Archive for the ‘Supplements’ Category

Researchers at The University of Auckland have shown for the first time that the mere presence of carbohydrate solution in the mouth immediately boosts muscle strength, even before it is swallowed.

The results suggest that a previously unknown neural pathway is activated when receptors in the mouth detect carbohydrate, stimulating parts of the brain that control muscle activity and producing an increase in muscle strength.

Previous research had shown that the presence of carbohydrate in the mouth can improve physical performance during prolonged activity, but the mechanism involved was not known and it was unclear whether a person must be fatigued for the effect to be seen.

“There appears to be a pathway in the brain that tells our muscles when energy is on the way,” says lead researcher Dr Nicholas Gant from the Department of Sport and Exercise Science.

“We have shown that carbohydrate in the mouth produces an immediate increase in neural drive to both fresh and fatigued muscle and that the size of the effect is unrelated to the amount of glucose in the blood or the extent of fatigue.”

The current research has been published in the journal Brain Research and has also captured the attention of New Scientist magazine.

In the first of two experiments, 16 healthy young men who had been doing biceps exercises for 11 minutes were given a carbohydrate solution to drink or an identically flavored energy-free placebo. Their biceps strength was measured before and immediately afterward, as was the activity of the brain pathway known to supply the biceps.

Around one second after swallowing the drink, neural activity increased by 30 percent and muscle strength two percent, with the effect lasting for around three minutes. The response was not related to the amount of glucose in the bloodstream or how fatigued the participants were.

“It might not sound like much, but a two percent increase in muscle strength is enormous, especially at the elite level. It’s the difference between winning an Olympic medal or not,” says co-author Dr Cathy Stinear.

As might be expected, a second boost in muscle strength was observed after 10 minutes when carbohydrate reached the bloodstream and muscles through digestion, but no additional boost in neural activity was seen at that time.

“Two quite distinct mechanisms are involved,” says Dr Stinear. “The first is the signal from the mouth via the brain that energy is about to be available and the second is when the carbohydrate actually reaches the muscles and provides that energy,” says Dr Stinear.

“The carbohydrate and placebo solutions used in the experiment were of identical flavor and sweetness, confirming that receptors in the mouth can process other sensory information aside from the basic taste qualities of food. The results suggest that detecting energy may be a sixth taste sense in humans,” says Dr Gant.

In the second experiment, 17 participants who had not been doing exercise and were not fatigued simply held one of the solutions in their mouths without swallowing. Measurements of the muscle between the thumb and index finger were taken while the muscle was either relaxed or active.

A similar, though smaller effect was observed as in the first experiment, with a nine percent increase in neural activity produced by the carbohydrate solution compared with placebo. This showed that the response is seen in both large powerful muscles and in smaller muscles responsible for fine hand movements.

“Together the results show that carbohydrate in the mouth activates the neural pathway whether or not muscles are fatigued. We were surprised by this, because we had expected that the response would be part of the brain’s sophisticated system for monitoring energy levels during exercise,” says Dr Stinear.

“Seeing the same effect in fresh muscle suggests that it’s more of a simple reflex – part of our basic wiring – and it appears that very ancient parts of the brain such as the brainstem are involved. Reflexive movements in response to touch, vision and hearing are well known but this is the first time that a reflex linking taste and muscle activity has been described,” she says.

Further research is required to determine the precise mechanisms involved and to learn more about the size of the effect on fresh versus fatigued muscle.

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Article adapted by MD Sports from original press release.
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Contact: Pauline Curtis
The University of Auckland

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Cereal and non-fat milk is as good as a commercially-available sports drink in initiating post-exercise muscle recovery.

Background

This study compared the effects of ingesting cereal and nonfat milk (Cereal) and a carbohydrate-electrolyte sports drink (Drink) immediately following endurance exercise on muscle glycogen synthesis and the phosphorylation state of proteins controlling protein synthesis: Akt, mTOR, rpS6 and eIF4E.

