High Temperature Cooking

[Guest guest]

High-Temperature Cooking

JoAnn Guest

Nov 09, 2004 21:11 PST

===============================================================================

High-Temperature Cooking & the World’s Healthiest Foods

 

(Note: All temperatures below are reported

in Fahrenheit measurements).

 

One of the greatest insults to nourishment in our modern, fast-paced,

and processed food culture is the high heat at which so much of our food

is cooked.

 

We deep fat fry at 350-450 degrees; we fry on the stovetop in shortening

and vegetable oils right up until their smoke points of 375-450 degrees;

and we barbecue with gas grills that can reach temperatures of over 1000

degrees! This exposure of food to high heat may be convenient and quick,

and it may fill the air with aromas that we savor, but it comes at a

definite nutritional cost. Our food just wasn’t designed to withstand

extremely high temperatures.

 

Neither was the nutrients contained within our food.

 

Unwanted consequences of high-heat cooking

How you prepare the foods you eat can be just as important to your

health as what you eat

 

Nutritional research is just starting to catch up with the consequences

of our high-heat approach. We’ve learned, for example, that some of the

most mutagenic agents formed in cooking are called heterocyclic amines,

and they are commonly found in barbecued beef, chicken, and pork cooked

at 392 degrees or above.

 

We even know what the basic ingredients are required for these mutagenic

agents to be produced: high temperature for more than a few minutes

duration, free amino acids (from protein), creatine (or creatinine) and

sugar.

 

Without the high temperature component, the formation of heterocyclic

amines does not occur. Direct flame grilling produces another of type of

carcinogen called polyocyclic aromatic hydrocarbons, which might be just

as bad as the heterocyclic amines.

 

Researchers at Mt Sinai Medical found that foods cooked at high

temperature contain greater levels of compounds called advanced

glycation end products (AGEs) that cause more tissue damage and

inflammation than foods cooked at lower temperatures.

 

AGEs irritate cells in the body, damaging tissues and increasing your

risk of complications from diseases like diabetes and heart disease.

Those chemicals can be avoided by cooking meals at lower temperatures

through stir-frying, baking or poaching, and also by cooking meats with

foods containing antioxidant bioflavonoids, such as garlic, onion and

peppers.

 

Unfortunately, we’re not off the hook if we are vegetarian and don’t eat

beef, chicken, or pork. Very recent research has discovered that a

potentially toxic substance called acrylamide that is a carcinogenic

nerve damaging compound is also formed when certain foods are cooked at

high temperature.

 

Potato chips are a key target of research interest here, as are some

other foods, including flaked breakfast cereals, and roasted nuts. As is

the case with heterocyclic amines, acrylamide does not appear to form

when high cooking temperatures are absent.

 

The problems with high-heat cooking are not restricted to creation of

toxic substances, however. High-heat cooking is also problematic when it

comes to loss of nutrients. Virtually all nutrients in food are

susceptible to damage from heat.

 

Of course, whether a particular nutrient gets damaged depends on the

exact nutrient in question, the degree of heat, and the amount of

cooking time. But in general, most of the temperatures we cook at in the

oven (250-450 degrees) are temperatures at which substantial nutrient

loss occurs. And although very short cooking at 212 degrees in boiling

water produces relatively little nutrient loss, once boiling goes on for

anything more than a very short period of time (a couple of minutes) the

nutrient loss becomes significant.

 

Up to 80% of the folic acid in carrots, for example, can be lost from

boiling. Ditto for the amount of vitamin B1 in boiled soybeans. Even the

high heats involved with commercial food canning rob foods of vast

amounts of nutrients. In canned mixed vegetables, the vitamin C loss can

be as high as 67%.

 

In canned tomato juice, up to 70% of the original folic acid can be

lost.

 

We’ve searched and searched through the nutrition research, and all of

the evidence points to the same conclusion: prolonged, high-heat cooking

is just not the way to go.

 

Sometimes heating of food is essential

 

While we cannot find any evidence in favor of high-heat cooking for

extended time periods, we’ve found plenty of evidence in favor of

high-heat cooking for very short time periods, or for cooking at various

temperatures for relatively short periods of time. For some foods,

especially animal foods, cooking temperature and duration are associated

with food safety and elimination of potentially disease-causing

bacteria. Exposure to heat can actually increase the variety of

nutrients found in some foods.

For example, heat increases the variety of sulfur-containing compounds

found in onions and garlic since it triggers certain chemical reactions

that create variations in those sulfur compounds. Flavor, color, and

aroma can also be enhanced through cooking. We don’t know of any

traditional cuisines anywhere in the world that rely exclusively on raw

foods. Every healthy food tradition incorporates some aspects of

cooking.

