The skinny on healthy skin

Your skin is your largest organ.  On average, this amounts to about 2 square meters of surface and roughly 3 to 4 kilograms of mass. It helps protect you against potentially harmful substances, extreme temperatures and the Sun’s ultraviolet light. In turn, the skin’s three layers – the epidermis, dermis, and subcutis – depend on you to keep them healthy.  This means taking precautions to avoid the Sun’s damage and meeting your nutritional requirements on a regular basis.

Eat right

Aside from scheduling regular visits to the dermatologist, avoiding direct Sun light for extended periods of time, and wearing Sun screens (hats, long sleeves, umbrellas, lotions), you can make sure you consume a healthy diet which includes vitamins A, B, C, E and omega-3 fatty acids.

Vitamin A

Vitamin A refers to three compounds (retinol, aldehyde, and retinoic acid) called retinoids.  Plants contain carotenoids which are metabolized by the body to form retinoids, the most important of which is B-carotene.  About 50% to 80% of vitamin A in the body is stored in the liver.  The rest is spread out among the lungs, kidneys, adipose tissue and a number of specialized cells throughout the body (1).

Known by most people as being crucial for good vision, vitamin A also plays a role in cell function, growth, development and differentiation (and, thus, is important in keeping our skin healthy), immune function, reproduction and a number of systemic functions, such as gene expression.

The RDA for adults is 700-900 RAE (retinol activity equivalents) which translates into 700-900 mcg of retinol or 8,400-10,800 mcg of B-carotene per day, depending on gender and pregnancy status (1).

  • 1 small sweet potato = 7,374 RAE (about ten times the RDA, or 88,488 mcg of B-carotene)
  • 1 cup raw carrots = 5,553 RAE
  • 1 cup of cooked broccoli = 725 RAE
  • 2 medium tomatoes = 860 RAE
  • 1 cup cooked spinach = 6,882 RAE
  • 1 cup cantaloupe = 1,625 RAE

Given the abundance of carotenoids in the plant world, particularly in the orange and red fruits and vegetables category, it is relatively easy to meet our daily requirements.

Supplementation with vitamin A is contraindicated in the absence of a known deficiency and without medical supervision.  Although readily available in our food supply, vitamin A may be poorly absorbed by some individuals who suffer from pancreatic or liver disease or who lack fat and/or zinc in their diets. On the flip side, vitamin A toxicity is serious business. Regular consumption of vitamin A at 100 times or more the RDA may lead to liver disease, skin disorders, higher incidence of bone fractures (including hip) and lung cancer among smokers (1).

B vitamins

B vitamins, in particular niacin, help keep skin healthy.  Niacin is essential for energy production and metabolism.

Niacin in most plants and grains is covalently bound with peptides and carbohydrates that are not released during digestion. However, alkaline hydrolysis (the addition of water and alkali) makes niacin bioavailable (the Central American tradition of soaking grains in lime water before cooking is, thus, more than just a dietary preference as it serves an important purpose). Niacin is also synthesized from tryptophan (an essential amino acid) with moderate efficiency (60 mg of tryptophan yield 1 mg of niacin) (1).

Ready to eat cereals have the highest niacin content (up to 26 mg per serving, depending on brand).  Mushrooms, peanuts, coffee, breads and pasta all yield enough niacin to meet daily recommendations from just one serving.  Current DRI for adults is anywhere from 2 – 18 mg depending on age and gender (1).

Vitamin C

Vitamin C, aka ascorbic acid, is involved in many electron transport reactions, some of which are involved in collagen synthesis.  Collagen is a fibrous protein found primarily in connective tissue, cartilage, bone, teeth, skin and tendons.  Needless to say, it is important for maintaining healthy skin.  Lucky for us, vitamin C is abundant in most fruits and vegetables, making it relatively easy to meet daily requirements (15 to 120 mg per day depending on age and gender)(1).  In spite of this, vitamin C is one of the most commonly overconsumed supplements in the US and Canada. I can only guess that its popularity rests with the misguided belief that it prevents or cures the common cold.

Too much of this good thing may result in GI disturbances, an increased risk of some cancers (whereas, normal intake has the opposite effect), slight oxaluria, and false-positive urinary glucose test results (1).

Vitamin E

Vitamin E is the most important fat soluble antioxidant in the cell as it protects cell membranes from free radical activity.  It depends on other nutrients and enzymes to do its job, particularly copper, zinc, riboflavin and manganese.

Vitamin E is measured in terms of a-tocopherol equivalents (a-TE) of which adults need about 15 mg per day.

Tocopherols (and tocotrienols) are only synthesized in plants.  The average American, and to a lesser extent, the average Canadian, consumes most of his/her vitamin E in the form of vegetable oil even though healthier sources abound.  One ounce of almonds yields a whopping 7.33 mg (more than three times the amount found in one tablespoon of canola oil)(1).

Omega-3 fatty acids

There are three types of omega-3 fatty acids:  a-linolenic acid (ALA), eicosapentaenoic acid (EPA), and docosahexanoic acid (DHA).  Of these, ALA is an essential fatty acid (EFA), meaning it can not be synthesized by the human body, so, we must get it from food. Humans can desaturate and elongate ALA into EPA and DHA as needed, thus, it is important to include ALA in the diet on a regular basis (1).

