Posts Tagged ‘performance’

Vitamin D – Its Role in Health & Optimal Athletic Performance

Fitness, nutrition, performance, Recovery - Repair | Posted by admin May 24th, 2010

There are a pandemic number of people who are vitamin D deficient.  This has become evident due to increased discovery and sharing of documentation from clinical trials, epidemiological studies, and educational journals.  The end results from an alarming and growing number due to lack of sunshine exposure and inadequate supply of vitamin D from daily food intake.   This added to obesity trends, an aging population, and improved skin products that block formation of vitamin D3.  Until recently, vitamin D was understood to be solely related to bone mineralization and calcium utilization in the body.   Further studies have revealed vitamin D to play a leading role in many additional cell processes.  More than 36 cell types and 10 extra renal organs have been discovered to possess the vitamin D receptor, or VDR. Insufficient vitamin D is related to reduced immunological conditions, cancers of the breast, colon, pancreas, and prostate as well as heart diseases, type I diabetes, rheumatoid arthritis, cognitive impairment, and all cause mortality.  This impressive collection of medical conditions accounts for more than 60% of all deaths in the Western World.

What is Vitamin D?

A fat soluble pro-hormone, vitamin D is a seco-steroid which exists in two forms:  vitamin D2 & vitamin D3.  Vitamin D2 is obtained from yeast and plant material, vitamin D3 is produced endogenously in the skin by the photo-chemical conversion of 7-dehydrocholesterol. Vitamin D circulates in the body bound to the vitamin D binding protein, or VDBP.  Both vitamin D2 and D3 are converted to the biomarker 25-hydoxyvitamin [D (25(OH)D] in the liver and undergoes further hydroxylation in the kidneys to the bio-active form of the hormone 1,25(OH)2D.

The Frequency of vitamin D Deficiency:

The March 2010 issue of the Journal of Clinical Endocrinology & Metabolism points towards an overwhelming 59% of people that are vitamin D insufficient.  This was based on a cross-sectional study designed to establish a relationship between serum 25(OH)D and the degree of fat penetration in muscle.  These results have been duplicated as well in several independent studies of people from all over the United States in recent months.

Adverse Outcomes of Vitamin D Insufficiency:

Presence of 1,25(OH)2D and vitamin D receptors (VDR) in a wide variety of tissues ranging from pancreas, colon, brain, liver, muscle, skin and lung  speaks of its newly found broad involvement in the functionality of bodily systems.  Published literature over several years indicates that the non-bone mineralization effects of vitamin D are autocrine, not endocrine.  Thus, implying these functions are not based or derived for the amount of circulating 1,25(OH)2D in the body, but rather due to the intracellular synthesis of 1,25(OH)2D by these tissues.  Studies also indicate that the levels of 1,25(OH)2D required for these non-calcemic functions are higher than the levels of normal serum 1,25(OH)2D. 

Epidemiological evidences have linked deprived levels of vitamin D conditions to osteoporosis, osteoarthritis, obesity, multiple sclerosis, hypertension, type I diabetes and several cancers.  Vitamin is also effective in maintaining low susceptibility to infections including pulmonary diseases.

Conclusion:

Vitamin D has been shown to have an extensive area of biological influence due to the discovery of VDR and its conversion in several body tissues.  Health, strength and athletic performance can be optimized by measuring the residual levels of vitamin D at the cellular level to determine the degree of insufficiencies in order to adjust diets and nutritional supplements which directly influences athletic strength and recovery time.

Contact us for information on measuring residual vitamins & minerals by functional intracellular analysis at the cellular level – which is directly proportional to the body stores . . .

Reference:  Ray J, Meike W. D-Light: Vitamin D and Good Health. MLO. 2010;42(5):32-38

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Quercetin – May Increase Aerobic Endurance & Protect Health

Fitness, performance, Recovery - Repair | Posted by admin March 16th, 2010

Quercetin is a phytochemical that is part of the coloring found in the skins of apples and red onions. It has been isolated and is sold as a dietary supplement.

