly well with NAFLD.

** Steps I and II were replaced by new diet advice in 2000. The AHA now recommends keeping saturated fat below 7% of calories. Stock up on those skinless chicken breasts! Make sure there isn't any residual fat sticking to the meat, it might kill you. I do have to give the AHA credit however, because their new recommendations focus mostly on eating real food rather than avoiding saturated fat and cholesterol.

Fatty Liver: It's not Just for Grown-ups Anymore

The epidemic of non-alcoholic fatty liver disease (NAFLD) is one of my favorite topics on this blog, due to the liver's role as the body's metabolic "grand central station", as Dr. Philip Wood puts it. The liver plays a critical part in the regulation of sugar, insulin, and lipid levels in the blood. Many of the routine blood tests administered in the doctor's office (blood glucose, cholesterol, etc.) partially reflect liver function.

NAFLD is an excessive accumulation of fat in the liver that impairs its function and can lead to severe liver inflammation (NASH), and in a small percentage of people, liver cancer. An estimated 20-30% of people in industrial nations suffer from NAFLD, a shockingly high prevalence (1).

I previously posted on dietary factors I believe are involved in NAFLD. In rodents, feeding a large amount of sugar or industrial seed oils (corn oil, etc.) promotes NAFLD, whereas fats such as butter and coconut oil do not (2). In human infants, enteric feeding with industrial seed oils causes severe liver damage, whereas the same amount of fat from fish oil doesn't, and can even reverse the damage done by seed oils (3).

So basically, I think sugar and industrial oils are major contributors to NAFLD, and if you look at diet trends in the US over the last 40 years, they're consistent with the idea. Industrial oils are harmful due (at least in part) to their high omega-6 content, which is problematic partially because it disturbs normal omega-3 metabolism. A potential solution to fatty liver is to reduce sugar, replace industrial oils with natural fats, and ensure a regular source of omega-3. I've posted two anecdotes of people rapidly healing their fatty livers using diet changes* (4, 5).

I recently came across a study that examined the diet of Canadian children with NAFLD (6). The children had a high sugar intake, a typical (i.e., high) omega-6 intake, and a low omega-3 intake. The authors claimed that the children also had a high saturated fat intake, but at 10.5% of calories, they were almost eating to the American Heart Association's "Step I" diet recommendations**. Busted! Total fat intake was also low.

High sugar consumption was associated with a larger waist circumference, insulin resistance, lower adiponectin and elevated markers of inflammation. High omega-6 intake was associated with markers of inflammation. Low omega-3 intake was associated with insulin resistance and elevated liver enzymes. Saturated fat intake presumably had no relation to any of these markers, since they didn't mention it in the text.

These children with NAFLD, who were all insulin resistant and mostly obese, had diets high in omega-6, high in sugar, and low in omega-3. This is consistent with the idea that these three factors, which have all been moving in the wrong direction in the last 40 years, contribute to NAFLD.


* Fatty liver was assessed by liver enzymes, admittedly not a perfect test. However, elevated liver enzymes do correlate fairly well with NAFLD.

** Steps I and II were replaced by new diet advice in 2000. The AHA now recommends keeping saturated fat below 7% of calories. Stock up on those skinless chicken breasts! Make sure there isn't any residual fat sticking to the meat, it might kill you. I do have to give the AHA credit however, because their new recommendations focus mostly on eating real food rather than avoiding saturated fat and cholesterol.

Fatty Liver: It's not Just for Grown-ups Anymore

The epidemic of non-alcoholic fatty liver disease (NAFLD) is one of my favorite topics on this blog, due to the liver's role as the body's metabolic "grand central station", as Dr. Philip Wood puts it. The liver plays a critical part in the regulation of sugar, insulin, and lipid levels in the blood. Many of the routine blood tests administered in the doctor's office (blood glucose, cholesterol, etc.) partially reflect liver function.

NAFLD is an excessive accumulation of fat in the liver that impairs its function and can lead to severe liver inflammation (NASH), and in a small percentage of people, liver cancer. An estimated 20-30% of people in industrial nations suffer from NAFLD, a shockingly high prevalence (1).

I previously posted on dietary factors I believe are involved in NAFLD. In rodents, feeding a large amount of sugar or industrial seed oils (corn oil, etc.) promotes NAFLD, whereas fats such as butter and coconut oil do not (2). In human infants, enteric feeding with industrial seed oils causes severe liver damage, whereas the same amount of fat from fish oil doesn't, and can even reverse the damage done by seed oils (3).

So basically, I think sugar and industrial oils are major contributors to NAFLD, and if you look at diet trends in the US over the last 40 years, they're consistent with the idea. Industrial oils are harmful due (at least in part) to their high omega-6 content, which is problematic partially because it disturbs normal omega-3 metabolism. A potential solution to fatty liver is to reduce sugar, replace industrial oils with natural fats, and ensure a regular source of omega-3. I've posted two anecdotes of people rapidly healing their fatty livers using diet changes* (4, 5).

I recently came across a study that examined the diet of Canadian children with NAFLD (6). The children had a high sugar intake, a typical (i.e., high) omega-6 intake, and a low omega-3 intake. The authors claimed that the children also had a high saturated fat intake, but at 10.5% of calories, they were almost eating to the American Heart Association's "Step I" diet recommendations**. Busted! Total fat intake was also low.