The conversion rate of ALA to EPA and DHA is relatively low in persons who consume fish.  However, in vegetarians and vegans, the conversion rate is significantly higher, which explains the similarity of EPA and DHA levels between these groups and their meat-eating cohorts (2).  It is not necessary for vegetarians or vegans to supplement with EPA and DHA as long as they consume a healthy diet that meets their nutritional needs.  In all groups, conversion rates of ALA to EPA and DHA are higher in women (3).

EFA deficiency is rare and occurs primarily among newborns and infants.  Even in developing countries, where food is scarce, EFA deficiency is very low most likely because the most commonly consumed type of fat in such areas is usually vegetable based (vegetable fat is a good source of ALA)(4).


Lastly, stay hydrated inside and out.  Rather than smother your skin with lotion (which can actually draw moisture out of the skin), use a water bottle set on “mist” instead.  Obviously, this may not be the thing to do at the office, but while you’re outdoors or at home, opt for water.  It doesn’t cost anything and it is better for your skin than most other topical applications.


  1. Mahan LK, Escott-Stump S. Krause’s Food and Nutrition Therapy. MO: Saunders-Elsevier; 2008.
  2. Welch AA, Shakya-Shrestha S, Lentjes MAH, Wareham NJ, Khaw KT. Dietary intake and status of n-3 polyunsaturated fatty acids in a population of fish-eating and non-fish-eating meat-eaters, vegetarians, and vegans and the precursor-product ratio of a-linolenic acid to long-chain n-3 polyunsaturated fatty acids: results from the EPIC-Norfolk cohort. Am J Clin Nutr, 2010;92:1040-51.
  3. Burdge GC. Metabolism of a-linolenic acid in humans. Prostaglandins, leukotrienes and essential fatty acids, 2006;75(3):161-8.
  4. The Merck Manual for Health Care Professionals. Available at:  Accessed: August 9, 2012.

A word on iron

The most abundant metal in the body and an essential component of red blood cells, iron is primarily responsible for oxygen binding/transport and electron transport.  It’s important.  But too much of a good thing can have devastating effects and, iron, unlike other nutrients, can’t always be denied entry into the body or be ushered unceremoniously out the door when too much of its ilk has overstayed their welcome.  So, how much is too little or too much?  What can happen?  How do we make sure we meet our requirements without going overboard?

First, it is important to understand how and why our bodies manage dietary iron as they do.  At a time when Homo sapiens were at a significantly higher risk of losing their contents, in no small part due to being mauled by cave lions and the occasional prehistoric hyena, or by simply stepping off a cliff while trying to escape neighbouring tribes, we developed an iron storage mechanism to ensure rapid recovery should sudden loss of blood take place.  And it was great.  Particularly since the human body can synthesize blood cells by more than 20 times the rate at which it can incorporate dietary iron.  In the absence of existing iron stores, scarfing down copious amounts of red meat in such instances would have resulted in a well fed corpse and not much else.

The ability to store iron, however, came at a cost.  As the risk of sudden blood loss decreased with time, our bodies retained the pesky habit of storing excess iron with no mechanism in place to get rid of it should it exceed our needs.  Today, iron stores are obsolete, thanks to blood banks and modern medical interventions should accidents occur, but the liability of iron stores indefinitely hanging around remains.


In the healthy, young body, not a whole lot, and this is true for a number of other excesses such as the occasional alcohol overload after a night out on the town.  A healthy body disposes of over-consumed substances by excreting or incorporating them for later use.  Iron can’t be disposed of once absorbed, so, it gets packed away in bio-storage “bins” throughout the body.

The average 70 kg adult man has approximately 2,800 mg of iron in his body.  Contrast this to the amount of dietary iron intake recommended for the same:  about 8 mg per day.  Compared to the amount of iron our bodies recycle on a daily basis, the amount we need to eat seems minuscule, and, as such, harmless.  But is it harmless?  Not exactly.  One or more extra mg per day, every day, month, year, and decade build up to become a risk factor for heart disease and colon cancer.

While a risk factor is just that, and not necessarily an assurance that disease will develop, it is, none the less, wise to make an effort and eliminate as many risk factors as we can, within reason.  To do so, we must understand which type of iron is most likely to be of benefit and why, and we need to identify a number of sources from where to get it.


There are two types of dietary iron. Haem iron is found in hemoglobin (the protein in red blood cells responsible for carrying oxygen) in most animal based foods.  Approximately 20% to 30% of haem iron present in food is absorbed.  The rest ends up in our lower intestine stirring up trouble, so, you want to consume very little, if any, of this type of iron, particularly if you are male or post-menopausal.

Non-haem iron is found in plant foods, eggs, insects and any other animals who do not carry hemoglobin (i.e. red blood).  Uptake, transport, and storage is tightly regulated to prevent both iron deficiency and toxicity.  Absorption rates increase up to ten fold when iron stores are depleted.


