Archive for the ‘Male Athlete’ Category

Duke University Medical Center researchers have identified the skeletal muscle changes that occur in response to endurance exercise and have better defined the role of vascular endothelial growth factor (VEGF) in creating new blood vessels, known as angiogenesis, in the process.

VEGF is a protein known to trigger blood vessel growth by activating numerous genes involved in angiogenesis.
The researchers’ new insights could provide a roadmap for medical investigators as they seek to use VEGF in treating human conditions characterized by lack of adequate blood flow, such as coronary artery disease or peripheral arterial disease.
Using mice as animal models, the researchers found that exercise initially stimulates the production of VEGF, which then leads to an increase in the number of capillaries within a specific muscle fiber type, ultimately leading to an anaerobic to aerobic change in the muscle fibers supplied by those vessels. The VEGF gene produces a protein that is known to trigger blood vessel growth.
The results of the Duke experiments were presented by cardiologist Richard Waters, M.D., Nov. 8, 2004, at the American Heart Association’s annual scientific sessions in New Orleans.
“It is known that exercise can improve the symptoms of peripheral arterial disease in humans and it has been assumed that angiogenesis played a role in this improvement,” Waters said. “However, the clinical angiogenesis trials to date utilizing VEGF have been marginally successful and largely disappointing, so we felt it would be better at this point to return to animal studies in an attempt to better understand the angiogenic process.”
The Duke team performed their experiments using a mouse model of voluntary exercise. This experimental approach is important, they explained, because most skeletal muscle adaptation studies utilize electrical stimulation of the muscle, which is much less physiologic and does not as closely mimic what would be expected in human exercise.
When placed in the dark with a running wheel, mice will instinctively run, the researchers said. In the Duke experiments, 41 out of 42 mice “ran” up to seven miles each night. At regular intervals over a 28-day period, the researchers then performed detailed analysis of capillary growth and the subsequent changes in muscle fiber type and compared these findings to sedentary mice.
Mammalian muscle is generally made up of two different fiber types – slow-twitch fibers requiring oxygen to function, and the fast-twitch fibers, which function in the absence of oxygen by breaking down glucose. Because of their need for oxygen, slow-twitch fibers tend to have a higher density of capillaries.
“Exercise training is probably the most widely utilized physiological stimulus for skeletal muscle, but the mechanisms underlying the adaptations muscle fibers make in response to exercise is not well understood,” Waters said. “What we have shown in our model is that increases in the capillary density occur before a significant change from fast-twitch to slow-twitch fiber type, and furthermore, that changes in levels of the VEGF protein occur before the increased capillary density.”
“Interestingly, capillary growth appears to occur preferentially among fast-twitch fibers, and it is these very fibers that likely change to slow-twitch fibers,” Waters said. “Since exercise has the potential to impact an enormous number of clinical conditions, therapeutic manipulations intended to alter the response to exercise would benefit from a more detailed understanding of what actually happens to muscle as a result of exercise.”
The exact relationship between VEGF, exercise induced angiogenesis, and muscle fiber type adaptation is still not clear and will become the focus of the group’s continuing research. The findings from the current study, however, are providing important temporal and spatial clues to the adaptability process.
“Our data suggests that angiogenesis is one of the key early steps in skeletal muscle adaptation and may be an essential step in the adaptability process,” Waters continued. “This understanding could be crucial for designing new studies that can be performed to inhibit the angiogenic response to exercise in order to directly test the links between angiogenesis and skeletal muscle plasticity.”
###
The research team was supported by grants from the American Heart Association and the U.S. Department of Veterans Affairs.
Other members of the Duke team were Ping Li, Brian Annex, M.D., and Zhen Yan, Ph.D. Svein Rotevatn, Haukeland University Hospital, Bergen, Norway, was also a member of the team.

Duke University Medical Center researchers have identified the skeletal muscle changes that occur in response to endurance exercise and have better defined the role of vascular endothelial growth factor (VEGF) in creating new blood vessels, known as angiogenesis, in the process.

VEGF is a protein known to trigger blood vessel growth by activating numerous genes involved in angiogenesis.

The researchers’ new insights could provide a roadmap for medical investigators as they seek to use VEGF in treating human conditions characterized by lack of adequate blood flow, such as coronary artery disease or peripheral arterial disease.