High sugar consumption was associated with a larger waist circumference, insulin resistance, lower adiponectin and elevated markers of inflammation. High omega-6 intake was associated with markers of inflammation. Low omega-3 intake was associated with insulin resistance and elevated liver enzymes. Saturated fat intake presumably had no relation to any of these markers, since they didn't mention it in the text.

These children with NAFLD, who were all insulin resistant and mostly obese, had diets high in omega-6, high in sugar, and low in omega-3. This is consistent with the idea that these three factors, which have all been moving in the wrong direction in the last 40 years, contribute to NAFLD.


* Fatty liver was assessed by liver enzymes, admittedly not a perfect test. However, elevated liver enzymes do correlate fairly well with NAFLD.

** Steps I and II were replaced by new diet advice in 2000. The AHA now recommends keeping saturated fat below 7% of calories. Stock up on those skinless chicken breasts! Make sure there isn't any residual fat sticking to the meat, it might kill you. I do have to give the AHA credit however, because their new recommendations focus mostly on eating real food rather than avoiding saturated fat and cholesterol.

Fatty Liver: It's not Just for Grown-ups Anymore

The epidemic of non-alcoholic fatty liver disease (NAFLD) is one of my favorite topics on this blog, due to the liver's role as the body's metabolic "grand central station", as Dr. Philip Wood puts it. The liver plays a critical part in the regulation of sugar, insulin, and lipid levels in the blood. Many of the routine blood tests administered in the doctor's office (blood glucose, cholesterol, etc.) partially reflect liver function.

NAFLD is an excessive accumulation of fat in the liver that impairs its function and can lead to severe liver inflammation (NASH), and in a small percentage of people, liver cancer. An estimated 20-30% of people in industrial nations suffer from NAFLD, a shockingly high prevalence (1).

I previously posted on dietary factors I believe are involved in NAFLD. In rodents, feeding a large amount of sugar or industrial seed oils (corn oil, etc.) promotes NAFLD, whereas fats such as butter and coconut oil do not (2). In human infants, enteric feeding with industrial seed oils causes severe liver damage, whereas the same amount of fat from fish oil doesn't, and can even reverse the damage done by seed oils (3).

So basically, I think sugar and industrial oils are major contributors to NAFLD, and if you look at diet trends in the US over the last 40 years, they're consistent with the idea. Industrial oils are harmful due (at least in part) to their high omega-6 content, which is problematic partially because it disturbs normal omega-3 metabolism. A potential solution to fatty liver is to reduce sugar, replace industrial oils with natural fats, and ensure a regular source of omega-3. I've posted two anecdotes of people rapidly healing their fatty livers using diet changes* (4, 5).

I recently came across a study that examined the diet of Canadian children with NAFLD (6). The children had a high sugar intake, a typical (i.e., high) omega-6 intake, and a low omega-3 intake. The authors claimed that the children also had a high saturated fat intake, but at 10.5% of calories, they were almost eating to the American Heart Association's "Step I" diet recommendations**. Busted! Total fat intake was also low.

High sugar consumption was associated with a larger waist circumference, insulin resistance, lower adiponectin and elevated markers of inflammation. High omega-6 intake was associated with markers of inflammation. Low omega-3 intake was associated with insulin resistance and elevated liver enzymes. Saturated fat intake presumably had no relation to any of these markers, since they didn't mention it in the text.

These children with NAFLD, who were all insulin resistant and mostly obese, had diets high in omega-6, high in sugar, and low in omega-3. This is consistent with the idea that these three factors, which have all been moving in the wrong direction in the last 40 years, contribute to NAFLD.


* Fatty liver was assessed by liver enzymes, admittedly not a perfect test. However, elevated liver enzymes do correlate fairly well with NAFLD.

** Steps I and II were replaced by new diet advice in 2000. The AHA now recommends keeping saturated fat below 7% of calories. Stock up on those skinless chicken breasts! Make sure there isn't any residual fat sticking to the meat, it might kill you. I do have to give the AHA credit however, because their new recommendations focus mostly on eating real food rather than avoiding saturated fat and cholesterol.

Another Fatty Liver Reversal, Part II

A month ago, I wrote about a reader "Steve" who reversed his fatty liver using a change in diet. Non-alcoholic fatty liver disease (NAFLD) is a truly disturbing modern epidemic, rare a few decades ago and now affecting roughly a quarter of the adult population of modern industrialized nations. Researchers cause NAFLD readily in rodents by feeding them industrial vegetable oils or large amounts of sugar.

Steve recently e-mailed me to update me on his condition. He also passed along his liver test results, which I've graphed below. ALT is a liver enzyme that enters the bloodstream following liver damage such as hepatitis or NAFLD. It's below 50 units/L in a healthy person*. AST is another liver enzyme that's below 35 units/L in a healthy person*.

Steve began his new diet in November of 2008 and saw a remarkable and sustained improvement in his ALT and AST levels:

Here's how Steve described his diet change to me:

I totally eliminated sugar, heavy starches, and grains. Started eating more whole, real foods, including things like grass-fed beef and pastured pork and eggs, began supplementing with good fats and omega-3 (pastured butter, coconut oil, cod liver oil). Ate more fruits and vegetables instead of refined carbs. Also completely gave up on the idea that I had to eat only "lean" meats. After my last results, the GI doc said that I wouldn't need the biopsy at all, that things were great, and that if I kept it up I "would live forever."