Healthy body:

Quercetin is a powerful antioxidant. It is also a natural anti-histamine, and anti-inflammatory. Research has shown quercetin may help to prevent cancer, especially prostate cancer. Quercetin’s antihistamine action may help to relieve allergic symptoms and asthma symptoms. The anti-inflammatory properties may help to reduce pain from disorders such as arthritis. Men who are concerned about prostate problems would also benefit from quercetin. Quercetin may also help reduce symptoms like fatigue, depression and anxiety. Another study has investigated the protection afforded by the flavonoid quercetin against macular degeneration. The macula is the yellowish, central part of the retina about 1.5 mm in diameter that produces central vision and color vision. Macular degeneration is the gradual, progressive destruction of the macula that results in lowered central visual acuity needed for most everyday activities, like reading this article. It leads to permanent blindness

Quercetin may not be a household word —

But a study by researchers at the University of South Carolina’s Arnold School of Public Health shows that the powerful antioxidant/anti-inflammatory compound found in fruits and vegetables significantly boosts endurance capacity and maximal oxygen capacity (VO2max) in healthy, active but untrained men and women.
The findings of the study – one of the first in humans to examine the energy-boosting effects of quercetin are reported in the International Journal of Sports Nutrition and Exercise Metabolism.

Dr. Mark Davis, the study’s lead author and a professor of exercise science, said the fatigue-fighting and health properties of quercetin – found in the skins of red apples, red onions, berries and grapes – have implications not only for athletes and soldiers whose energy and performance are tested to the extreme, but also for average adults who battle fatigue and stress daily.

“The natural, biological properties of quercetin that include powerful antioxidant and anti-imflammatory activity, as well as the ability to boost the immune system and increase mitochondria (the powerhouse of the cell) in muscle and brain is great news for those who often think that they’re too tired to exercise,”

Davis said. “While there’s no magic pill to make people get up and move, or to take the place of regular exercise, quercetin may be important in relieving the fatigue that keeps them sedentary and in providing some of the benefits of exercise,” he said. “We believe that this could be a major breakthrough in nutrition.”

For the study, funded in part by the U.S. Department of Defense, 12 participants were randomly assigned to one of two treatments. Half were given 500 milligrams of quercetin twice a day in Tang for seven days. The other subjects drank Tang with placebos. After the seven days of treatment, during which the subjects were told not to alter their physical activity, the participants rode stationary bicycles to the point of fatigue.

Researchers also tested their additional VO2max, one of the most important measures of fitness. Then the participants received the opposite treatment for another seven days before riding the bicycle to the point of fatigue and VO2max tests. Neither the participants nor the research staff knew who received the quercetin Tang or the placebo Tang, and all subjects took part in the quercetin and placebo treatments.

“The participants were healthy, relatively active, college-age students, but they were not physically trained athletes, and they were not taking part in a regular exercise training program,” he said. The results: After taking quercetin for only seven days, the participants had a 13.2 percent increase in endurance and a 3.9 percent increase in VO2max. “These were statistically significant effects that indicate an important improvement in endurance capacity in a very short time,” Davis said. “Quercetin supplementation was able to mimic some of the effects of exercise training.

Although the study did not examine why the results were so dramatic, Davis said pre-clinical data suggest that quercetin may increase the mitochondria in brain and muscle cells. He likened the mitochondria to the “powerhouse of the cell,” producing most of its energy. Mitochondria in brain and muscle also are believed to be fundamentally important in battling age-related dementia, obesity, diabetes and cardiovascular dysfunction.