Methods

Trained cyclists or triathletes (8 male: 28.0+/-1.6 yrs, 1.8+/-0.0 m, 75.4+/-3.2 kg, 61.0+/-1.6 ml O2 * kg-1 * min-1; 4 female: 25.3+/-1.7 yrs, 1.7+/-0.0 m, 66.9+/-4.6 kg, 46.4+/-1.2 mlO2 * kg-1 * min-1) completed two randomly-ordered trials serving as their own controls. After 2 hours of cycling at 60-65% VO2MAX, a biopsy from the vastus lateralis was obtained (Post0), then subjects consumed either Drink (78.5 g carbohydrate) or Cereal (77 g carbohydrate, 19.5 g protein and 2.7 g fat). Blood was drawn before and at the end of exercise, and at 15, 30 and 60 minutes after treatment. A second biopsy was taken 60 minutes after supplementation (Post60). Differences within and between treatments were tested using repeated measures ANOVA.

Results

At Post60, blood glucose was similar between treatments (Drink 6.1+/-0.3, Cereal 5.6+/-0.2 mmol/L, p<.05), but after Cereal, plasma insulin was significantly higher (Drink 123.1+/-11.8, Cereal 191.0+/-12.3 pmol/L, p<.05), and plasma lactate significantly lower (Drink 1.4+/-0.1, Cereal 1.00+/-0.1 mmol/L, p<.05). Except for higher phosphorylation of mTOR after Cereal, glycogen and muscle proteins were not statistically different between treatments. Significant Post0 to Post60 changes occurred in glycogen (Drink 52.4+/-7.0 to 58.6+/-6.9, Cereal 58.7+/-9.6 to 66.0+/-10.0 mumol/g, p<.05) and rpS6 (Drink 17.9+/-2.5 to 35.2+/-4.9, Cereal 18.6+/-2.2 to 35.4+/-4.4 %Std, p<.05) for each treatment, but only Cereal significantly affected glycogen synthase (Drink 66.6+/-6.9 to 64.9+/-6.9, Cereal 61.1+/-8.0 to 54.2+/-7.2%Std, p<.05), Akt (Drink 57.9+/-3.2 to 55.7+/-3.1, Cereal 53.2+/-4.1 to 60.5+/-3.7 %Std, p<.05) and mTOR (Drink 28.7+/-4.4 to 35.4+/-4.5, Cereal 23.0+/-3.1 to 42.2+/-2.5 %Std, p<.05). eIF4E was unchanged after both treatments.

Conclusion

These results suggest that Cereal is as good as a commercially-available sports drink in initiating post-exercise muscle recovery.

Author: Lynne Kammer, Zhenping Ding, Bei Wang, Daiske Hara, Yi-Hung Liao and John L. Ivy

Credits/Source: Journal of the International Society of Sports Nutrition 2009, 6:11

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Research News

Bethesda, MD – A visit to the meat counter at any supermarket is proof positive that a good number of Americans are avoiding carbohydrates and consuming high levels of protein and fat, in accordance with the Atkins diet. This carbohydrate-free, fat- and protein- rich diet is for those seeking immediate weight loss, which means most of us.But what do others, such as weight lifters and callisthenic enthusiasts, do about carbohydrates? Their goal is muscle preservation and strengthening, but for years, different theories have been offered about the effectiveness of carbohydrates in maintaining an appropriate muscle protein balance. A new study may lead to a truce in the debate at the nation’s gymnasiums, and those dedicated to resistance training may finally have an answer as to whether carbohydrates have a positive role in muscle development.

Background

Resistance exercise — also called strength training — increases muscle strength and mass, bone strength, and the body’s metabolism. The different methods for resistance training include free weights, weight machines, calisthenics and resistance tubing. When using free weights, dumbbells, and bars stacked with weight plates, you are responsible for both lifting the weight and determining and controlling your body position through the range of motion.