Using mice as animal models, the researchers found that exercise initially stimulates the production of VEGF, which then leads to an increase in the number of capillaries within a specific muscle fiber type, ultimately leading to an anaerobic to aerobic change in the muscle fibers supplied by those vessels. The VEGF gene produces a protein that is known to trigger blood vessel growth.

The results of the Duke experiments were presented by cardiologist Richard Waters, M.D., Nov. 8, 2004, at the American Heart Association’s annual scientific sessions in New Orleans.

“It is known that exercise can improve the symptoms of peripheral arterial disease in humans and it has been assumed that angiogenesis played a role in this improvement,” Waters said. “However, the clinical angiogenesis trials to date utilizing VEGF have been marginally successful and largely disappointing, so we felt it would be better at this point to return to animal studies in an attempt to better understand the angiogenic process.”

The Duke team performed their experiments using a mouse model of voluntary exercise. This experimental approach is important, they explained, because most skeletal muscle adaptation studies utilize electrical stimulation of the muscle, which is much less physiologic and does not as closely mimic what would be expected in human exercise.

When placed in the dark with a running wheel, mice will instinctively run, the researchers said. In the Duke experiments, 41 out of 42 mice “ran” up to seven miles each night. At regular intervals over a 28-day period, the researchers then performed detailed analysis of capillary growth and the subsequent changes in muscle fiber type and compared these findings to sedentary mice.

Mammalian muscle is generally made up of two different fiber types – slow-twitch fibers requiring oxygen to function, and the fast-twitch fibers, which function in the absence of oxygen by breaking down glucose. Because of their need for oxygen, slow-twitch fibers tend to have a higher density of capillaries.

“Exercise training is probably the most widely utilized physiological stimulus for skeletal muscle, but the mechanisms underlying the adaptations muscle fibers make in response to exercise is not well understood,” Waters said. “What we have shown in our model is that increases in the capillary density occur before a significant change from fast-twitch to slow-twitch fiber type, and furthermore, that changes in levels of the VEGF protein occur before the increased capillary density.”

“Interestingly, capillary growth appears to occur preferentially among fast-twitch fibers, and it is these very fibers that likely change to slow-twitch fibers,” Waters said. “Since exercise has the potential to impact an enormous number of clinical conditions, therapeutic manipulations intended to alter the response to exercise would benefit from a more detailed understanding of what actually happens to muscle as a result of exercise.”

The exact relationship between VEGF, exercise induced angiogenesis, and muscle fiber type adaptation is still not clear and will become the focus of the group’s continuing research. The findings from the current study, however, are providing important temporal and spatial clues to the adaptability process.

“Our data suggests that angiogenesis is one of the key early steps in skeletal muscle adaptation and may be an essential step in the adaptability process,” Waters continued. “This understanding could be crucial for designing new studies that can be performed to inhibit the angiogenic response to exercise in order to directly test the links between angiogenesis and skeletal muscle plasticity.”

 

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Article adapted by MD Sports from original press release.
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Contact: Richard Merritt
Duke University Medical Center 

The research team was supported by grants from the American Heart Association and the U.S. Department of Veterans Affairs

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WESTCHESTER, Ill. – Athletes who get an extra amount of sleep are more likely to improve their performance in a game, according to a research abstract presented at the 21st Annual Meeting of the Associated Professional Sleep Societies (APSS).

The study, authored by Cheri Mah of Stanford University, was conducted on six healthy students on the Stanford men’s basketball team, who maintained their typical sleep-wake patterns for a two-week baseline followed by an extended sleep period in which they obtained as much extra sleep as possible. To assess improvements in athletic performance, the students were judged based on their sprint time and shooting percentages.

Significant improvements in athletic performance were observed, including faster sprint time and increased free-throws. Athletes also reported increased energy and improved mood during practices and games, as well as a decreased level of fatigue.

“Although much research has established the detrimental effects of sleep deprivation on cognitive function, mood and performance, relatively little research has investigated the effects of extra sleep over multiple nights on these variables, and even less on the specific relationship between extra sleep and athletic performance. This study illuminated this latter relationship and showed that obtaining extra sleep was associated with improvements in indicators of athletic performance and mood among members of the men’s basketball team.”