“One of the most important biological mechanisms for increasing endurance is increasing the mitochondria,” said Davis. “More mitochondria in the brain and muscle would enhance both mental and physical energy, as well as provide a better ability to fight other diseases in which mitochondrial dysfunction are hallmarks.”
Quercetin also appears to have valuable properties to fight inflammation, which has been linked to health problems such as colon cancer and heart disease. Davis’ research group has recently received a National Institutes of Health grant to study quercetin’s effects on colon cancer and others are pending that involve breast cancer. “If the findings of this study and others on the biological mechanisms of quercetin are confirmed in future clinical studies, the implications go beyond improvements in endurance,” he said. “We may find that quercetin may work in conjunction with regular physical activity as an ally in preventing and treating diabetes, obesity and cardiovascular diseases and the degenerative diseases of aging.”

Reference: University of South Carolina’s Arnold School of Public Health

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CoQ10 – Reduce Muscle Injuries for Athletes?

performance, Recovery - Repair | Posted by admin January 5th, 2010

Marker levels associated with increased wear and tear in the muscle, like creatine kinase and lipid peroxide, were significantly lower in elite Japanese kendo athletes after consuming co-enzyme Q10 for 20 days, compared to placebo.

Researchers from University of Tsukuba, University of Tokyo, and Kobe Gakuin University report their findings in the British Journal of Nutrition.

The study adds to an ever growing body of studies supporting the benefits of the coenzyme for sports nutrition. Only recently, another Japanese group reported that CoQ10 supplements may boost physical performance and reduce feelings of tiredness associated with exercise (Nutrition, doi:10.1016/j.nut.2007.12.007).

CoQ10 has properties similar to vitamins, but since it is naturally synthesized in the body it is not classed as a vitamin. With chemical structure 2,3-dimethoxy-5-methyl-6-decaprenyl-1,4-benzoquinone, it is also known as ubiquinone because of its ‘ubiquitous’ distribution throughout the human body.

The level of CoQ10 produced by the body begins to drop after the age of about 20, and the coenzyme is concentrated in the mitochondria – the ‘power plant’ of body cells. It plays a vital role in the production of chemical energy by participating in the production of adenosince triphosphate (ATP), the body’s so-called ‘energy currency’.

Beyond it’s participation with mitochondria CoQ10 acts as a potent antioxidant. The coenzyme plays an important role in preserving levels of vitamin E and vitamin C.

kendo athletic study

Michihiro Kon and co-workers recruited 18 elite Japanese kendo student athletes and randomly assigned them to receive daily supplements of CoQ10 (300 mg) or placebo for 20 days. The study was double-blind, meaning neither volunteers nor researchers knew who was receiving the active or placebo dose. The volunteers had daily training sessions of five and a half hours per day for six days during the intervention period. At day three and five of the six day training period, the researchers report that both groups experienced increased in serum creatine kinase activity and the concentration of myoglobin, but these increases were significantly lower in the group receiving the CoQ10 supplements.

Creatine kinase is an enzyme that catalyses the conversion of creatine to phosphocreatine, in the process consuming adenosine triphosphate (ATP) and generating adenosine diphosphate (ADP). Elevated levels of the enzyme are indicative of muscle damage and injury. Moreover, levels of lipid peroxide, a marker of oxidative stress, were also lower in the CoQ10 group after three and five days of training, said the researchers.

“These results indicate that CoQ10 supplementation reduced exercise-induced muscular injury in athletes”

Mechanism

The underlying mechanism appears to be due to the antioxidant potential of the coenzyme, suggest the researchers, although further research is necessary to confirm these findings.

Source: British Journal of Nutrition
“Reducing exercise-induced muscular injury in kendo athletes with supplementation of coenzyme Q10”
Authors: M. Kon, K. Tanabe, T. Akimoto, F. Kimura, Y. Tanimura, K. Shimizu, T. Okamoto, I. Kono

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Importance of Magnesium – Prevents Health Risks

nutrition, performance | Posted by admin November 6th, 2009

Most people are aware of the importance of getting enough calcium, which remains a widespread problem. Most people don’t know there are other common micronutrient deficiencies that need to be addressed. Magnesium is one of those important micronutrients that doesn’t seem to get much attention, but plays a huge role in the body promoting health & performance.

