In his epic work Nutrition and Physical Degeneration, Dr. Weston Price documented the abnormal dental development and susceptibility to tooth decay that accompanied the adoption of modern foods in a number of different cultures throughout the world. Although he quantified changes in cavity prevalence (sometimes finding increases as large as 1,000-fold), all we have are Price's anecdotes describing the crooked teeth, narrow arches and "dished" faces these cultures developed as they modernized.
Price published the first edition of his book in 1939. Fortunately, Nutrition and Physical Degeneration wasn't the last word on the matter. Anthropologists and archaeologists have been extending Price's findings throughout the 20th century. My favorite is Dr. Robert S. Corruccini, currently a professor of anthropology at Southern Illinois University. He published a landmark paper in 1984 titled "An Epidemiologic Transition in Dental Occlusion in World Populations" that will be our starting point for a discussion of how diet and lifestyle factors affect the development of the teeth, skull and jaw (Am J. Orthod. 86(5):419)*.
First, some background. The word occlusion refers to the manner in which the top and bottom sets of teeth come together, determined in part by the alignment between the upper jaw (maxilla) and lower jaw (mandible). There are three general categories: - Class I occlusion: considered "ideal". The bottom incisors (front teeth) fit just behind the top incisors.
- Class II occlusion: "overbite." The bottom incisors are too far behind the top incisors. The mandible may appear small.
- Class III occlusion: "underbite." The bottom incisors are beyond the top incisors. The mandible protrudes.
Malocclusion means the teeth do not come together in a way that's considered ideal. The term "class I malocclusion" is sometimes used to describe crowded incisors when the jaws are aligning properly.
Over the course of the next several posts, I'll give an overview of the extensive literature showing that hunter-gatherers past and present have excellent occlusion, subsistence agriculturalists generally have good occlusion, and the adoption of modern foodways directly causes the crooked teeth, narrow arches and/or crowded third molars (wisdom teeth) that affect the majority of people in industrialized nations. I believe this process also affects the development of the rest of the skull, including the face and sinuses. In his 1984 paper, Dr. Corruccini reviewed data from a number of cultures whose occlusion has been studied in detail. Most of these cultures were observed by Dr. Corruccini personally. He compared two sets of cultures: those that adhere to a traditional style of life and those that have adopted industrial foodways. For several of the cultures he studied, he compared it to another that was genetically similar. For example, the older generation of Pima indians vs. the younger generation, and rural vs. urban Punjabis. He also included data from archaeological sites and nonhuman primates. Wild animals, including nonhuman primates, almost invariably show perfect occlusion. The last graph in the paper is the most telling. He compiled all the occlusion data into a single number called the "treatment priority index" (TPI). This is a number that represents the overall need for orthodontic treatment. A TPI of 4 or greater indicates malocclusion (the cutoff point is subjective and depends somewhat on aesthetic considerations). Here's the graph: Every single urban/industrial culture has an average TPI of greater than 4, while all the non-industrial or less industrial cultures have an average TPI below 4. This means that in industrial cultures, the average person requires orthodontic treatment to achieve good occlusion, whereas most people in more traditionally-living cultures naturally have good occlusion.
The best occlusion was in the New Britain sample, a precontact Melanesian hunter-gatherer group studied from archaeological remains. The next best occlusion was in the Libben and Dickson groups, who were early Native American agriculturalists. The Pima represent the older generation of Native Americans that was raised on a somewhat traditional agricultural diet, vs. the younger generation raised on processed reservation foods. The Chinese samples are immigrants and their descendants in Liverpool. The Punjabis represent urban vs. rural youths in Northern India. The Kentucky samples represent a traditionally-living Appalachian community, older generation vs. processed food-eating offspring. The "early black" and "black youths" samples represent older and younger generations of African-Americans in the Cleveland and St. Louis area. The "white parents/youths" sample represents different generations of American Caucasians.
