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Eating Healthy with Cruciferous Vegetables

Many people are familiar with the term "cruciferous vegetables" and can even identify a vegetable like broccoli as belonging to this group. But because research on cruciferous vegetables has skyrocketed over the past three to seven years, many people are not familiar with the latest science on this age-old group of vegetables.

The name "cruciferous vegetables" is itself undergoing change! This group of vegetables was originally named for the four equal-sized petals in its flowers that could be viewed as forming a cross-like or crucifix shape. But many scientists are starting to favor the term "brassica vegetables" over "cruciferous vegetables" and the traditional name of this plant family in Latin, Cruciferae, is now being largely replaced by the Latin name Brassicaceae. (In Latin, the word "brassica" simply translates as "cabbage," and cabbage is definitely a featured member of this vegetable group.)

You'll also hear farmers referring to foods in this vegetable group as "cole crops." The word 'cole' (which is easy to spot in the word "coleslaw," a dish usually made from cabbage but also from cruciferous vegetables like broccoli) once again takes us back to the Latin language; it comes from the word "caulis" that refers to the stalks of plants, especially to the stalk of the cabbage plant. (Interestingly, you can find this Latin root not in the cabbages that so commonly represent the broader family of cruciferous vegetables, but in cauliflower, which is another important member of this vegetable group.) Cruciferous vegetables are also sometimes referred to as the mustard family vegetables, since the widely popular mustard greens'and mustard seeds and mustard oils'also belong to this vegetable group.

The table below contains a comprehensive list of cruciferous vegetables that are commonly consumed as a part of cuisines worldwide:

Cruciferous Vegetables

  • Arugula
  • Bok choy
  • Broccoli
  • Brussels sprouts
  • Cabbage
  • Cauliflower
  • Chinese cabbage
  • Collard greens
  • Daikon radish
  • Horseradish
  • Kale
  • Kohlrabi
  • Land cress
  • Mustard greens
  • Radish
  • Rutabaga
  • Shepherd's purse
  • Turnip
  • Watercress

The above list makes it clear that we should also be thinking about spices like brown mustard seed, yellow mustard seed, and horseradish as cruciferous vegetables, because they are! Health-supportive molecules like glucosinolates are concentrated in these spices in the same way that they are concentrated in the leaves of the plants (like mustard greens or horseradish greens).

Two especially common scientific groupings of cruciferous vegetables are the Brassica oleracea (broccoli, Brussels sprouts, cabbage, cauliflower, collards, kale, and kohlrabi) and the Brassica rapa (Chinese cabbage and turnips). Brassica campestris is another name for the genus-species grouping called Brassica rapa.

Conventional Nutrients in Cruciferous Vegetables

In terms of conventional nutrients (vitamins, minerals, proteins, carbs, and fats), we cannot find another vegetable group that is as high in vitamin A carotenoids, vitamin C, folic acid, and fiber as the cruciferous vegetables. As a group, the cruciferous vegetables are simply superstars in these conventional nutrient areas.

The vitamin K content of cruciferous vegetables'especially kale and collards'is fascinating to think about in light of intensive research over the past five years on cancer, inflammation, and cruciferous vegetables. Vitamin K is a conventional nutrient that clearly helps regulate our inflammatory response, including chronic, excessive inflammatory responses that can increase our risk of certain cancers. Studies on cruciferous vegetables and cancer prevention have not typically focused on vitamin K per se, but we suspect that the amazing K content of cruciferous vegetables is definitely related to their cancer-preventive properties through mechanisms involving better control of inflammation.