Unfortunately the diets of all Americans are likely to be deficient and they don’t even know it. Sources estimate that nearly 70 percent of Americans get inadequate doses of magnesium every day and do not consume the daily recommended amounts of Magnesium. Studies have also shown food alone can’t meet the minimal Recommended Daily Allowances (RDA) micronutrient requirements for preventing nutrient-deficiency diseases. For several years experts have suggested that the availability of magnesium in the soil has significantly decreased and it is difficult to get the amount of magnesium needed to function at an optimal level. This, in combination with diets low in whole grains and fresh fruits and vegetables, has led to a general deficiency in the population.

Magnesium is used for more than 300 bodily functions and assists in energy production, maintains healthy bone density and aids the electrical conduction of the heart. Magnesium belongs in a category of minerals called electrolytes because they conduct electrical signals in the body. It is needed in energy metabolism, glucose utilization, protein synthesis, fatty acid synthesis and breakdown, muscle contraction, all ATPase functions, for almost all hormonal reactions, and in the maintenance of cellular ionic balance. It is found in all of the body’s cells, although it is mostly concentrated in the bones, muscles, and soft tissues. Magnesium also affects calcium’s role in homeostasis through two mechanisms.

Magnesium deficiency results in altered cardiovascular function, including electrocardiographic abnormalities, impaired carbohydrate metabolism, with insulin resistance and decreased insulin secretion, and high blood pressure. Even a mild deficiency causes sensitiveness to noise, nervousness, irritability, mental depression, confusion, twitching, trembling, apprehension, insomnia, muscle weakness and cramps in the toes, feet, legs, or fingers.

In active adults and athletes low magnesium levels can acutely contribute to early fatigue, nausea, muscle cramps & an irregular heartbeat during exercise. Magnesium as well as zinc, chromium and selenium are excreted in the sweat or as part of the process of metabolic acceleration. Heavy sweat loss can interfere with the important functions for which magnesium and other electrolytes are responsible. Also, the rate of magnesium loss is increased in conditions of high humidity and high temperature. An important consideration for athletes is the rate of magnesium loss that occurs during heavy physical activity. Heavy exercise makes you lose magnesium in the urine and scientific evidence suggests this is why long distance runners may suddenly drop dead with heart arrhythmias.

In a very tightly controlled three-month US study carried out last year, the effects of magnesium depletion on exercise performance in 10 women were observed. In the first month, the women received a magnesium-deficient diet (112mgs per day), which was supplemented with 200mgs per day of magnesium to bring the total magnesium content up to the RDA of 310mgs per day. In the second month, the supplement was withdrawn to make the diet magnesium-deficient, but in the third month it was reintroduced to replenish magnesium levels.

At the end of each month, the women were asked to cycle at increasing intensities until they reached 80% of their maximum heart rate, at which time a large number of measurements were taken, including blood tests, ECG and respiratory gas analysis.

The researchers found that, for a given workload, peak oxygen uptake, total and cumulative net oxygen utilization and heart rate all increased significantly during the period of magnesium restriction, with the amount of the increase directly related to the extent of magnesium depletion. In plain English, a magnesium deficiency reduced metabolic efficiency, increasing the oxygen consumption and heart rate required to perform work – exactly what an athlete doesn’t want!

No serious athlete or trainer can afford to overlook the benefits that magnesium brings to athletic performance and the recovery process. Research suggests that even a small shortfall in magnesium can lead to greatly reduced performance and stamina. Many athletic medical specialists believe that magnesium is the single most important mineral to sports nutrition. Not only does it help optimize an athlete’s performance, but it speeds up recovery from fatigue and injuries.

Optimal muscle contraction and relaxation is the foundation of an athlete’s performance. Proper magnesium levels are required for muscles to relax fully following a contraction. Some doctors believe that injuries to hamstring muscles can be partially avoided through intake of magnesium and stated that a shortened hamstring is a result of lack of available magnesium.