In men and in postmenopausal women iron stores increase almost linearly with age, generating an additional risk for oxidative stress-related diseases like arteriosclerosis, chronic inflammatory diseases or cancer.

Cancer – regular consumption of heme-iron has been shown to increase the production of N-nitroso compounds (NOC’s) in the colon – NOC’s are carcinogenic and are usually involved in gastro-intestinal cancers.

Diabetes – low iron stores, such as those found among vegetarian populations, are inversely related to insulin sensitivity (low iron stores = high insulin sensitivity = lowered risk for diabetes). Conversely, the more stored iron a person has, the more insulin resistant s/he is, thus, increasing risk of developing diabetes.


Iron deficiency takes months to years to develop depending on dietary intake, gender, and age. Symptoms include: chronic fatigue, weakness, dizziness, headaches, difficulty thinking. Incidentally, some symptoms of iron overload overlap, so, it is best to leave the diagnosis to your family physician.

As iron is slowly depleted from stores, iron in hemoglobin remains normal. It is only once hemoglobin levels start to become affected that a deficiency is declared and when the body can no longer meet daily functional needs dependent on iron, the diagnosis becomes iron deficiency anemia. Low iron stores, however, do not necessarily lead to anemia.  This explains the lack of difference in anemia rates between vegetarian and non-vegetarian populations (vegetarians and vegans usually have lower iron stores than the rest of the population). In fact, there is no conclusive evidence that an absence of iron stores has any negative consequences in otherwise healthy individuals.  It is only when we are in negative balance that unpleasant things begin to happen.  Should this occur, reach for a good quality iron supplement and include more leafy greens in your diet until the problem is corrected.


Obesity – hepcidin, a peptide produced by the liver and adipose tissue is a key regulator of iron homeostasis. Obesity increases hepcidin expression which, in turn, increases iron deficiency risk by decreasing iron absorption and increasing chronic inflammation in the body.

Vitamin A deficiency – can also lead to anemia. Vitamin A plays a role in releasing iron from ferritin stores for use by the body. Approximately 50 carotenoids (i.e. alpha-, beta-, and gamma-carotene) are converted by the body into vitamin A. Sources include: eggs, fortified cereals, dark orange or green vegetables.

Diet – very low intake or lack of dietary sources of iron may eventually result in a negative balance of iron in the body, primarily in premenopausal women.

Menstruation – premenopausal women require higher intakes of iron to counteract monthly losses.


  • Adult men: 8 mg
  • Pre-menopausal women: 18 mg
  • Post-menopausal: 8 mg
  • Pregnant women: 27 mg
  • Athletes: depends on level of activity


In plants, leaves are the major site for iron accumulation. The amount of iron in leaves increases with leaf development, with mature leaves containing the highest amounts. The exception is legumes – iron is found in higher concentrations in the beans themselves.

Dietary iron in plant foods varies depending on crop growing conditions, the specific food type, and the part of the plant consumed. In soybeans, for example, much of the ferritin is found in the hulls. Thus, foods made from whole soy such as soymilk or soy nuts contain more ferritin than foods from dehulled soy beans or processed foods such as tofu.

The best vegetarian sources of iron include:

  • Legumes (lima, soy, peas, kidney beans)
  • Dried fruits (prunes, raisins, apricots)
  • Iron-fortified cereals (depending on type of iron used for fortification)
  • Whole grains (wheat, millet, oats, brown rice)
  • Vegetables (broccoli, spinach, kale, collards, asparagus, dandelion greens)


Phytate – antioxidant found in plant foods that, when consumed in excessive amounts, interferes with iron absorption. Soaking, fermentation, germination or cooking significantly decrease this effect.

Polyphenols – found in a variety of plant foods, but only significantly inhibitory in tea (both herbal and black), beans, and chili powder. Most common are tannins.

Calcium – inhibits non-heme iron absorption, so, try to abstain from drowning your veggies in cheese.

Although phytates, polyphenols and calcium inhibit absorption in single meals, consuming a varied diet provides a fair amount of protection against these effects.


Ascorbic acid – aka vitamin C, chelates iron and reduces it from ferric to ferrous form so that it can be absorbed more easily. When consumed along with polyphenols, the inhibiting effect of these is cancelled out and vice versa. The trick is not to cook the vitamin C when using it to enhance iron absorption (i.e. use lemon juice on your spinach, after the spinach has been cooked).

Ascorbyl palimate – is a derivative of ascorbic acid that is commonly found in processed foods. It has the same beneficiary effect and is not affected by high cooking temperatures (as in baking).


The World Health Organization (WHO) recommends fortifying foods (particularly flour) with ferrous sulfate, ferrous fumarate, ferric pyrophosphate, and electrolytic iron powder. Most food manufacturers, however, use low cost elemental iron powders that are contra-indicated by WHO. Thus, unless manufacturers start to follow WHO recommendations, the fortification you see on food labels doesn’t usually amount to a hill of beans.


Supplements are useful in replenishing iron stores, but should not be used indefinitely because they usually interfere with zinc absorption.


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