He did experience some side effects from this diet though:

My triglycerides also went from pre-diet measures of 201 and 147 to post diet 86, 81, and 71.

The added bonus, of course, was that my weight went from 205 pounds to 162 pounds and my body fat percentage from 24% to 12% in the matter of five months--all without the typically excessive cardio I used to try unsuccessfully for weight loss.

The liver is the body's "metabolic grand central station". It's essential for nutrient homeostasis, insulin sensitivity, detoxification, and hormone conversion, among other things. What's bad for the liver is bad for the rest of the body as well. Don't poison your liver with sugar and industrial vegetable oils.


* The cutoff depends on who you ask, but these numbers are commonly used.

How to Fatten Your Liver
Excess Omega-6 Fat Damages Infants' Livers
Health is Multi-Factorial
Fatty Liver Reversal
Another Fatty Liver Reversal

Another Fatty Liver Reversal, Part II

A month ago, I wrote about a reader "Steve" who reversed his fatty liver using a change in diet. Non-alcoholic fatty liver disease (NAFLD) is a truly disturbing modern epidemic, rare a few decades ago and now affecting roughly a quarter of the adult population of modern industrialized nations. Researchers cause NAFLD readily in rodents by feeding them industrial vegetable oils or large amounts of sugar.

Steve recently e-mailed me to update me on his condition. He also passed along his liver test results, which I've graphed below. ALT is a liver enzyme that enters the bloodstream following liver damage such as hepatitis or NAFLD. It's below 50 units/L in a healthy person*. AST is another liver enzyme that's below 35 units/L in a healthy person*.

Steve began his new diet in November of 2008 and saw a remarkable and sustained improvement in his ALT and AST levels:

Here's how Steve described his diet change to me:

I totally eliminated sugar, heavy starches, and grains. Started eating more whole, real foods, including things like grass-fed beef and pastured pork and eggs, began supplementing with good fats and omega-3 (pastured butter, coconut oil, cod liver oil). Ate more fruits and vegetables instead of refined carbs. Also completely gave up on the idea that I had to eat only "lean" meats. After my last results, the GI doc said that I wouldn't need the biopsy at all, that things were great, and that if I kept it up I "would live forever."

He did experience some side effects from this diet though:

My triglycerides also went from pre-diet measures of 201 and 147 to post diet 86, 81, and 71.

The added bonus, of course, was that my weight went from 205 pounds to 162 pounds and my body fat percentage from 24% to 12% in the matter of five months--all without the typically excessive cardio I used to try unsuccessfully for weight loss.

The liver is the body's "metabolic grand central station". It's essential for nutrient homeostasis, insulin sensitivity, detoxification, and hormone conversion, among other things. What's bad for the liver is bad for the rest of the body as well. Don't poison your liver with sugar and industrial vegetable oils.


* The cutoff depends on who you ask, but these numbers are commonly used.

How to Fatten Your Liver
Excess Omega-6 Fat Damages Infants' Livers
Health is Multi-Factorial
Fatty Liver Reversal
Another Fatty Liver Reversal

Another Fatty Liver Reversal, Part II

A month ago, I wrote about a reader "Steve" who reversed his fatty liver using a change in diet. Non-alcoholic fatty liver disease (NAFLD) is a truly disturbing modern epidemic, rare a few decades ago and now affecting roughly a quarter of the adult population of modern industrialized nations. Researchers cause NAFLD readily in rodents by feeding them industrial vegetable oils or large amounts of sugar.

Steve recently e-mailed me to update me on his condition. He also passed along his liver test results, which I've graphed below. ALT is a liver enzyme that enters the bloodstream following liver damage such as hepatitis or NAFLD. It's below 50 units/L in a healthy person*. AST is another liver enzyme that's below 35 units/L in a healthy person*.

Steve began his new diet in November of 2008 and saw a remarkable and sustained improvement in his ALT and AST levels:

Here's how Steve described his diet change to me:

I totally eliminated sugar, heavy starches, and grains. Started eating more whole, real foods, including things like grass-fed beef and pastured pork and eggs, began supplementing with good fats and omega-3 (pastured butter, coconut oil, cod liver oil). Ate more fruits and vegetables instead of refined carbs. Also completely gave up on the idea that I had to eat only "lean" meats. After my last results, the GI doc said that I wouldn't need the biopsy at all, that things were great, and that if I kept it up I "would live forever."

He did experience some side effects from this diet though:

My triglycerides also went from pre-diet measures of 201 and 147 to post diet 86, 81, and 71.

The added bonus, of course, was that my weight went from 205 pounds to 162 pounds and my body fat percentage from 24% to 12% in the matter of five months--all without the typically excessive cardio I used to try unsuccessfully for weight loss.

The liver is the body's "metabolic grand central station". It's essential for nutrient homeostasis, insulin sensitivity, detoxification, and hormone conversion, among other things. What's bad for the liver is bad for the rest of the body as well. Don't poison your liver with sugar and industrial vegetable oils.


* The cutoff depends on who you ask, but these numbers are commonly used.

How to Fatten Your Liver
Excess Omega-6 Fat Damages Infants' Livers
Health is Multi-Factorial
Fatty Liver Reversal
Another Fatty Liver Reversal

Another Fatty Liver Reversal, Part II

A month ago, I wrote about a reader "Steve" who reversed his fatty liver using a change in diet. Non-alcoholic fatty liver disease (NAFLD) is a truly disturbing modern epidemic, rare a few decades ago and now affecting roughly a quarter of the adult population of modern industrialized nations. Researchers cause NAFLD readily in rodents by feeding them industrial vegetable oils or large amounts of sugar.