The first step is to eat more magnesium rich foods, especially beans, nuts and vegetables. The more active a person is the greater the need to make sure there is a variety of balanced micronutrient-enriched foods into their diet. The challenge is to eat large amounts of magnesium-rich foods on a consistent basis. Often this proves difficult and unrealistic, as an athlete’s requirement of magnesium intake far surpasses that of an average person. Micronutrient supplementation still may be needed to be incorporated into their wellness program as a preventative protocol for preventing these observed deficiencies.

Another important step is to have your levels checked. The residual level of magnesium in the cells is what’s important. The body does all it can to keep the blood levels normal, so if there is a body deficit, it will be found within the cells. Work with a practitioner that will check your RBC-magnesium level (the level of magnesium in red blood cells) or provide an FIA (functional intracellular analysis) for your body’s residual nutrient levels that will benchmark your cell level status to find the amount of supplements needed to achieve normal levels. Recommended intake for endurance athletes is 500 to 800 mg daily.

There is virtually no one that cannot benefit greatly from increasing daily magnesium intake. In terms of health and longevity magnesium is essential. For the professional athlete it means the difference between winning and losing, and in some cases, living and dying.

GoTo: Prevention not Prescriptions

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Manipulating The Glycemic Index Diet – The Winning Edge ???

Fitness, nutrition, performance, Recovery - Repair, strength | Posted by admin November 4th, 2009

A high-carbohydrate training diet is a must for optimum sports performance because it produces the biggest stores of muscle glycogen. Unlike the fat stores in the body, which can release almost unlimited amounts of fatty acids, the carbohydrate stores are small. They are fully depleted after two or three hours of strenuous exercise. This depletion of carbohydrate stores is called “hitting the wall.” The blood glucose concentration begins to decline at this point. If exercise continues as the same rate, blood glucose may drop to levels that interfere with brain function and cause disorientation and unconsciousness.

All else being equal, the eventual winner is the person with the largest stores of muscle glycogen. It is important to maximize your muscle glycogen stores by ingesting a high-carbohydrate training diet and by carb loading in the days prior to the competition.

There are times when low G.I. foods provide an advantage and times when high G.I. are better. For best performance a serious athlete needs to learn which foods have high and low G.I. factors and when to eat them. Understanding the glycemic index and making the best food choices can give you an advantage.

Low-GI Foods: Before the Event
Low-GI foods have been proven to extend endurance when eaten alone one or two hours before prolonged strenuous exercise. Low-GI foods are best eaten about two hours before the big event –so that the meal will have left the stomach but will remain in the small intestine, slowly releasing glucose energy, for hours afterwards. The slow rate and steady stream of glucose trickles into the bloodstream during the event. Most importantly, the extra glucose will still be available toward the end of the exercise, when muscle stores are running close to empty. In this way, low-GI foods increase endurance and prolong the time before exhaustion hits.

When a pre-event meal of lentils (low GI value) was compared with one of potatoes (high GI value), cyclists were able to continue cycling at high intensity (65 percent of their maximum capacity) for twenty minutes longer when the meal had a low G value. Their blood-glucose and insulin levels were still above fasting levels at the end of exercise, indicating that carbohydrates were continuing to be absorbed from the small intestine even after ninety minutes of strenuous exercise.

In any sport context, it’s critical to select low-GI foods that do not cause gastrointestinal discomfort (stomach cramps, etc.). Some low-GI foods, such as legumes that are high in fiber or ingestible sugars, may produce symptoms in people not use to eating large amounts of them. There are plenty of low-fiber, low-GI choices, including pasta, noodles, and Basmati rice.

High- GI Foods: During and After the Event
While the pre-event meal should have a low GI value, scientific evidence indicates that there are times when high-GI foods are preferable. This includes during the event, after the event, and after normal training sessions. This is because high-GI foods are absorbed faster and stimulate more insulin, the hormone responsible for getting glucose back into the muscles for either immediate or future use.