The astonishing concentration of vitamin A carotenoids in cruciferous vegetables and their unusually high content of vitamin C and manganese are clearly key components in their growing reputation as an antioxidant vegetable group. Scientific interest in the antioxidant function of the cruciferous vegetables has been sufficient to trigger funding of isotope studies on cruciferous vegetables that document the uptake of antioxidants in these foods from our digestive tract into our bloodstream. We've seen studies on 13C-labeled kale that show impressive bioavailability of beta-carotene, lutein, and retinol from this cruciferous vegetable. Significant increases in the blood levels of these key antioxidant nutrients have been seen very quickly in subjects who consume generous amounts of cruciferous vegetables in research studies. ("Generous" in one such study meant consumption of 3 cups of blanched, chopped broccoli during a meal.) The antioxidant richness of cruciferous vegetables has also been explicitly mentioned in several recent studies as one of the strong contributors to the risk-lowering impact of cruciferous vegetables on numerous forms of cancer.

One hundred calories' worth of cruciferous vegetables (about 5-6% of a daily diet) provides about 25-40% of your daily fiber requirement! That fact shows what an incredible bargain cruciferous vegetables are when it comes to fiber. We suspect that it's one of the reasons these vegetables have become increasingly prominent in research studies on diet and digestive support. We may not typically think about cruciferous vegetables when considering digestive disorders or risk of digestive tract cancers, but we should.

Two additional macronutrients'proteins and fats'also deserve special mention with respect to recent research on cruciferous vegetables. We tend to think about legumes, nuts, seeds, meats, dairy, and fish as the diet's pre-eminent protein sources'as they are. But cruciferous vegetables can contribute a surprising amount of protein to the diet—over 25% of the Daily Value in 3 cups—and at a very low calorie cost. Two hundred calories of steamed broccoli will provide you with 20 grams of protein—not as much as the 30 grams in two hundred calories of roasted chicken breast—but still a very substantial amount. We suspect that the substantial protein content of cruciferous vegetables may contribute to their risk-lowering impact on certain cancers, partially due to their support of detoxification. (Especially during Phase 2 detoxification, certain amino acids found in protein are known to play a critical role.)

We are no more likely to think about cruciferous vegetables as pre-eminent sources of fat in the diet than we are to think about them as pre-eminent sources of protein. In particular, cruciferous vegetables don't make many popular lists of omega-3 fats and their most important food sources. However, 100 calories' worth of cruciferous vegetables typically gives us somewhere between one-third and one-half of a gram of omega-3 fat (333-500 milligrams). This omega-3 fat is primarily in the form of ALA (alpha-linolenic acid), which serves as the basic building block for all other forms of omega-3 fats in the body. The past 5 years of greatly expanded research on cruciferous vegetables and inflammation points to the omega-3 content of cruciferous vegetables as a potentially critical component of their unique health benefits.

The chart below summarizes the conventional nutrient richness of some widely consumed cruciferous vegetables:

Cruciferous Vegetables Nutrient Content

(Amount for each vegetable = 100 calories)

Nutrient Broccoli (chopped & steamed) Brussels sprouts (boiled) Cabbage (shredded & boiled) Collard greens (chopped & boiled) Kale (chopped & boiled)
Vitamin A (IU) 5178 1840 600 12,008 26,455
Vitamin B1 (mg) 0.20 0.28 0.27 0.16 0.19
Vitamin B2 (mg) 0.41 0.20 0.24 0.40 0.25
Vitamin B3 (mg) 2.13 1.56 1.27 2.20 1.51
Vitamin B5 (mg) 1.8 0.64 0.64 0.83 0.17
Vitamin B6 (mg) 0.50 0.46 0.52 0.48 0.50
Folic acid (mcg) 213 154 91 357 48
Vitamin C (mg) 279 159 91 70 147
Vitamin E (mg) 1.70 2.18 0.70 3.37 2.58
Vitamin K(mcg) 351 359 221 1422 2921
Iron (mg) 3.1 3.1 0.79 1.76 3.22
Magnesium (mg) 88 51 36 65 64
Manganese (mg) 0.77 0.57 0.55 2.16 1.49
Phosphorous (mg) 234 143 68 100 100
Potassium (mg) 1146 810 439 998 815
Zinc (mg) 1.41 0.51 0.42 1.62 0.72
Protein (g) 10.6 6.5 4.6 9.5 6.8
Fiber (g) 10.6 6.7 10.5 10.7 7.15
Omega-3 fatty acids (g) 0.45 0.43 0.52 0.36 0.36