The body’s net muscle protein balance (i.e., the difference between muscle protein synthesis and protein breakdown) generally remains negative in the recovery period after resistance exercise in the absence of nutrient intake, i.e., the muscle’s protein is breaking down complex chemical compounds to simpler ones. However, it has been demonstrated that infusion or ingestion of amino acids after resistance exercise stimulates muscle protein synthesis. Furthermore, as little as six grams of essential amino acids (EAA) alone effectively stimulates net protein synthesis after a strenuous resistance exercise session.

The body’s response to the six grams of EAA does not appear to differ when 35 grams of carbohydrates are added. This reflects the uncertainty of the independent effects of carbohydrates on muscle protein metabolism after resistance exercise. Additionally, it is unclear how carbohydrate intake causes changes of net protein balance between synthesis and breakdown and how it relates to changes in plasma insulin concentration.

Interpretation of the response of muscle protein to insulin is complicated by the fact that a systemic increase in insulin concentration causes a fall in plasma amino acid concentrations, and this reduced amino acid availability could potentially counteract a direct effect of insulin on synthesis. A past study found that the normal postexercise increase in muscle protein breakdown was slowed by insulin, thus improving net muscle protein balance. However, whereas local infusion of insulin may effectively isolate the effect of insulin per se, the response may differ from when insulin release is stimulated by ingestion of carbohydrates.

A New Study

Accordingly, a new study set out to investigate the independent effect of carbohydrate intake on muscle protein net balance during recovery from resistance exercise. The authors of “Effect Of Carbohydrate Intake on Net Muscle Protein Synthesis During Recovery from Resistance Exercise,” are Elisabet Børsheim, Melanie G. Cree, Kevin D. Tipton, Tabatha A. Elliott, Asle Aarsland, and Robert R. Wolfe, all from the Department of Surgery, Metabolism Unit, Shriners Hospitals for Children-Galveston, University of Texas Medical Branch, Galveston, TX. Their findings appeared in the February 2004 edition of the Journal of Applied Physiology. The journal is one of 14 peer-reviewed scientific journals published each month by the American Physiological Society (www.APS.org).

Methodology

Sixteen recreationally active and healthy subjects took part in the study. At least one week before an experiment, subjects were familiarized with the exercise protocol, and their one repetition maximum, a maximum weight possible with a leg extension, was determined. The subjects were assigned to one of two groups: carbohydrate group (CHO; n = 8) or placebo group (n = 8). Subjects were instructed not to exercise for at least 48 hours before an experiment, not to use tobacco or alcohol during the 24 h before an experiment, and not to make any changes in their dietary habits.

The two groups of eight subjects performed a resistance exercise bout (10 sets of eight repetitions of leg presses at 80 percent of one repetition maximum) before they rested in bed for four hours. One group (CHO) received a drink consisting of 100 grams of carbohydrates one hour after exercise; the placebo group received a noncaloric placebo drink. Leg amino acid metabolism was determined by infusion of 2H5- or 13C6-labeled phenylalanine, sampling from femoral artery and vein, and muscle biopsies from vastus lateralis, the lateral head of quadriceps muscle of anterior (extensor) compartment of thigh.

Results

Key findings of the study included: 

  • Plasma glucose concentration was significantly increased in the carbohydrate group until 210 min after intake of drink. 
  • Plasma concentration of insulin reflected the changes in glucose concentration. The drink intake did not affect arterial insulin concentration in the placebo group, whereas arterial insulin increased by several times after the drink in the CHO group. 
  • Arterial phenylalanine (a common amino acid in proteins) concentration did not change after intake of drink in the placebo group but decreased and stabilized in the CHO group. 
  • Net muscle protein balance between synthesis and breakdown did not change in the placebo group but improved in the CHO group during the second and third hour after the drink. The improved net balance in the CHO group was due primarily to a progressive decrease in muscle protein breakdown.

Conclusions

This study is the first to compare net muscle protein balance (protein synthesis minus breakdown) after carbohydrate ingestion with control after exercise. The principal finding was that intake of 100 grams of carbohydrates after resistance exercise improved muscle net protein balance.