During the event
High-GI foods should be used during events lasting longer than ninety minutes. This form of carbohydrate is rapidly released into the bloodstream and ensures that glucose is available for oxidation in the muscle cells. Liquid foods are usually tolerated better than solid foods, for endurance racing for example, because they are emptied more quickly from the stomach. Sports drinks are ideal during the race because they replace water and electrolytes as well. If you feel hungry for something solid during a race, try jelly beans (GI value of 80) or another form of high-glucose candy. Consume 30 to 60 grams of carbohydrate per hour during the event.

After the event (recovery)
In some competitive sports, athletes compete on consecutive days, and glycogen stores need to be at their maximum each time. Here it is important to restock the glycogen store in the muscles as quickly as possible after each day’s events. High-GI foods are best in this situation. Muscles are more sensitive to glucose in the bloodstream in the first hour after exercise, so a concerted effort should be made to get as many high-GI foods in as soon as possible.

Suggested foods include most of the sports drinks which replace water and electrolyte losses, or high-GI rice (e.g., jasmine), breads, and breakfast cereals such as cornflakes or rice krispies. Potatoes cooked without fat are good choice too but their high satiety means it is hard to eat lots of them.

Carbohydrate Loading For Training & Understanding
Why This Is Important…

It’s not just your pre- and post-event meals that influence your performance. Very active people need to eat much larger amounts of carbohydrates than inactive people. Consuming a high-carbohydrate diet every day will help you reach peak performance. When athletes fail to consume adequate carbohydrates each day, muscle and liver glycogen stores eventually become depleted. Dr. Ted Costill at the University of Texas showed that the gradual and chronic depletion of stored glycogen may decrease endurance and exercise performance. Intense workouts two to three times a day draw heavily on the athlete’s muscle glycogen stores. Athletes on low-carbohydrate diet will not perform their best because muscle stores of fuel are low.
If the diet provides inadequate amounts of carbohydrate, the reduction in muscle glycogen will be critical. An athlete training heavily should consume about 500 to 800 grams of carbohydrate a day (about two to three times normal) to help prevent carbohydrate depletion. Typically, American adults consume between 200 to 250 grams of carbohydrates each day.

Could a High-GI Diet Be Harmful to Athletes?

By virtue of their high activity levels, athletes have optimal insulin sensitivity. When they eat high-carbohydrate, high-GI foods, blood glucose and insulin levels rise far less in them than in the average person. This also provides the athlete with a bonus by not exposing their bodies to dangerous levels of blood glucose which produce disease in sedentary, insulin resistant individuals.

Adapted from the Book: The New Glucose Revolution
Written by: Jennie Brand-Miller, PhD
Thomas M.S. Wolever, MD PhD
Stephen Colagiuri, MD
Kaye Foster-Powell, M Nutr & Diet

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Glutathione – Athletes Competitive Edge ?

performance, Recovery - Repair | Posted by admin August 26th, 2009

What is Glutathione?

Glutathione simply put is the “Master Antioxidant” in your body. Increasing glutathione levels will naturally increase your energy, detoxify your body and strengthen your immune system.

Research has shown that individuals that have low glutathione levels are susceptible to chronic illness including heart conditions, cancers, diabetes, seizures disorders, Alzheimer’s disease, and Parkinson’s disease to name a few. Our glutathione levels begin to decline at the age of 20 and do so at a rate of 8%-12% per decade.

Anti-Aging

Aging is the accumulation of changes in an organism overtime. Oxidation damage is now recognized as being the key feature of much of the aging processes that our bodies endure. The key to living better is to resist age related deterioration due to oxidation. Recent studies have shown that glutathione play a key role in reducing the oxidation process (antioxidant) and protecting our bodies against free radicals. Supplements that increase glutathione, may be a way for us to protect our bodies against the aging process.