 

Our senses can tell us a lot

Sometimes scientific research just reminds us that we can trust our five

senses and our own good judgment. This conclusion seems to apply to

high-heat cooking. Almost always, there is some magical point at which

our senses begin to dislike the result of the high-heat.

 

It may be a color change in the kale or collards, where the green ceases

to become more and more vibrant and begins to take on a duller, grayer

shade. It may be a change in air and aroma, as occurs when a vegetable

oil starts to smoke. Vegetables oils have unique smoke points that can

be more than 200 degrees apart.

 

Although we don’t like heating oils much at all, the fact that they

smoke is still a nice common-sense warning that high-heat is doing some

damage. If we expose foods to high heat for too long, our taste buds

will also let us know.

 

Vegetables and high-heat cooking

Throughout our website, we’ve tried to emphasize the wonderful diversity

and uniqueness of food. We’ve tried to pay attention to all of the

little details that make each fruit or vegetable or legume nutritionally

special. It should not be surprising that specific foods within any food

family must be treated just as uniquely when it comes to cooking.

Nevertheless, we’ve still found it amazing just how sensitive some foods

are when it comes to high-heat - especially vegetables!

 

When it comes to vegetables, sensitivity to high heat has to be measured

in matter of minutes! In some foods, like Swiss chard, loss of vitamin C

can increase by 15% in a matter of just 4-5 minutes. Swiss chard can’t

be cooked as an afterthought, while we are talking on the phone, or

setting the table, or feeding the cat. Just a few minutes can change the

outcome completely!

 

Green beans will steam in 3-7 minutes. During this time, their color

will take on a more vibrant green hue. But toward the end of this

7-minute period, a drop in color intensity will begin to occur. By 9 or

10 minutes, the color intensity will have dropped noticeably. Just 2-3

minutes of steaming can make this notable difference.

 

The optimal timetable for high-heat cooking will vary with a number of

factors in addition to the type of vegetable. How the vegetable is

sliced, for example, will change the amount of steaming it needs. Finely

shredded cabbage requires less steaming than coarsely shredded cabbage.

 

Because more surface of the finely shredded cabbage gets directly

exposed to the steam, it takes less time for the cabbage to become

tender. If you mix vegetables in the steamer basket, the top-most layers

that are more directly exposed to the steam should be the vegetables

needing the least steaming. The vegetables requiring longer steaming

should be placed on the bottom-most layer. Alternatively, vegetables

that need less steaming can be added to the steamer basket later on,

after the vegetables that are more coarse and dense have been added.

 

Why we like steam

You may think of steam as a high-heat way of cooking, but in comparison

to most other ways, it isn’t. Since water boils at 212 degrees and

transforms into steam, steam is actually a lower-heat way of cooking

than most oven-based approaches and most stove-top ones as well.

 

When compared with boiling, steaming is a better way of avoiding

nutrient loss, since the food is surrounded by water dispersed in air,

rather than being completely submerged in water alone.

 

The decreased contact of water with the surface of the food results in

decreased nutrient loss. If a food is sliced or chopped into

sufficiently small sections, steaming can get it into a tender and tasty

form long before most other heating methods. Even our butternut squash

can be perfectly steamed in under 20 minutes.

 

Cover the pot

It may sound silly, but covering the pot while steaming can help

preserve the nutritional quality of our food. When a pot is covered,

steam contact with the food is more consistent, allowing the steaming

process to be completed in the least amount of time.

 

In addition, light-sensitive nutrients - like vitamin B2 - will not be

leeched out of the food so easily. As an added benefit, many

water-soluble nutrients will pass out into the steam, and then drop back

down into the water below the steamer basket.

 

Save this water! It can be used as a base for soups and sauces, or at

the very minimum, allowed to cool and used to water plants in the

garden.

 

High-heat cooking and vegetable oils

There is no area of high-heat cooking that we are more concerned about

that the area of vegetable oils. We recognize that several companies

have produced very high-quality refined oils, specifically designed for

high-heat cooking.

 

The refinement of these oils raises their smoke point, sometimes by as

much as 200 degrees. In addition, we recognize that some vegetable oils

that would normally be very susceptible to high heat because of their

polyunsaturated fat content have been produced in such a way as to lower

this polyunsaturated fat content. We’re thinking here of a vegetable oil

like safflower oil, which ordinarily contains a lot of polyunsaturated

fat but relatively little monounsaturated fat. Today a version of

safflower oil is available called “high-oleic” safflower oil. (Oleic

acid is a monounsaturated fatty acid, and it’s less susceptible to heat

damage than the polyunsaturated fatty acids normally found in safflower

oil). This version of safflower oil can indeed withstand higher heats,

and is better for use with high heats than ordinary safflower oil.

 

At the same time, however, we wonder why any oil should be exposed to

high heat if there is a low-heat or no-heat alternative. We developed

our healthy stir-fry technique for precisely this reason - to avoid

unnecessary heating of vegetable oils. (The method we developed uses

vegetable broth instead of vegetable oil).