Cruciferous Vegetable Phytonutrients

As impressive as they are in terms of their conventional nutrient content, cruciferous vegetables are even more renowned for their phytonutrients. During the past five years, cruciferous vegetables have largely taken over the world of research in the area of glucosinolates, phytonutrients that clearly have their headquarters in the cruciferous vegetable group. Thanks to research on cruciferous vegetables, scientists have now identified over 100 different glucosinolates in food, and without cruciferous vegetables in our diet, we simply cannot get optimal intake of the glucosinolates. What's so special about glucosinolates is their potential for cancer prevention. Once converted into other molecules called isothiocyanates, the glucosinolates have an eye-opening track record in lowering the risk of certain cancers. The list below summarizes key glucosinolates found in cruciferous vegetables:

Glucosinolates in Cruciferous Vegetables with Known Health Benefits

  • Erucin
  • Glucoallyn
  • Glucobrassicanapin
  • Gluconapin
  • Gluconasturtin
  • Glucoraphanin
  • Iberin
  • Progoitrin
  • Sinigrin
  • 4-methoxyglucobrassicin

In our article "Feeling Great with Cruciferous Vegetables" we talk in detail about glucosinolates and explain exactly how they accomplish their cancer-preventive effects.

Understanding Differences between Raw and Cooked Cruciferous Vegetables

Recent research shows a definite dietary place for cruciferous vegetables in both raw and cooked form. Studies in this area have expanded in recent years, and scientists understand better than ever about the different paths taken by cruciferous vegetables when prepared in different ways. When consumed in raw form, it appears especially helpful for us to have freshly picked cruciferous vegetables. The greater potential benefits here involve enzymes. When cruciferous vegetables like broccoli are freshly picked (for example, within the previous 48 hours), their enzymes are much more likely to remain active. This better chance of enzyme activity—including activity of the enzyme myrosinase—gives us a better chance of having phytonutrients like glucosinolates converted into uniquely health-supportive molecules (like isothiocyanates). When consumed in fresh, raw, uncooked form, nutrients from the cruciferous vegetables that we eat are also more likely to be absorbed in the upper digestive tract, transported to the liver, and made available to other tissues in the body that might benefit from their presence.

When cruciferous vegetables are consumed in cooked form, and especially if they have not been allowed to sit chopped for several minutes prior to cooking, there is unlikely to be much enzyme activity (including myrosinase activity), and the digestive products of the cruciferous vegetables are more likely to pass through the upper digestive tract unabsorbed and continue down into the lower digestive tract (colon). At that point in the digestive process, the cruciferous vegetable nutrients are very likely to be further metabolized by bacteria. Some of the risk reduction seen for colon cancer following intake of cruciferous vegetables may be related to this passage of cooked cruciferous vegetable nutrient down through the digestive tract all the way to the colon without being absorbed. One way to increase availability of enzyme breakdown products in the upper digestive tract, however, is to chop raw cruciferous vegetables and let them sit in chopped form for several minutes prior to cooking. This process will allow myrosinase enzymes to go to work prior to their deactivation by cooking heats.

Eventually, researchers may be able to tell us the exact advantages and disadvantages for each consumption form of cruciferous vegetables (raw and cooked). In addition, researchers predict that we may one day understand how to match individual genetic tendencies with the best mix of cruciferous vegetables and the best balance of raw-versus-cooked consumption. At present, however, we can only conclude that both raw and cooked forms of cruciferous vegetables are very likely to have a place in optimal nourishment.