Sports Enhancement

Many world-class athletes are discovering the importance of glutathione, which when maintained, gives them the edge over the competition. Increased glutathione levels provides athletes with increased strength and endurance, decreased recovery time from injury, less pain and fatigue and possibly an increase in muscle-promoting activities.

Athletes use glutathione for sports performance and recovery from their strenuous workouts. Up until very recently there was not a efficient way to get glutathione into our bodies other than intravenous (IV).

During workouts, athletes generate free radicals which in turn lead to muscle fatigue and poorer performance. Glutathione neutralizes these radicals and allows our bodies to recover faster.

Sports

Should Glutathione be a part of our exercise routine?

Free radicals are produced during normal cellular metabolism and increase when we exercise. These free radicals react within the cells by a process called oxidation and can result in inflammation to accumulate with our bodies. Overtime this inflammation accumulates within the cell and decreases the function of the cell and eventually leads to cellular death unless we have a way of reversing the process. To fight this cellular destruction our body uses an antioxidant, and the “Master Antioxidant” in the body is Glutathione.

Several studies have confirmed the beneficial effects of glutathione in protecting our bodies tissues from free radicals and exercise induced stress. Increasing Glutathione can increase energy, decrease recovery time and provide our cells with the tools so that they can function at an optimal level.

Ref: asktheRN.com

Bioavailable glutathione supplement option link here:

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Resveratrol: A Key for High Performance: Health & Endurance . . .

Fitness, performance, Recovery - Repair | Posted by admin August 10th, 2009

A drug based on resveratrol, a phytonutrient found in red wine, may double exercise endurance, fight obesity and prolong life, according to a new study by French researchers.

Dr. Johan Auwerx and colleagues from the Institute of Genetics and Molecular and Cellular Biology in Illkirch, France, recently conducted an animal study to test the effects of high doses of resveratrol on exercise endurance in mice.

A typical laboratory mouse can run roughly one kilometer on a treadmill before it collapses from exhaustion. Auwerx supplemented a group of mice with up to 400 mg of resveratrol per kilo of body weight, and found that the mice were then able to run twice as far as the mice that were not supplemented. The resveratrol mice were also found to have energy-charged muscles and a lower heart rate, much like trained athletes.

Resveratrol makes you look like a trained athlete without the training, Auwerx said.

Auwerx believes that the results of his animal study published online in the journal Cell could be replicated in humans, based on the results of a Finnish study that analyzed the gene that is influenced by the resveratrol drug. Previous studies of mice have indicated that moderate-to-high doses of resveratrol can activate a genetic mechanism that protects against the degenerative diseases of aging, as well as prolong life span by up to 30 percent.

Auwerx believes resveratrol can help offset the negative health effects of high-fat diets which can lead to the onset of metabolic disorder and diabetes by increasing the number of mitochondria in the body’s muscle cells. Extra mitochondria, organelles that generate energy, were found to help mice burn more fat and remodel muscle fibers to more closely resemble those of trained athletes.

Though resveratrol is present in red wine and some other foods, the concentrations used in Auwerx’ study were much higher than could ever be obtained through red wine consumption.

More research on resveratrol is needed before possible drug therapies to combat obesity and diabetes-related disorders can be developed.

Ref: (NaturalNews)

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Genetics And Performance

performance | Posted by admin June 12th, 2009

Genetics shape us in many ways including our potential to excel in sports. Training, diet, and other factors play a large role in developing our potential, but our genes may also limit performance. You may have the genetic potential for being a champion athlete, but if you live a lifestyle of overeating and no exercise you are unlikely to achieve that potential. On the other hand, someone with limited genetic potential can find ways to compensate and become a solid performer.

Genetics have a large influence over strength, muscle size and muscle fiber composition (fast or slow twitch), anaerobic Threshold, lung capacity, flexibility, and, to some extent, endurance.

One major limitation for endurance athletes is cardiac capacity, or the heart’s ability to deliver enough oxygen (via the bloodstream) to the working skeletal muscles. This, too, is largely determined by genetics.

