A *very* special dual-fuel car analogy for the human body that I just invented.

The human body is like a very special dual-fuel car.

From http://www.aa1car.com/library/alternative_fuels.htm

In this very special dual-fuel car:-

Glucose is represented by Ethanol, 'cos Ethanol is a carbohydrate, according to Robert Lustig ;-)
Glucose is C₆H₁₂O₆. Ethanol is C₂H₆O. 3(C₂H₆O) = C₆H₁₈O₃. It's not very close, but it'll do!

Caprylic acid is represented by Octane, 'cos fatty acids are hydrocarbons, don'tcha know? ;-)
Caprylic acid is CH₃(CH₂)₆COOH and Octane is CH₃(CH₂)₆CH₃, which is actually pretty close.

Storage depots:

 

Carbohydrates:

For Ethanol, there's a large storage tank (≡ muscle glycogen) and a small storage tank (≡ liver glycogen). The contents of the large storage tank cannot be used to top-up the small storage tank, but the contents of the small storage tank can be used to top-up the large storage tank. The contents of the small storage tank are used to fuel a generator (≡ Hepatic Glucose Production) to keep the ECU (≡ brain) working at all times. The contents of the large storage tank are used to fuel the engine.

Fats:

For Octane, there's a large storage tank (≡ subcutaneous adipose tissue) and a small storage tank (≡ visceral adipose tissue). The contents of the small storage tank are used to produce hormones etc. The contents of the large storage tank are used to fuel the engine.

Substrate Utilisation:

When the car is driven at low speed, the engine burns mostly Octane (≡ RQ=0.7).
When the car is rapidly accelerating or driven at high speed, the engine burns mostly Ethanol (≡ RQ=1).
When the car is being driven intermediately, the engine burns a mixture of Octane & Ethanol.

Overeating/Undereating:

 

Carbohydrates:

If the large Ethanol storage tank becomes full, excess Ethanol overspills to the small storage tank.
If the small storage tank becomes full, a gizmo kicks-in and converts excess Ethanol into Octane (≡ De-Novo Lipogenesis).
It also shifts fuel usage of the engine towards Ethanol, to deplete Ethanol as quickly as possible.
If the small storage tank becomes full, the car malfunctions (≡ fatty liver).

Conversely, if the small storage tank becomes nearly empty, it shifts fuel usage of the engine towards Octane, to conserve Ethanol.

Fats:

If the large Octane storage tank becomes full, excess Octane overspills to the small storage tank.
If the small storage tank becomes full, the car malfunctions (≡ insulin resistance/metabolic syndrome/type 2 diabetes).

How low-carbohydrate diets are (incorrectly) explained to work.

Having explained how low-carbohydrate diets work, here are a few ways in which they don't work.

Uh, nope!

1. Hormonal clogs: This is a term used by Jonathan Bailor. I don't think he's referring to wooden shoes! The "clog", I'm guessing, is supposedly caused by that dastardly hormone insulin. Uh, nope!

See the following plots of RER vs exercise intensity after being on high-fat diet or low-fat diet.

RER = 0.7 ≡ 100%E from fat. RER ≥ 1.0 ≡ 100%E from carb.

The low-fat diet results in higher RER, so the body is burning a higher %E from carb and a lower %E from fat.

However, this doesn't make any difference to weight loss, as it's merely a substrate utilisation issue. In addition, when the body is burning a higher %E from carb, this depletes muscle glycogen stores faster, which lowers RER during the course of the exercise. So, it's not a problem.


2. Insulin: This is Gary Taubes' hypothesis. Insulin makes your body store carbohydrates as body fat. Uh, nope!

The only time that there's significant hepatic DNL is when there's chronic carbohydrate over-feeding. If you eat sensibly, there's no significant hepatic DNL.


3. A Calorie isn't a Calorie, where weight change is concerned: This is Richard D Feinman's hypothesis. "A calorie is a calorie" violates the second law of thermodynamics, therefore there's a metabolic advantage with low-carbohydrate diets. Uh, nope!

Where to start? Evelyn Kocur knows her Physics, so I'll start there. See The first law of thermodynamics (Part 1) and The first law of thermodynamics (Part 2).

From Second Law of Thermodynamics:-
"Living organisms are often mistakenly believed to defy the Second Law because they are able to increase their level of organization. To correct this misinterpretation, one must refer simply to the definition of systems and boundaries. A living organism is an open system, able to exchange both matter and energy with its environment."

People on ketogenic diets excrete very few kcals as ketone bodies. See STUDIES IN KETONE BODY EXCRETION. There is no significant Metabolic Advantage with low-carbohydrate diets.

Carbs, Carbs, Carbs, Carbs and Carbs.

Carbohydrates seem to get the blame for everything nowadays. "Carbohydrates made me fat". "Carbohydrates burned-out my pancreas". "Carbohydrates raised my blood glucose". "Carbohydrates raised my blood triglycerides". "Carbohydrates stole mer jerb!". O.K, I made the last one up!
If carbohydrates are responsible for all of these bad things, then how come a diet of only potatoes had the opposite effect? See 20 Potatoes a day.

Also, Blue Zone populations eat a diet with a high percentage of total energy (%E) from carbohydrates. See Low serum insulin in traditional Pacific Islanders--the Kitava Study and The Kitava Study. The Kitavans eat ~70%E from carbohydrates, ~20%E from fats and ~10%E from proteins. They don't eat a significant amount of Western crap-in-a-bag/box/bottle.

Maybe it has something to do with the type of carbohydrates and with what they're eaten. In A very-low-fat diet is not associated with improved lipoprotein profiles in men with a predominance of large, low-density lipoproteins , (emphasis, mine) "The very-low-fat, high-carbohydrate experimental diet was designed to supply less than 10% of energy from fat (2.7% saturated, 3.7% monounsaturated, and 2.6% polyunsaturated), with 75% from carbohydrate (with equal amounts of naturally occurring and added simple and complex carbohydrate) and 15% from protein." Simple carbohydrates are sugars.

The experimental diet which did bad things contained 37.5%E from sugars. I declare shenanigans!

1. There are simple carbs, there are simple carbs and there are simple carbs. In the previous post, the graph of plasma triglycerides after an OGTT showed that 100g of glucose had no significant effect on plasma triglycerides over a 6 hour period. If it had been 100g of fructose, there would have been a significant increase in plasma triglycerides. Galactose is taken-up by the liver and has minimal effect on blood glucose, but I don't know its effect on plasma triglycerides.

2. There are complex carbs, there are complex carbs and there are complex carbs. Overcooked starch is high in amylopectin which is highly-branched, which means that it hydrolyses rapidly into glucose which gives it a very high glycaemic index. Raw & refrigerated potato starches have very low glycaemic indices, due to the presence of amylose, or other resistant starches. Rice contains a mixture of starches which varies with rice type, cooking time and subsequent refrigeration.

3. There are oligosachharides e.g. FOS.

4. There are polysaccharides e.g. inulin.

5. There is soluble fibre/fiber e.g. cellulose.

Although overeating sugars containing fructose & starches that rapidly hydrolyse into glucose makes the liver fatty, overeating fats also makes the liver fatty. See Pathogenesis of type 2 diabetes: tracing the reverse route from cure to cause.

It's the chronic over-consumption of crap-in-a-bag/box/bottle (high in sugars and/or starches and/or fats), not just carbohydrates, that causes over-fatness and other health problems.