The point is clear: there's something about industrialization that causes malocclusion. It's not genetic; it's a result of changes in diet and/or lifestyle. A "disease of civilization". I use that phrase loosely, because malocclusion isn't really a disease, and some cultures that qualify as civilizations retain traditional foodways and relatively good teeth. Nevertheless, it's a time-honored phrase that encompasses the wide array of health problems that occur when humans stray too far from their ecological niche. I'm going to let Dr. Corruccini wrap this post up for me:
I assert that these results serve to modify two widespread generalizations: that imperfect occlusion is not necessarily abnormal, and that prevalence of malocclusion is genetically controlled so that preventive therapy in the strict sense is not possible. Cross-cultural data dispel the notion that considerable occlusal variation [malocclusion] is inevitable or normal. Rather, it is an aberrancy of modern urbanized populations. Furthermore, the transition from predominantly good to predominantly bad occlusion repeatedly occurs within one or two generations' time in these (and other) populations, weakening arguments that explain high malocclusion prevalence genetically.
* This paper is worth reading if you get the chance. It should have been a seminal paper in the field of preventive orthodontics, which could have largely replaced conventional orthodontics by now. Dr. Corruccini is the clearest thinker on this subject I've encountered so far.
I just found another very interesting study performed in Japan by Dr. Hajime Haimoto and colleagues (free full text). They took severe diabetics with an HbA1c of 10.9% and put them on a low-carbohydrate diet: The main principle of the CRD [carbohydrate-restricted diet] was to eliminate carbohydrate-rich food twice a day at breakfast and dinner, or eliminate it three times a day at breakfast, lunch and dinner... There were no other restrictions. Patients on the CRD were permitted to eat as much protein and fat as they wanted, including saturated fat.
What happened to their blood lipids after eating all that fat for 6 months, and increasing their saturated fat intake to that of the average American? LDL decreased and HDL increased, both statistically significant. Oops. But that's water under the bridge. What we really care about here is glucose control. The patients' HbA1c (glycated hemoglobin; a measure of average blood glucose over the past several weeks) declined from 10.9 to 7.4%. Here's a graph showing the improvement in HbA1c. Each line represents one individual:Every single patient improved, except the "dropout" who stopped following the diet advice after 3 months (the one line that shoots back up at 6 months). And now, an inspirational anecdote from the paper:One female patient had an increased physical activity level during the study period in spite of our instructions. However, her increase in physical activity was no more than one hour of walking per day, four days a week. She had implemented an 11% carbohydrate diet without any antidiabetic drug, and her HbA1c level decreased from 14.4% at baseline to 6.1% after 3 months and had been maintained at 5.5% after 6 months.
That patient began with the highest HbA1c and ended with the lowest. Complete glucose control using only diet and exercise. It may not work for everyone, but it's effective in some cases. The study's conclusion:...the 30%-carbohydrate diet over 6 months led to a remarkable reduction in HbA1c levels, even among outpatients with severe type 2 diabetes, without any insulin therapy, hospital care or increase in sulfonylureas. The effectiveness of the diet may be comparable to that of insulin therapy.
Diabetics on a Low-carbohydrate DietThe Tokelau Island Migrant Study: Diabetes
Dr. Staffan Lindeberg has published a new study using the "paleolithic diet" to treat type II diabetics (free full text). Type II diabetes, formerly known as late-onset diabetes until it began appearing in children, is typically thought to develop as a result of insulin resistance (a lowered tissue response to the glucose-clearing function of insulin). This is often followed by a decrease in insulin secretion due to degeneration of the insulin-secreting pancreatic beta cells.After Dr. Lindeberg's wild success treating patients with type II diabetes or glucose intolerance, in which he normalized the glucose tolerance of all 14 of his volunteers in 12 weeks, he set out to replicate the experiment. This time, he began with 13 men and women who had been diagnosed with type II diabetes for an average of 9 years. Patients were put on two different diets for 3 months each. The first was a "conventional diabetes diet". I read a previous draft of the paper in which I believe they stated it was based on American Diabetes Association guidelines, but I can't find that statement in the final draft. In any case, here are the guidelines from the methods section:The information on the Diabetes diet stated that it should aim at evenly distributed meals with increased intake of vegetables, root vegetables, dietary fiber, whole-grain bread and other whole-grain cereal products, fruits and berries, and decreased intake of total fat with more unsaturated fat. The majority of dietary energy should come from carbohydrates from foods naturally rich in carbohydrate and dietary fiber. The concepts of glycemic index and varied meals through meal planning by the Plate Model were explained [18]. Salt intake was recommended to be kept below 6 g per day.