The other limitation for endurance athletes is the muscles’ ability to effectively use the oxygen and create ATP (adenosine triphosphate), the fuel that allows muscular contraction and movement. The efficiency of this process is measured by something called VO2 max (maximum volume of oxygen).

How Genetics Influence Response to Training
Your genes may also determine how your body responds to training, diet and other external factors.

Research on aerobic endurance shows that some people respond more to training than others. So even if you have a low genetic potential for endurance, you may respond well to training and develop your potential more completely than someone with genetic ‘talent’ who doesn’t respond to training.

Training also increases cardiac efficiency, but the extent of this increase may depend upon genetics. Genetically gifted athletes will have a much greater response to training and will have a large increase in the number of mitochondria in cells. (The mitochondria are organelles in cells that produce the ATP, so the more mitochondria a person has, and the more efficient they are.)

Other Factors That Affect Performance
Characteristics that genetics have less influence over include balance, agility, reaction time and accuracy.

Nutrition also affects performance. This is clear when even the most highly-trained and gifted athlete bonks during an event. Bonking is usually related to running out of glycogen. Athletes can avoid this either by ‘teaching’ the body to burn fat when glycogen stores decrease, or replenishing the body with nutrition during an event.

Mental Skills Training
Practicing mental skills training (including good judgment, learning the tactics and strategies of your sport, and using the right equipment) is another critical component of success that has nothing to do with genetics.

While it is more likely that elite athletes are blessed with great genetics and a great training routine, even recreational athletes can make the most of their ability through optimal conditioning, good nutrition and a positive mental attitude.

By Elizabeth Quinn, at About.com: Sports Medicine

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Sports Nutrition: Critical to Athletic Success

nutrition | Posted by admin May 18th, 2009

All athletes strive to compete at the top of their game but, unbeknownst to many of them, their performance relies on their nutritional status. Young athletes with inadequate diets may have insufficient fuel for workouts, nutrient deficiencies that can lead to illness or fatigue, a decrement in bone growth and maintenance, and may not reach their potential for muscle growth. All of these will be reflected in their performance, regardless of their determination.

Despite the recognition that young athletes need to pay greater attention to their fuel consumption, recent research suggests that many youths struggle with energy balance, experiencing an energy deficit or surplus. We are all too familiar with this energy surplus, known as overweight or obesity, but that crisis is not the focus of this article. The concern is that many young athletes require greater amounts of nutrients but remain uninformed or unconcerned about their nutrition needs or simply feel powerless to improve their nutritional status. Young athletes need help to overcome these problems.

The number of young athletes in the United States is increasing and estimates are that approximately 30 to 45 million youths aged 6 to 18 participate in some form of athletics. These young athletes turn to coaches, parents, teammates, and health professionals for nutrition guidance. They can guide athletes to be leaner, stronger, and able to withstand the rigors of training and competition. They can offer superior advice because they are more cognizant of research findings and are equipped with clinical and counseling skills to aid in a young athlete’s quest for improvement. By helping athletes improve their diet, they can eliminate obstacles to better health and nutrition and thereby help athletes push their limits and reach their full potential.

Nutrition professionals can aid young athletes in their quest for victory by recognizing that children and adolescents generally need more calories and protein per pound of body weight than many adults. It is a well-known fact that children need this extra energy to grow, fully develop, and thrive. Nutrient needs further elevate and reach their peak during adolescence. Potential differences in nutrition needs between a typical child or adolescent and an athletic child or adolescent likely exist but are not entirely clear. Limited studies of energy balance in young athletes have been published, and conservative recommendations have been made. But self-reported diet records of young athletes often indicate that intake of energy, carbohydrate, and select micronutrients may be below recommended levels. They must be aware that these deficiencies exist and are especially apparent in athletes involved in sports that focus on body composition and appearance.

Residual nutritional levels of micronutrients can now be baseline measured by new scientific based technology.

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