The findings from this research demonstrate that carbohydrates intake alone can improve net protein balance between synthesis and breakdown. In this work, the gradual improvement in net muscle protein balance after carbohydrate intake was due principally to a progressive reduction in breakdown. However, the improvement was small compared with previous findings after intake of amino acids or amino acids and carbohydrates.

The researchers conclude that intake of carbohydrates alone after resistance exercise will modestly improve the anabolic effect of exercise. However, amino acid intake is necessary for a maximal response, one desired by most participating in resistance exercise programs.

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Article adapted by Sports Performance Research from original press release.

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Contact: Donna Krupa

American Physiological Society 

Source: Journal of Applied Physiology. The journal is one of 14 peer-reviewed scientific journals published each month by the American Physiological Society (www.APS.org).

The American Physiological Society (APS) was founded in 1887 to foster basic and applied science, much of it relating to human health. The Bethesda, MD-based Society has more than 10,000 members and publishes 3,800 articles in its 14 peer-reviewed journals every year.

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It’s fewer calories not Carbs or fluid loss responsible for weight loss.

PHILADELPHIA —  A new three-week in-hospital study of 10 volunteers found that during the two-week period on a strictly controlled very-low carbohydrate diet, participants lost an average of 3.6 pounds, voluntarily reduced their calorie intake from 3,111 calories per day to 2,164 calories per day, and did not eat more of the readily available fat and protein to make up for the lost carbohydrate calories.The study, “Effect of a Low-Carbohydrate Diet on Appetite, Blood Glucose Levels, and Insulin Resistance in Obese Patients with Type 2 Diabetes,” compared a very low-carbohydrate diet with a regular diet. It is published in the March 15, 2005, issue of Annals of Internal Medicine and is the subject of a video news release.

During the first study week, participants, who were obese and had mild type 2 diabetes mellitus, ate a regular diet in which they could eat anything and as much as they wanted. They ate about 3,000 calories and 300 grams of carbohydrates per day and remained at entry weight.

In the following two weeks, when restricted to 20 grams of carbohydrates per day, as specified in the Atkins induction diet, and despite readily available protein and fat foods, the participants voluntarily ate about 1,000 fewer calories per day, a calorie intake considered appropriate to their height.

Participants’ blood sugar improved on the low-carb diet, with better insulin sensitivity and lower blood triglycerides and cholesterol levels.

“We proved that people lose weight on the Atkins diet because they eat less (consume fewer calories), not because they get bored with the diet or lose body water or because the carbohydrate calories are treated differently by the body than fat or protein calories,” said Guenther Boden, MD, a Laura H. Carnell Professor of Medicine and chief of the division of endocrinology/diabetes/metabolism at Temple University School of Medicine.

“All the weight loss was in fat,” said Boden, the lead study author. “We weighed and measured every calorie that participants ate and every calorie they spent. We knew what went in and what went out.”

“On the very low-fat diet, participants spontaneously reduced their calories by about 1,000 per day. One gram of fat equals 9 calories, so, doing the math, you can determine how much fat will be lost by cutting 1,000 calories.”

Boden also believes that the carbohydrates actually stimulated the patients’ big appetites during the regular-diet week.

“Participants went from an excessive caloric intake to a normal caloric intake for their height and weight when we reduced their carbohydrates. This indicates to me that it was the carbohydrates that stimulated the excessive appetite,” Boden said.

Throughout the three-week study, researchers weighed all food, monitored exercise, measured participants’ calorie energy intake, expenditure and body water composition, and tested blood sugar, cholesterol, and several hormone levels believed to be involved in appetite regulation.

“You don’t have to cut carbs as drastically as participants did,” said Boden. “If you cut carbs modestly, you cut calories, and you’ll lose weight.”