Steve recently e-mailed me to update me on his condition. He also passed along his liver test results, which I've graphed below. ALT is a liver enzyme that enters the bloodstream following liver damage such as hepatitis or NAFLD. It's below 50 units/L in a healthy person*. AST is another liver enzyme that's below 35 units/L in a healthy person*.

Steve began his new diet in November of 2008 and saw a remarkable and sustained improvement in his ALT and AST levels:

Here's how Steve described his diet change to me:

I totally eliminated sugar, heavy starches, and grains. Started eating more whole, real foods, including things like grass-fed beef and pastured pork and eggs, began supplementing with good fats and omega-3 (pastured butter, coconut oil, cod liver oil). Ate more fruits and vegetables instead of refined carbs. Also completely gave up on the idea that I had to eat only "lean" meats. After my last results, the GI doc said that I wouldn't need the biopsy at all, that things were great, and that if I kept it up I "would live forever."

He did experience some side effects from this diet though:

My triglycerides also went from pre-diet measures of 201 and 147 to post diet 86, 81, and 71.

The added bonus, of course, was that my weight went from 205 pounds to 162 pounds and my body fat percentage from 24% to 12% in the matter of five months--all without the typically excessive cardio I used to try unsuccessfully for weight loss.

The liver is the body's "metabolic grand central station". It's essential for nutrient homeostasis, insulin sensitivity, detoxification, and hormone conversion, among other things. What's bad for the liver is bad for the rest of the body as well. Don't poison your liver with sugar and industrial vegetable oils.


* The cutoff depends on who you ask, but these numbers are commonly used.

How to Fatten Your Liver
Excess Omega-6 Fat Damages Infants' Livers
Health is Multi-Factorial
Fatty Liver Reversal
Another Fatty Liver Reversal

The Diet-Heart Hypothesis: Oxidized LDL, Part II

In the last post, I presented the evidence that oxidized LDL (oxLDL) is a dominant factor in the arterial disease known as atherosclerosis, although probably not the only factor. In this post, I'll describe some of the major contributors to oxLDL.

Polyunsaturated Fats Increase LDL Oxidation

The serum concentration of oxLDL is strongly influcenced by diet. One dietary determinant of oxLDL is dietary polyunsaturated fat (PUFA). PUFA are inherently susceptible to oxidative damage, compared to monounsaturated and saturated fats. The predominant PUFA in the modern diet is linoleic acid, found excessively in industrial seed oils like corn oil, sunflower oil, safflower oil, cottonseed oil and soy oil. LDL is naturally rich in linoleic acid, even in cultures such as the Kitavans who have a very low dietary intake of it. However, LDL content of linoleic acid does correlate with dietary intake, and the Kitavans have a comparatively small amount of linoleic acid in their LDL, relative to industrial cultures.

There have been a number of media reports in the last few years proclaiming that monounsaturated fat reduces LDL oxidation compared to saturated and polyunsaturated fat. This is rather implausible on the surface, so let's take a closer look. There are two ways to measure oxLDL:

1. Measure it directly from the blood
   
2. Take normal LDL from the blood, expose it to copper in a test tube, and see how fast it oxidizes

The first reflects actual oxLDL in the blood, whereas the second reflects "susceptibility to oxidation" and has a dubious relationship with actual oxidized LDL in the bloodstream. This results in statements like the following (ref):

LDL resistance to copper-induced oxidation, expressed as lag time, was highest during the MUFA-rich diet (55.1±7.3 minutes) and lowest during the PUFA(n-3)– (45.3±7 minutes) and SFA- (45.3±6.4 minutes) rich diets.

This was published in a paper by P. Mata and colleagues in 1996. They fed 42 volunteers one of four different diets for 5 weeks each: one rich in saturated fat, one rich in monounsaturated fat, one rich in linoleic acid PUFA, and one rich in linoleic acid plus omega-3 PUFA. They emphasized the finding quoted above, as did the media. But there's an embarrassing piece of data buried in the paper that the authors, and the media, ignored (thanks to Chris Masterjohn for pointing this out). Here's what they saw when they looked directly at LDL oxidation in their volunteers:

Oops! LDL oxidation in the two PUFA groups was increased by more than 31%. The difference between the leftmost two groups and the rightmost two was statistically significant. As one would expect, oxidized LDL is proportional to the amount of PUFA in LDL, which is proportional to dietary PUFA. This somehow got left out of the abstract and media reports. The same investigators published a similar report a year later.

In another diet trial, participants were placed on one of two diets for 5 weeks: a low-fat, high PUFA diet low in vegetables; or a low-fat, high PUFA diet high in vegetables. The authors were forthright about their findings, so I'll let them summarize:

The median plasma OxLDL-EO6 increased by 27% (P less than 0.01) in response to the low-fat, low-vegetable diet and 19% (P less than 0.01) in response to the low-fat, high-vegetable diet. Also, the Lp(a) concentration was increased by 7% (P less than 0.01) and 9% (P=0.01), respectively.