The investigators gave the paleolithic group the following advice:The information on the Paleolithic diet stated that it should be based on lean meat, fish, fruit, leafy and cruciferous vegetables, root vegetables, eggs and nuts, while excluding dairy products, cereal grains, beans, refined fats, sugar, candy, soft drinks, beer and extra addition of salt. The following items were recommended in limited amounts for the Paleolithic diet: eggs (≤2 per day), nuts (preferentially walnuts), dried fruit, potatoes (≤1 medium-sized per day), rapeseed or olive oil (≤1 tablespoon per day), wine (≤1 glass per day). The intake of other foods was not restricted and no advice was given with regard to proportions of food categories (e.g. animal versus plant foods). The evolutionary rationale for a Paleolithic diet and potential benefits were explained.
Neither diet was restricted in calories. After comparing the effects of the two diets for 3 months, the investigators concluded that the paleolithic diet:- Reduced HbA1c more than the diabetes diet (a measure of average blood glucose)
- Reduced weight, BMI and waist circumference more than the diabetes diet
- Lowered blood pressure more than the diabetes diet
- Reduced triglycerides more than the diabetes diet
- Increased HDL more than the diabetes diet
However, the paleolithic diet was not a cure-all. At the end of the trial, 8 out of 13 patents still had diabetic blood glucose after an oral glucose tolerance test (OGTT). This is compared to 9 out of 13 for the diabetes diet. Still, 5 out of 13 with "normal" OGTT after the paleolithic diet isn't bad. The paleolithic diet also significantly reduced insulin resistance and increased glucose tolerance, although it didn't do so more than the diabetes diet.As has been reported in other studies, paleolithic dieters ate fewer total calories than the comparison group. This is part of the reason why I believe that something in the modern diet causes hyperphagia, or excessive eating. According to the paleolithic diet studies, this food or combination of foods is neolithic, and probably resides in grains, refined sugar and/or dairy. I have my money on wheat and sugar, with a probable long-term contribution from industrial vegetable oils as well. Were the improvements on the paleolithic diet simply due to calorie restriction? Maybe, but keep in mind that neither group was told to restrict its caloric intake. The reduction in caloric intake occurred naturally, despite the participants presumably eating to fullness. I suspect that the paleolithic diet reset the dieters' body fat set-point, after which fat began pouring out of their fat tissue. They were supplementing their diets with body fat-- 13 pounds (6 kg) of it over 3 months. The other notable difference between the two diets, besides food types, was carbohydrate intake. The diabetes diet group ate 56% more carbohydrate than the paleo diet group, with 42% of their calories coming from it. The paleolithic group ate 32% carbohydrate. Could this have been the reason for the better outcome of the paleolithic group? I'd be surprised if it wasn't a factor. Advising a diabetic to eat a high-carbohydrate diet is like asking someone who's allergic to bee stings to fetch you some honey from your bee hive. Diabetes is a disorder of glucose intolerance. Starch is a glucose polymer. Although to be fair, participants on the diabetes diet did improve in a number of ways. There's something to be said for eating whole foods. This trial was actually a bit of a disappointment for me. I was hoping for a slam dunk, similar to Lindeberg's previous study that "cured" all 14 patients of glucose intolerance in 3 months. In the current study, the paleolithic diet left 8 out of 13 patients diabetic after 3 months. What was the difference? For one thing, the patients in this study had well-established diabetes with an average duration of 9 years. As Jenny Ruhl explains in her book Blood Sugar 101, type II diabetes often progresses to beta cell loss, after which the pancreas can no longer secrete an adequate amount of insulin.This may be the critical finding of Dr. Lindeberg's two studies: type II diabetes can be prevented when it's caught at an early stage, such as pre-diabetes, whereas prolonged diabetes may cause damage that cannot be completely reversed though diet. I think this is consistent with the experience of many diabetics who have seen an improvement but not a cure from changes in diet. Please add any relevant experiences to the comments. Collectively, the evidence from clinical trials on the "paleolithic diet" indicate that it's a very effective treatment for modern metabolic dysfunction, including excess body fat, insulin resistance and glucose intolerance. Another way of saying this is that the modern industrial diet causes metabolic dysfunction.Paleolithic Diet Clinical TrialsPaleolithic Diet Clinical Trials Part IIOne Last ThoughtPaleolithic Diet Clinical Trials Part III
Researchers have developed a number of animal models of atherosclerosis (fatty/fibrous lesions in the arteries that influence heart attack risk) to study the factors that affect its development. In the next two posts, I will argue that these models rely on a massive increase in LDL, up to 10-fold, due to overloading the cholesterol metabolism of herbivorous species with excessive dietary cholesterol. This also greatly increases oxidized LDL, leading to atherosclerosis. I will discuss the role of saturated fat, which often receives the blame, in this process.A reader recently sent me a reference to an interesting paper titled "Dietary Fat Saturation Effects on Low-density-lipoprotein Concentrations and Metabolism in Various Animal Models". It's a review of animal studies that have looked at the effect of different fats on LDL concentration as of 1997.