“The message is: Calories count,” Boden said. “If you want to lose weight, you have to decrease your food intake or increase your physical activity. It helps to know that carbohydrates make it more difficult to reduce food intake. So cutting the carbohydrates, at least to some extent, will help keep down the caloric intake. With fewer carbohydrates, you’re going to eat fewer total calories a day.”

George A. Bray, MD, Chief, Division of Clinical Obesity and Metabolism at the Pennington Biomedical Research Center in Baton Rouge, La., and a well-known researcher in obesity and diabetes, wrote an accompanying editorial, “Is There Something Special about Low-Carbohydrate Diets?”

Bray notes that the study is small but calls it “a nicely done, short-term metabolic ward study.” He says that using “many different diets with different approaches to food restriction for individual patients at different times in their efforts to lose weight may be the most effective way a clinician can use the available diets. … (I) am not yet convinced that one diet has any more value than another — they all have value.”

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Article adapted by MD Sports from original press release.
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Contact: Susan Anderson
American College of Physicians

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Research News

 In many HIV-infected individuals with prior weight loss, the failure to regain weight and lean tissue is at least in part the consequence of inadequate protein intake or ingestion of a poor-quality protein rather than total caloric intake. Dietary sources of protein are presumably inadequate to meet the high metabolic needs caused by HIV infection. To achieve a target protein intake in the range (1.5 to 2.0 g/kg/day) demonstrated in other catabolic diseases necessary to achieve positive nitrogen balance and to generate substantial anabolic effects.

A high-quality protein food supplement may help HIV-positive patients maintain, and possibly gain, muscle mass. Many HIV-positive patients lose weight that they are then unable to regain. This may be because patients are not eating enough protein or are not eating the right kinds of protein. The protein eaten in foods (such as meat, eggs, or beans) may not be able to make up for the amount of protein lost due to HIV infection.

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Research News

Negative Energy Balance

By Sandco Staff

University Park, Pa. – Female athletes often lose their menstrual cycle when training strenuously, but researchers have long speculated on whether this infertility was due to low body fat, low weight or exercise itself. Now, researchers have shown that the cause of athletic amenorrhea is more likely a negative energy balance caused by increasing exercise without increasing food intake.

“A growing proportion of women are susceptible to losing their menstrual cycle when exercising strenuously,” says Dr. Nancy I. Williams, assistant professor of kineseology and physiology at Penn State. “If women go six to 12 months without having a menstrual cycle, they could show bone loss. Bone densities in some long distance runners who have gone for a prolonged time period without having normal menstrual cycles can be very low.”

In studies done with monkeys, which show menstrual cyclicity much like women, researchers showed that low energy availability associated with strenuous exercise training plays an important role in causing exercise-induced amenorrhea. These researchers, working at the University of Pittsburgh, published findings in the Journal of Clinical Endocrinology and Metabolism showing that exercise-induced amenorrhea was reversible in the monkeys by increasing food intake while the monkeys still exercised.

Williams worked with Judy L. Cameron, associate professor of psychiatry and cell biology and physiology at the University of Pittsburgh. Dana L. Helmreich and David B. Parfitt, then graduate students, and Anne Caston-Balderrama, at that time a post-doctoral fellow at the University of Pittsburgh, were also part of the research team. The researchers decided to look at an animal model to understand the causes of exercise-induced amenorrhea because it is difficult to closely control factors, such as eating habits and exercise, when studying humans. They chose cynomolgus monkeys because, like humans, they have a menstrual cycle of 28 days, ovulate in mid-cycle and show monthly periods of menses.

“It is difficult to obtain rigorous control in human studies, short of locking people up,” says Williams.

Previous cross-sectional studies and short-term studies in humans had shown a correlation between changes in energy availability and changes in the menstrual cycle, but those studies were not definitive.

There was also some indication that metabolic states experienced by strenuously exercising women were similar to those in chronically calorie restricted people. However, whether the increased energy utilization which occurs with exercise or some other effect of exercise caused exercise-induced reproductive dysfunction was unknown.