This is the diet mainstream cardiologists have been prescribing to heart attack patients for 40 years. The trials I mentioned above are the only three I'm aware of in which fat quality was manipulated and oxLDL was directly measured (the first two were based on subsets of the same data). They all suggest that replacing saturated fat with PUFA increases oxLDL.

I suspect that the effect has less to do with the decrease in saturated fat and more to do with the increase in PUFA, although there's no way to know for sure. In the Lyon Diet-Heart trial, which I believe was the most successful diet trial of all time, linoleic acid was reduced to 3.6% of calories, but saturated fat was also reduced. Another reason is that there are numerous low-fat, low PUFA, high-carbohydrate cultures that have low levels of atherosclerosis and heart attacks. The Kitavans, for example, don't seem to have heart attacks or strokes (although no autopsies have been done so we don't know how much atherosclerosis they have).

They get 69% of their calories from high-glycemic starchy tubers, and their 21% fat comes mostly from coconut so it's highly saturated. Their blood lipids are low in omega-6 linoleic acid and very saturated. But there's a little surprise in the data: their lipids are full of palmitic acid (saturated), despite the fact that their diet contains very little of it. The reason is that their livers are turning all that carbohydrate into saturated fat, which is what happens when you eat more carbohydrate than you can burn immediately or store as glycogen. The moral of the story is that you don't need to eat saturated fat to have saturated LDL: a high-carbohydrate diet can accomplish the same thing, especially if it has a high glycemic index.

Fat-Soluble Antioxidants Decrease LDL Oxidation

LDL carries fat-soluble antioxidants, predominantly vitamin E and coenzyme Q10 (CoQ10). One form of vitamin E, alpha-tocopherol, slows atherosclerosis in most animal models but has shown equivocal results in human trials. There is even the suggestion that it may increase LDL oxidation under some circumstances. I don't recommend supplementing with vitamin E. However, the first line of antioxidant defense in LDL is provided by CoQ10. CoQ10 unequivocally reduces LDL oxidation in human subjects, and potently reduces atherosclerosis in animal models.

CoQ10 has a special relationship with cardiovascular health. Levels are reduced in individuals with cardiovascular disease and high oxLDL. Whether this is cause or effect, it's difficult to say. However, supplementing with CoQ10 has been repeatedly shown to be effective for high blood pressure and congestive heart failure. There has been one controlled trial of CoQ10 (120 mg/day) supplementation for the prevention of heart attacks, which reduced cardiac events including deaths by 45%, compared to a group receiving B vitamins. The CoQ10 group showed a large reduction in plasma lipid oxidation. This is a promising result and the experiment should be repeated.

CoQ10 is not an essential nutrient, although food does contribute a small portion of our total CoQ10 use. The large majority of CoQ10 is synthesized by the body itself, and this is dependent on a number of essential nutrients, including vitamin B2, B3, B5, B6, B12, vitamin C and folic acid. Thus, the body's synthesis of CoQ10 is dependent on overall nutritional status. Sub-clinical deficiency of any of these vitamins can hypothetically contribute to reduced CoQ10 production and thus oxLDL. This is potentially a big problem since modern Americans get more than half their calories from nutrient-poor refined foods. Liver is the single best source of many of these vitamins, and also holds the title of Most Nutritious Food on the Planet. It's also rich in CoQ10.

CoQ10 synthesis declines with age and is reduced in people with disorders involving oxidative stress, like cardiovascular disease. It's also greatly reduced by the cholesterol-lowering drugs statins. I'm not generally in favor of supplements, but CoQ10 seems to have a lot of promise and nothing but positive side effects that I'm aware of. CoQ10 deficiency may be a common theme in a number of modern disorders.

Excess Blood Sugar and Fructose Increase LDL Oxidation

Both type I and type II diabetes are associated with higher levels of oxLDL, therefore, prolonged high blood glucose may contribute to LDL oxidation due to glycosylation of the LDL protein ApoB. Fructose consumption increases oxLDL relative to glucose. Fructose is a very powerful glycosylating agent (binds non-specifically to other molecules, causing damage). Although it isn't present at high levels in the general circulation, it does interact with blood lipids in the hepatic portal vein as it moves from the digestive tract to the liver to be turned into fat (palmitic acid). Peter at Hyperlipid has written extensively about the role of glycosylation in LDL oxidation.

The Diet-Heart Hypothesis: The Verdict

The diet-heart hypothesis, the idea that dietary saturated fat and cholesterol raise blood cholesterol and thus increase heart attack risk, is a half-century embarrassment to the international scientific community. It requires willful ignorance of the fact that saturated fat does not increase total cholesterol or LDL in humans, in the long term. It requires a simplistic view of blood lipids that ignores the potentially harmful effects of replacing animal fats with carbohydrate or industrial seed oils. Worst of all, it requires selective citation of the literature on diet modification trials.

I have to conclude that if dietary saturated fat and cholesterol play any role whatsoever in cardiovascular disease, it's a minor one that's trumped by other factors. Industrial seed oils and sugar are likely to play an important role in cardiovascular disease.

The Diet-Heart Hypothesis: Oxidized LDL, Part II

In the last post, I presented the evidence that oxidized LDL (oxLDL) is a dominant factor in the arterial disease known as atherosclerosis, although probably not the only factor. In this post, I'll describe some of the major contributors to oxLDL.