If we look exclusively at cooked cruciferous vegetables, however, and compare different cooking methods and their pros and cons, we will definitely find new information in the research that is well worth noting. First is the preference of steaming over microwaving. In a study that compared steaming versus microwaving of raw cabbage, researchers found that it took 7 minutes of steaming to result in the same about of enzyme (myrosinase) destruction that occurred with only 2 minutes of microwaving. In other words, short steaming was much better than microwaving for preserving some myrosinase activity in the cabbage. Researchers in this study also found higher concentrations of one particular isothiocyanate (AITC, or allyl-isothiocyanate) in lightly steamed cabbage, and for this reason they concluded that light steaming of cabbage might provide some unique health benefits. Steaming, of course, cooks foods at 212°F/100°C, a relatively low heat. We're convinced that this relatively low level of heat was important in providing steamed cabbage with its higher AITC content. Along this same line of thinking, we've seen another cruciferous vegetable study showing successful delivery of glucosinolates in broccoli to a group of study participants in the form of broccoli soup. Like steamed cabbage, broccoli soup is likely to expose this cruciferous vegetable to a relatively low cooking temperature and help preserve desirable nutrients for this reason.

We'd like to make one final comment about preparation of foods in this cruciferous vegetable food group. Especially within the average U.S. diet, it's difficult to find another food group in which as many different parts of the food are consumed. Within the cruciferous vegetable group, we commonly eat the flowers of the plant (for example, the broccoli florets), the leaves (for example, mustard greens, collard greens, turnip greens, and kale), the stems and stalks (for example, broccoli stems and stalks), the roots (for example, turnips or rutabagas or radishes), and the seeds (for example, mustard seeds). The unique benefits of this cruciferous vegetables food group may be partly related to inclusion of so many different plant parts in a diet that includes cruciferous foods. Particularly when it comes to phytonutrients, plants distribute nutrients differently in their different anatomical parts. The fact that we commonly include so many different parts of cruciferous plants in our diet may help us broaden the diversity of phytonutrients that we get from this food group. Given this diversity of cruciferous plant parts, it's also important to remember that different parts may require different cooking times for optimal nutrient retention.

Bitterness of Taste of Cruciferous Vegetables

From a chemistry standpoint, the taste of all foods is complicated. A wide variety of different substances contribute to the taste of any particular food. In addition, our individual biochemistry causes us to perceive taste differently, and the exact same food containing the exact same substances can taste extremely different to different people. In the case of cruciferous vegetables, however, a large percentage of individuals describe a certain bitterness of taste, and in research, this taste has been linked to a wide variety of phytonutrients, including glucosinolates, terpenoids, and flavonoids. Recent research has also linked the bitterness of taste in cruciferous vegetables with calcium content. Turnip greens, for example, which taste far more bitter to many people than cabbage, contain about 4 times more calcium than their fellow cruciferous vegetable. Although the commercial food industry has sometimes attempted to breed out bitter-tasting constituents from cruciferous vegetables (including sinigrin, one of the glucosinolates especially plentiful in cabbage), that practice does not make sense if we want to optimize our nourishment from this vegetable group. A much healthier approach would involve the blending of cruciferous vegetables with differently flavored foods in such a way that the cruciferous vegetables retain some of their natural and noticeable bitterness but within a blended-flavor context that makes the dish delicious!

Unique Nourishment from Cruciferous Vegetables--A Practical Summary

We are not aware of any food group that matches cruciferous vegetables for what we would call integrated nourishment across such a wide variety of nutritional categories. There are important amounts of macronutrients including fiber, protein, and omega-3s in this group. There are showcase amounts of many antioxidant, anti-inflammatory, and detox-related nutrients. Many B-complex vitamins are unusually concentrated in cruciferous vegetables, as are certain minerals. This food group also contains its own unique set of phytonutrients&mdah;the glucosinolates—that are simply unavailable to the same extent in any other food group. By commonly consuming all parts of plants from this group, including flowers, leaves, stems, stalks, roots, and seeds, we allow this cruciferous vegetable group to integrate together an unusually wide range of nutrients that is broader than any other single food group subdivision in the average U.S. diet. For all of these reasons, and based on the latest research evidence, we cannot say enough about the healthiness of this food group for most every individual diet plan.