When an investigator wants to study diet-induced atherosclerosis, first he selects a species that's susceptible to it. These are generally herbivorous or nearly herbivorous species such as rabbits, guinea pigs, hamsters, and several species of monkey. Then, he feeds it an "atherogenic diet". This is typically a combination of 0.1 to 1% cholesterol by weight, plus 20-40% of calories as fat. The fat can come from a variety of sources, but animal fats or saturated vegetable fats are typical. The remainder of the diet is processed grains, vitamin and mineral supplements, and often casein for protein.Let's put that amount of cholesterol into human context. Assuming the average person eats about 2 pounds dry weight of food per day, 0.5% cholesterol would be 4.5 grams. That's the equivalent of:- 17.5 pounds of beef steak, or
- 3.8 pounds of beef liver, or
- 22.5 eggs
Per day. Now feed that to an herbivore that's not adapted to clearing cholesterol. You can imagine it doesn't do their blood lipids any favors. For example, in one study, compared to a low-fat, low-cholesterol "control diet", a diet of 20% hydrogenated coconut oil plus 0.12% cholesterol caused hamsters' LDL to increase by more than 7-fold. A polyunsaturated fat (PUFA) rich diet caused LDL to increase less. This study is typical, and the interpretation is typical as well: SFA raises LDL. But there's another possible explanation: in the absence of unnatural amounts of dietary cholesterol, PUFA reduces LDL in some species, and SFA has very little effect on it in most.It's important to remember that the relevance of this hamster experiment to humans is unclear. No one is claiming that reducing saturated fat and cholesterol will reduce a human's LDL by 7-fold. But let's get back to the animal models. The hypothesis the paper addresses is that saturated fat raises LDL in animal models. If that is true, it should be able to raise LDL even in the absence of added cholesterol. So let's consider only the studies that didn't add extra cholesterol to the diets. And if saturated fat raises LDL, it should also do it relative to monounsaturated fat (MUFA- like olive oil), rather than only in comparison to PUFA, which has a known cholesterol-lowering effect. So let's narrow the studies further to those that compared SFA-rich fats, MUFA-rich fats and PUFA-rich fats. In Fernandez et al. (1989), investigators fed guinea pigs 35% of calories from corn oil (PUFA), olive oil (MUFA) or lard (MUFA-SFA). Here's what their LDL looked like:The same investigators published two more studies showing similar results over the next five years. The next study was published by Khosla et al. in 1992. They fed cebus and rhesus monkeys cholesterol-free diets containing 40% of calories from safflower oil (PUFA), high-oleic safflower oil (MUFA) or palm oil (SFA-MUFA). How was their LDL?None of the differences were statistically significant. Khosla and colleagues published another study with the same result in 1993. This is hardly supportive of the idea that saturated fat raises LDL in animal models. The most you can say is that PUFA lowers LDL in some, but not all, species. There is no indication from these studies that SFA raises LDL in the absence of excessive dietary cholesterol. I didn't cherry pick studies here; this is every study in the review paper that met my two criteria of no added cholesterol and a MUFA comparison group. The bottom line is that experimental models of atherosclerosis appear to rely on overloading herbivorous species with dietary cholesterol that they are not equipped to clear. SFA does exacerbate the increase in LDL caused by cholesterol overload. But in the absence of excess cholesterol, it does not necessarily raise LDL even in species ill-equipped to digest these types of fats. Dietary cholesterol has a modest effect on LDL cholesterol in humans, and it has even less effect on LDL particle number, a more important measure. So there may not be a cholesterol overload for saturated fat to exacerbate in humans. PUFA vegetable oils do lower LDL in humans, and the effect appears to persist for at least a few years (probably indefinitely). But the evidence is not conclusive that lowering cholesterol in this way actually prevents heart attacks.