Polyunsaturated Fats Increase LDL Oxidation

The serum concentration of oxLDL is strongly influcenced by diet. One dietary determinant of oxLDL is dietary polyunsaturated fat (PUFA). PUFA are inherently susceptible to oxidative damage, compared to monounsaturated and saturated fats. The predominant PUFA in the modern diet is linoleic acid, found excessively in industrial seed oils like corn oil, sunflower oil, safflower oil, cottonseed oil and soy oil. LDL is naturally rich in linoleic acid, even in cultures such as the Kitavans who have a very low dietary intake of it. However, LDL content of linoleic acid does correlate with dietary intake, and the Kitavans have a comparatively small amount of linoleic acid in their LDL, relative to industrial cultures.

There have been a number of media reports in the last few years proclaiming that monounsaturated fat reduces LDL oxidation compared to saturated and polyunsaturated fat. This is rather implausible on the surface, so let's take a closer look. There are two ways to measure oxLDL:

1. Measure it directly from the blood
   
2. Take normal LDL from the blood, expose it to copper in a test tube, and see how fast it oxidizes

The first reflects actual oxLDL in the blood, whereas the second reflects "susceptibility to oxidation" and has a dubious relationship with actual oxidized LDL in the bloodstream. This results in statements like the following (ref):

LDL resistance to copper-induced oxidation, expressed as lag time, was highest during the MUFA-rich diet (55.1±7.3 minutes) and lowest during the PUFA(n-3)– (45.3±7 minutes) and SFA- (45.3±6.4 minutes) rich diets.

This was published in a paper by P. Mata and colleagues in 1996. They fed 42 volunteers one of four different diets for 5 weeks each: one rich in saturated fat, one rich in monounsaturated fat, one rich in linoleic acid PUFA, and one rich in linoleic acid plus omega-3 PUFA. They emphasized the finding quoted above, as did the media. But there's an embarrassing piece of data buried in the paper that the authors, and the media, ignored (thanks to Chris Masterjohn for pointing this out). Here's what they saw when they looked directly at LDL oxidation in their volunteers:

Oops! LDL oxidation in the two PUFA groups was increased by more than 31%. The difference between the leftmost two groups and the rightmost two was statistically significant. As one would expect, oxidized LDL is proportional to the amount of PUFA in LDL, which is proportional to dietary PUFA. This somehow got left out of the abstract and media reports. The same investigators published a similar report a year later.

In another diet trial, participants were placed on one of two diets for 5 weeks: a low-fat, high PUFA diet low in vegetables; or a low-fat, high PUFA diet high in vegetables. The authors were forthright about their findings, so I'll let them summarize:

The median plasma OxLDL-EO6 increased by 27% (P less than 0.01) in response to the low-fat, low-vegetable diet and 19% (P less than 0.01) in response to the low-fat, high-vegetable diet. Also, the Lp(a) concentration was increased by 7% (P less than 0.01) and 9% (P=0.01), respectively.

This is the diet mainstream cardiologists have been prescribing to heart attack patients for 40 years. The trials I mentioned above are the only three I'm aware of in which fat quality was manipulated and oxLDL was directly measured (the first two were based on subsets of the same data). They all suggest that replacing saturated fat with PUFA increases oxLDL.

I suspect that the effect has less to do with the decrease in saturated fat and more to do with the increase in PUFA, although there's no way to know for sure. In the Lyon Diet-Heart trial, which I believe was the most successful diet trial of all time, linoleic acid was reduced to 3.6% of calories, but saturated fat was also reduced. Another reason is that there are numerous low-fat, low PUFA, high-carbohydrate cultures that have low levels of atherosclerosis and heart attacks. The Kitavans, for example, don't seem to have heart attacks or strokes (although no autopsies have been done so we don't know how much atherosclerosis they have).

They get 69% of their calories from high-glycemic starchy tubers, and their 21% fat comes mostly from coconut so it's highly saturated. Their blood lipids are low in omega-6 linoleic acid and very saturated. But there's a little surprise in the data: their lipids are full of palmitic acid (saturated), despite the fact that their diet contains very little of it. The reason is that their livers are turning all that carbohydrate into saturated fat, which is what happens when you eat more carbohydrate than you can burn immediately or store as glycogen. The moral of the story is that you don't need to eat saturated fat to have saturated LDL: a high-carbohydrate diet can accomplish the same thing, especially if it has a high glycemic index.

Fat-Soluble Antioxidants Decrease LDL Oxidation

LDL carries fat-soluble antioxidants, predominantly vitamin E and coenzyme Q10 (CoQ10). One form of vitamin E, alpha-tocopherol, slows atherosclerosis in most animal models but has shown equivocal results in human trials. There is even the suggestion that it may increase LDL oxidation under some circumstances. I don't recommend supplementing with vitamin E. However, the first line of antioxidant defense in LDL is provided by CoQ10. CoQ10 unequivocally reduces LDL oxidation in human subjects, and potently reduces atherosclerosis in animal models.

CoQ10 has a special relationship with cardiovascular health. Levels are reduced in individuals with cardiovascular disease and high oxLDL. Whether this is cause or effect, it's difficult to say. However, supplementing with CoQ10 has been repeatedly shown to be effective for high blood pressure and congestive heart failure. There has been one controlled trial of CoQ10 (120 mg/day) supplementation for the prevention of heart attacks, which reduced cardiac events including deaths by 45%, compared to a group receiving B vitamins. The CoQ10 group showed a large reduction in plasma lipid oxidation. This is a promising result and the experiment should be repeated.