References

Ambrosone CB and Tang L. Cruciferous vegetable intake and cancer prevention: role of nutrigenetics. Cancer Prev Res (Phila Pa). 2009 Apr;2(4):298-300.

Angeloni C, Leoncini E, Malaguti M et al. Modulation of phase II enzymes by sulforaphane: implications for its cardioprotective potential. J Agric Food Chem. 2009 Jun 24;57(12):5615-22.

Higdon JV, Delage B, Williams DE et al. Cruciferous Vegetables and Human Cancer Risk: Epidemiologic Evidence and Mechanistic Basis. Pharmacol Res. 2007 March; 55(3): 224-236.

Hofmann T, Kuhnert A, Schubert A et al. Modulation of detoxification enzymes by watercress: in vitro and in vivo investigations in human peripheral blood cells. Eur J Nutr. 2009 Dec;48(8):483-91.

Kelemen LE, Cerhan JR, Lim U et al. Vegetables, fruit, and antioxidant-related nutrients and risk of non-Hodgkin lymphoma: a National Cancer Institute-Surveillance, Epidemiology, and End Results population-based case-control study. Am J Clin Nutr. 2006 Jun;83(6):1401-10.

Li F, Hullar MAJ, Schwarz Y et al. Human Gut Bacterial Communities Are Altered by Addition of Cruciferous Vegetables to a Controlled Fruit- and Vegetable-Free Diet. Journal of Nutrition, Vol. 139, No. 9, 1685-1691, September 2009.

Nettleton JA, Steffen LM, Mayer-Davis EJ et al. Dietary patterns are associated with biochemical markers of inflammation and endothelial activation in the Multi-Ethnic Study of Atherosclerosis (MESA). Am J Clin Nutr. 2006 Jun;83(6):1369-79.

Prawan A, Saw CL, Khor TO et al. Anti-NF-kappaB and anti-inflammatory activities of synthetic isothiocyanates: effect of chemical structures and cellular signaling. Chem Biol Interact. 2009 May 15;179(2-3):202-11.

Rungapamestry V, Duncan AJ, Fuller Z et al. Effect of cooking brassica vegetables on the subsequent hydrolysis and metabolic fate of glucosinolates. Proc Nutr Soc. 2007 Feb;66(1):69-81.

Tang L, Zirpoli GR, Guru K et al. Consumption of Raw Cruciferous Vegetables is Inversely Associated with Bladder Cancer Risk. Cancer Res. 2007 Apr 15;67(8):3569-73.

Taraseviien Z, Danilenko E, Jarien E et al. Changes in Some Chemical Components During Germination of Broccoli Seeds

Journal: Notulae Botanicae Horti Agrobotanici Cluj-Napoca Year: 2009 Vol: 37 Issue: 2 Pages/record No.: 173-176.

Thompson CA, Habermann TM, Wang AH et al. Antioxidant intake from fruits, vegetables and other sources and risk of non-Hodgkin's lymphoma: the Iowa Women's Health Study. Int J Cancer. 2010 Feb 15;126(4):992-1003.

Tordoff MG and Sandell MA. Vegetable bitterness is related to calcium content. Appetite. 2009 Apr;52(2):498-504.

Vasanthi HR, Mukherjee S and Das DK. Potential health benefits of broccoli- a chemico-biological overview.

Mini Rev Med Chem. 2009 Jun;9(6):749-59.

Yang G, Gao YT, Shu XO et al. Isothiocyanate exposure, glutathione S-transferase polymorphisms, and colorectal cancer risk. Am J Clin Nutr. 2010 Mar;91(3):704-11.

Zhang Y. Allyl isothiocyanate as a cancer chemopreventive phytochemical.Mol Nutr Food Res. 2010 Jan;54(1):127-35.

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