“The idea that exercise or something about exercise is harmful to females was not definitively ruled out,” says Williams. “That exercise itself is harmful would be a dangerous message to put out there. We needed to look at what it was about exercise that caused amenorrhea, what it was that suppresses ovulation. To do that, we needed a carefully controlled study.”

After the researchers monitored normal menstrual cycles in eight monkeys for a few months, they trained the monkeys to run on treadmills, slowly increasing their daily training schedule to about six miles per day. Throughout the training period the amount of food provided remained the standard amount for a normal 4.5 to 7.5 pound monkey, although the researchers note that some monkeys did not finish all of their food all of the time.

The researchers found that during the study “there were no significant changes in body weight or caloric intake over the course of training and the development of amenorrhea.” While body weight did not change, there were indications of an adaptation in energy expenditure. That is, the monkeys’ metabolic hormones also changed, with a 20 percent drop in circulating thyroid hormone, suggesting that the suppression of ovulation is more closely related to negative energy balance than to a decrease in body weight.

To seal the conclusion that a negative energy balance was the key to exercise-induced amenorrhea, the researchers took four of the previous eight monkeys and, while keeping them on the same exercise program, provided them with more food than they were used to. All the monkeys eventually resumed normal menstrual cycles. However, those monkeys who increased their food consumption most rapidly and consumed the most additional food, resumed ovulation within as little as 12 to 16 days while those who increased their caloric intake more slowly, took almost two months to resume ovulation.

Williams is now conducting studies on women who agree to exercise and eat according to a prescribed regimen for four to six months. She is concerned because recreational exercisers have the first signs of ovulatory suppression and may easily be thrust into amenorrhea if energy availability declines. Many women that exercise also restrict their calories, consciously or unconsciously.

“Our goal is to test whether practical guidelines can be developed regarding the optimal balance between calories of food taken in and calories expended through exercise in order to maintain ovulation and regular menstrual cycles,” says Williams. “This would then ensure that estrogen levels were also maintained at healthy levels. This is important because estrogen is a key hormone in the body for many physiological systems, influencing bone strength and cardiovascular health, not just reproduction.”

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Article adapted by MD Sports from original press release.
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Contact: A’ndrea Elyse Messer
Penn State

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Research News

Nitrogen Balance

By Sandco Staff

The sensitivity of Nitrogen balance to changes in energy intake has been demonstrated in numerous studies. It is well known that when diet provides adequate amounts of protein the addition of energy-yielding nutrients (either carbohydrate or fat) results in a linear improvement in N balance in humans and animals (Munro, 1951, 1964, 1978; Inoue et al. 1973; Garza et al. 1976; Reeds et al. 1981). However, the underlying biochemical mechanism whereby energy intake above requirements affects N metabolism in long-term studies remains obscure.

 

References:

Munro, H. N. (1951). Carbohydrate and fat as factors in protein utilization and metabolism. Physiological Reviews 31, 449488.
Munro, H. N. (1964). General aspects of the regulation of protein metabolism by diet and by hormones. In Mammalian Protein Metabolism, vol. 1, pp. 381481 [H. N. Munro and J. B. Allison, editors]. New York:
Academic Press.
Munro, H. N. (1978). Energy and protein intakes as determinants of nitrogen balance. Kidney International 14, 313-316.
Inoue, G., Fujita, Y. & Niiyama, Y. (1973). Studies on protein requirements of young men fed egg protein and rice protein with excess and maintenance energy intakes. Journal of Nutrition 103, 1673-1687.
   

Garza, C., Scrimshaw, N. S. & Young, V. R. (1976). Human protein requirements: the effect of variations in energy intake within the maintenance range. American Journal of Clinical Nutrition 29, 28G287
Reeds, P. J., Fuller, M. F., Cadenhead, A,, Lobley, G. E. & McDonald, J. D. (1981). Effects of changes in the intakes of protein and non-protein energy on whole-body protein turnover in growing pigs. British Journal of Nutrition 45, 539-546.