CoQ10 is not an essential nutrient, although food does contribute a small portion of our total CoQ10 use. The large majority of CoQ10 is synthesized by the body itself, and this is dependent on a number of essential nutrients, including vitamin B2, B3, B5, B6, B12, vitamin C and folic acid. Thus, the body's synthesis of CoQ10 is dependent on overall nutritional status. Sub-clinical deficiency of any of these vitamins can hypothetically contribute to reduced CoQ10 production and thus oxLDL. This is potentially a big problem since modern Americans get more than half their calories from nutrient-poor refined foods. Liver is the single best source of many of these vitamins, and also holds the title of Most Nutritious Food on the Planet. It's also rich in CoQ10.

CoQ10 synthesis declines with age and is reduced in people with disorders involving oxidative stress, like cardiovascular disease. It's also greatly reduced by the cholesterol-lowering drugs statins. I'm not generally in favor of supplements, but CoQ10 seems to have a lot of promise and nothing but positive side effects that I'm aware of. CoQ10 deficiency may be a common theme in a number of modern disorders.

Excess Blood Sugar and Fructose Increase LDL Oxidation

Both type I and type II diabetes are associated with higher levels of oxLDL, therefore, prolonged high blood glucose may contribute to LDL oxidation due to glycosylation of the LDL protein ApoB. Fructose consumption increases oxLDL relative to glucose. Fructose is a very powerful glycosylating agent (binds non-specifically to other molecules, causing damage). Although it isn't present at high levels in the general circulation, it does interact with blood lipids in the hepatic portal vein as it moves from the digestive tract to the liver to be turned into fat (palmitic acid). Peter at Hyperlipid has written extensively about the role of glycosylation in LDL oxidation.

The Diet-Heart Hypothesis: The Verdict

The diet-heart hypothesis, the idea that dietary saturated fat and cholesterol raise blood cholesterol and thus increase heart attack risk, is a half-century embarrassment to the international scientific community. It requires willful ignorance of the fact that saturated fat does not increase total cholesterol or LDL in humans, in the long term. It requires a simplistic view of blood lipids that ignores the potentially harmful effects of replacing animal fats with carbohydrate or industrial seed oils. Worst of all, it requires selective citation of the literature on diet modification trials.

I have to conclude that if dietary saturated fat and cholesterol play any role whatsoever in cardiovascular disease, it's a minor one that's trumped by other factors. Industrial seed oils and sugar are likely to play an important role in cardiovascular disease.

The Diet-Heart Hypothesis: Oxidized LDL, Part II

In the last post, I presented the evidence that oxidized LDL (oxLDL) is a dominant factor in the arterial disease known as atherosclerosis, although probably not the only factor. In this post, I'll describe some of the major contributors to oxLDL.

Polyunsaturated Fats Increase LDL Oxidation

The serum concentration of oxLDL is strongly influcenced by diet. One dietary determinant of oxLDL is dietary polyunsaturated fat (PUFA). PUFA are inherently susceptible to oxidative damage, compared to monounsaturated and saturated fats. The predominant PUFA in the modern diet is linoleic acid, found excessively in industrial seed oils like corn oil, sunflower oil, safflower oil, cottonseed oil and soy oil. LDL is naturally rich in linoleic acid, even in cultures such as the Kitavans who have a very low dietary intake of it. However, LDL content of linoleic acid does correlate with dietary intake, and the Kitavans have a comparatively small amount of linoleic acid in their LDL, relative to industrial cultures.

There have been a number of media reports in the last few years proclaiming that monounsaturated fat reduces LDL oxidation compared to saturated and polyunsaturated fat. This is rather implausible on the surface, so let's take a closer look. There are two ways to measure oxLDL:

1. Measure it directly from the blood
   
2. Take normal LDL from the blood, expose it to copper in a test tube, and see how fast it oxidizes

The first reflects actual oxLDL in the blood, whereas the second reflects "susceptibility to oxidation" and has a dubious relationship with actual oxidized LDL in the bloodstream. This results in statements like the following (ref):

LDL resistance to copper-induced oxidation, expressed as lag time, was highest during the MUFA-rich diet (55.1±7.3 minutes) and lowest during the PUFA(n-3)– (45.3±7 minutes) and SFA- (45.3±6.4 minutes) rich diets.

This was published in a paper by P. Mata and colleagues in 1996. They fed 42 volunteers one of four different diets for 5 weeks each: one rich in saturated fat, one rich in monounsaturated fat, one rich in linoleic acid PUFA, and one rich in linoleic acid plus omega-3 PUFA. They emphasized the finding quoted above, as did the media. But there's an embarrassing piece of data buried in the paper that the authors, and the media, ignored (thanks to Chris Masterjohn for pointing this out). Here's what they saw when they looked directly at LDL oxidation in their volunteers:

Oops! LDL oxidation in the two PUFA groups was increased by more than 31%. The difference between the leftmost two groups and the rightmost two was statistically significant. As one would expect, oxidized LDL is proportional to the amount of PUFA in LDL, which is proportional to dietary PUFA. This somehow got left out of the abstract and media reports. The same investigators published a similar report a year later.