 

Extra virgin olive oil is our oil of choice at the World’s Healthiest

Foods, and it deserves special mention in this discussion of high heat.

 

Information of olive oil smoke point - associated with the level of high

heat it can withstand - is very confusing, and not at all consistent.

Manufacturers of extra virgin olive oil - the most nutrient-rich type of

olive oil from the very first pressing - list their smoke points as low

as 200 degrees and as high as 406 degrees! In general, we believe that

the lower limit of this range, somewhere between 200-250 degrees, is the

most likely upper limit for safe heating of extra virgin olive oil

without excessive damage to the oil. Inclusion of extra virgin olive oil

in products baked in the oven at 350 degrees would therefore be worth

avoiding, as would stir-frying in olive oil on the stove-top.

 

Inclusion of the fresh oil directly on salads, or as a late-addition to

some soups or sauces would prevent this high-heat exposure.

 

You’ll find very specific temperature and time recommendations

throughout our website. These temperatures and times are listed for all

individual foods, as well as for all recipes. You won’t find any

high-heat frying, or high-heat stir-frying in oil, or prolonged oven

exposure to high heat anywhere on our website. But you will find meals

that take about 15 minutes to prepare and turn out delicious!

 

We believe it is not only possible, but relatively easy, to live in our

fast-paced culture and avoid insulting the beauty of food with

unnecessary high heat.

 

References

Becalski A, Lau BP, Lewis D, Seaman SW. Acrylamide in foods: occurrence,

sources, and modeling. J Agric Food Chem 2003;51:802-8.

 

Kaack, K. Blanching of green bean (Phaseolus vulgaris). Plant Foods Hum

Nutr. 1994 Dec; 46(4):353-60.

 

Kimura, M. and Itokawa, Y. Cooking losses of minerals in foods and its

nutritional significance. J Nutr Sci Vitaminol (Tokyo). 1990; 36 Suppl

1:S25-32; discussion S33.

 

Larsson BK. Formation of polycyclic aromatic hydrocarbons during the

smoking and grilling of food. Prog Clin Biol Res 1986;206:169-80.

 

Mangels, A. R.; Block, G.; Frey, C. M.; Patterson, B. H.; Taylor, P. R.;

Norkus, E. P., and Levander, O. A. The bioavailability to humans of

ascorbic acid from oranges, orange juice and cooked broccoli is similar

to that of synthetic ascorbic acid. J Nutr. 1993 Jun; 123(6):1054-61

 

Moret S, Conte LS. Polycyclic aromatic hydrocarbons in edible fats and

oils: occurrence and analytical methods. J Chromatogr A 2000;882:245-53.

 

 

Nursal, B. and Yucecan, S. Vitamin C losses in some frozen vegetables

due to various cooking methods. Nahrung. 2000 Dec; 44(6):451-3.

 

Reiter, L. A. and Driskell, J. A. VitaminB-6 content of selected foods

served in dining halls. J Am Diet Assoc. 1985 Dec; 85(12):1625-7.

 

Shaw I, Thomson B. Acrylamide food risk. Lancet 2003;361:434.

 

Simko P. Determination of polycyclic aromatic hydrocarbons in smoked

meat products and smoke flavouring food additives. J Chromatogr B Analyt

Technol Biomed Life Sci 2002;770:3-18.

 

Stadler RH, Blank I, Varga N et al. Acrylamide from Maillard reaction

products. Nature 2002;419:449-50.

 

Thorkelsson G. The effect of processing on the content of polycyclic

aromatic hydrocarbons and volatile N-nitrosamines in cured and smoked

lamb meat. Bibl Nutr Dieta 1989;188-98.

 

Tilgner DJ, Daun H. Polycyclic aromatic hydrocarbons (polynuclears) in

smoked foods. Residue Rev 1969;27:19-41.

 

Weiss G. Cancer risks. Acrylamide in food: uncharted territory. Science

2002;297:27.

http://www.whfoods.com/genpage.php?tname=george & dbid=122

_________________

 

JoAnn Guest

mrsjo-

DietaryTi-

www.geocities.com/mrsjoguest/Genes

 

 

 

 

 

 

 

The complete " Whole Body " Health line consists of the " AIM GARDEN TRIO "

Ask About Health Professional Support Series: AIM Barleygreen

 

" Wisdom of the Past, Food of the Future "

 

http://www.geocities.com/mrsjoguest/AIM.html

 

PLEASE READ THIS IMPORTANT DISCLAIMER

We have made every effort to ensure that the information included in these pages

is accurate. However, we make no guarantees nor can we assume any responsibility

for the accuracy, completeness, or usefulness of any information, product, or

process discussed.

 

 

 

 

 

 

 

 

 

Check out the new Front Page. www.