In another diet trial, participants were placed on one of two diets for 5 weeks: a low-fat, high PUFA diet low in vegetables; or a low-fat, high PUFA diet high in vegetables. The authors were forthright about their findings, so I'll let them summarize:

The median plasma OxLDL-EO6 increased by 27% (P less than 0.01) in response to the low-fat, low-vegetable diet and 19% (P less than 0.01) in response to the low-fat, high-vegetable diet. Also, the Lp(a) concentration was increased by 7% (P less than 0.01) and 9% (P=0.01), respectively.

This is the diet mainstream cardiologists have been prescribing to heart attack patients for 40 years. The trials I mentioned above are the only three I'm aware of in which fat quality was manipulated and oxLDL was directly measured (the first two were based on subsets of the same data). They all suggest that replacing saturated fat with PUFA increases oxLDL.

I suspect that the effect has less to do with the decrease in saturated fat and more to do with the increase in PUFA, although there's no way to know for sure. In the Lyon Diet-Heart trial, which I believe was the most successful diet trial of all time, linoleic acid was reduced to 3.6% of calories, but saturated fat was also reduced. Another reason is that there are numerous low-fat, low PUFA, high-carbohydrate cultures that have low levels of atherosclerosis and heart attacks. The Kitavans, for example, don't seem to have heart attacks or strokes (although no autopsies have been done so we don't know how much atherosclerosis they have).

They get 69% of their calories from high-glycemic starchy tubers, and their 21% fat comes mostly from coconut so it's highly saturated. Their blood lipids are low in omega-6 linoleic acid and very saturated. But there's a little surprise in the data: their lipids are full of palmitic acid (saturated), despite the fact that their diet contains very little of it. The reason is that their livers are turning all that carbohydrate into saturated fat, which is what happens when you eat more carbohydrate than you can burn immediately or store as glycogen. The moral of the story is that you don't need to eat saturated fat to have saturated LDL: a high-carbohydrate diet can accomplish the same thing, especially if it has a high glycemic index.

Fat-Soluble Antioxidants Decrease LDL Oxidation

LDL carries fat-soluble antioxidants, predominantly vitamin E and coenzyme Q10 (CoQ10). One form of vitamin E, alpha-tocopherol, slows atherosclerosis in most animal models but has shown equivocal results in human trials. There is even the suggestion that it may increase LDL oxidation under some circumstances. I don't recommend supplementing with vitamin E. However, the first line of antioxidant defense in LDL is provided by CoQ10. CoQ10 unequivocally reduces LDL oxidation in human subjects, and potently reduces atherosclerosis in animal models.

CoQ10 has a special relationship with cardiovascular health. Levels are reduced in individuals with cardiovascular disease and high oxLDL. Whether this is cause or effect, it's difficult to say. However, supplementing with CoQ10 has been repeatedly shown to be effective for high blood pressure and congestive heart failure. There has been one controlled trial of CoQ10 (120 mg/day) supplementation for the prevention of heart attacks, which reduced cardiac events including deaths by 45%, compared to a group receiving B vitamins. The CoQ10 group showed a large reduction in plasma lipid oxidation. This is a promising result and the experiment should be repeated.

CoQ10 is not an essential nutrient, although food does contribute a small portion of our total CoQ10 use. The large majority of CoQ10 is synthesized by the body itself, and this is dependent on a number of essential nutrients, including vitamin B2, B3, B5, B6, B12, vitamin C and folic acid. Thus, the body's synthesis of CoQ10 is dependent on overall nutritional status. Sub-clinical deficiency of any of these vitamins can hypothetically contribute to reduced CoQ10 production and thus oxLDL. This is potentially a big problem since modern Americans get more than half their calories from nutrient-poor refined foods. Liver is the single best source of many of these vitamins, and also holds the title of Most Nutritious Food on the Planet. It's also rich in CoQ10.

CoQ10 synthesis declines with age and is reduced in people with disorders involving oxidative stress, like cardiovascular disease. It's also greatly reduced by the cholesterol-lowering drugs statins. I'm not generally in favor of supplements, but CoQ10 seems to have a lot of promise and nothing but positive side effects that I'm aware of. CoQ10 deficiency may be a common theme in a number of modern disorders.

Excess Blood Sugar and Fructose Increase LDL Oxidation

Both type I and type II diabetes are associated with higher levels of oxLDL, therefore, prolonged high blood glucose may contribute to LDL oxidation due to glycosylation of the LDL protein ApoB. Fructose consumption increases oxLDL relative to glucose. Fructose is a very powerful glycosylating agent (binds non-specifically to other molecules, causing damage). Although it isn't present at high levels in the general circulation, it does interact with blood lipids in the hepatic portal vein as it moves from the digestive tract to the liver to be turned into fat (palmitic acid). Peter at Hyperlipid has written extensively about the role of glycosylation in LDL oxidation.

The Diet-Heart Hypothesis: The Verdict

The diet-heart hypothesis, the idea that dietary saturated fat and cholesterol raise blood cholesterol and thus increase heart attack risk, is a half-century embarrassment to the international scientific community. It requires willful ignorance of the fact that saturated fat does not increase total cholesterol or LDL in humans, in the long term. It requires a simplistic view of blood lipids that ignores the potentially harmful effects of replacing animal fats with carbohydrate or industrial seed oils. Worst of all, it requires selective citation of the literature on diet modification trials.

I have to conclude that if dietary saturated fat and cholesterol play any role whatsoever in cardiovascular disease, it's a minor one that's trumped by other factors. Industrial seed oils and sugar are likely to play an important role in cardiovascular disease.