The amount of sleep a person gets affects his or her physical health, emotional well-being, mental abilities, productivity and performance. Recent studies associate lack of sleep with serious health problems such as an increased risk of depression, obesity, cardiovascular disease and diabetes.
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Article adapted by MD Sports from original press release.
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Contact: Jim Arcuri
American Academy of Sleep Medicine 

Experts recommend that adults get between seven and eight hours of sleep each night to maintain good health and optimum performance.

Persons who think they might be suffering from a sleep disorder are encouraged to consult with their primary care physician, who will refer them to a sleep specialist.

The annual SLEEP meeting brings together an international body of 5,000 leading researchers and clinicians in the field of sleep medicine to present and discuss new findings and medical developments related to sleep and sleep disorders.

More than 1,000 research abstracts will be presented at the SLEEP meeting, a joint venture of the American Academy of Sleep Medicine and the Sleep Research Society. The four-day scientific meeting will bring to light new findings that enhance the understanding of the processes of sleep and aid the diagnosis and treatment of sleep disorders such as insomnia, narcolepsy and sleep apnea.

ATHENS, Ohio – Men over 60 may be able to increase their strength by as much as 80 percent by performing intense weight training exercises, according to physiologists involved in studies of the health benefits of weight lifting. The researchers also have found that older men gain strength at the same rate as men in their 20s.

In a study of 18 men ages 60 to 75, Ohio University physiologists found that subjects who participated in a 16-week, high-intensity resistence training program on average were 50 percent to 80 percent stronger by the end of the study. None of the participants had engaged in weight lifting prior to the study. Researchers also observed improvements in the seniors’ muscle tone, aerobic capacity and cholesterol profile.

These are some of the latest findings from a decades-long examination of the impact of exercise on the health of men and women of all ages. When researchers compared the strength gains of the elderly participants in this study to findings from other studies they’ve done of college-age men, they found that changes in strength and muscle size were similar in both age groups. The findings were published in a recent issue of the Journal of Gerontology.

“There have been a number of research projects that have come out over the years that suggest there is no age limitation to getting stronger from resistance training,” said Robert Staron, co-author of this study and an associate professor of anatomy in the university’s College of Osteopathic Medicine. “It’s become obvious that it’s important to maintain a certain amount of muscle mass as we age.”

This new study also suggests that elderly men can handle heavy workloads over a long period of time. Participants – who all were in good health and closely monitored during testing and training – performed leg presses, half squats and leg extensions twice a week to exercise the lower body. When the men began the study, they were able to leg press about 375 pounds on average. After the 16-week period, they could take on about 600 pounds. Studies elsewhere have involved low-intensity exercises over a shorter term.

In addition to the increase in strength, researchers found that weight lifting had a beneficial impact on the participants’ cardiovascular system. Tests on an exercise treadmill showed that their bodies used oxygen more efficiently after weight training.

“The individuals run until they are completely exhausted, and it took longer for them to reach that point after resistance training,” Staron said.

Blood samples taken before and after weight training also showed favorable changes in participants’ overall cholesterol profiles, he said, including increases in HDL cholesterol levels and decreases in LDL cholesterol levels.

Losing muscle tone and strength is not uncommon for many senior citizens, Staron said, but this research suggests that a lack of physical exercise can contribute to the problem.

“Certainly, inactivity does play a role in contributing to the decrease in muscle mass,” Staron said. “If we can maintain a certain level of strength through exercise, our quality of life should be better as we age.”

Before beginning a weight lifting regimen, it’s a good idea to consult a physician, Staron advised, adding that it’s also important to learn proper weight lifting techniques. Staron and his colleagues now have turned their attention to how certain weight training routines impact young people.

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Article adapted by MD Sports from original press release.
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Contact: Andrea Gibson
Ohio University

Collaborators on this project are Fredrick Hagerman, Robert Hikida and Thomas Murray of the College of Osteopathic Medicine, former graduate student Seamus Walsh, Roger Gilders of the College of Health and Human Services, Kumika Toma of the College of Arts and Sciences and Kerry Ragg of the Student Health Service.

Research news from Journal of Mass Spectrometry

A new mass spectrometry test can help sports anti-drug doping officials to detect whether an athlete has used drugs that boost naturally occurring steroid levels. The test is more sensitive compared to previous alternatives, more capable of revealing specific suspicious chemical in the body, faster to perform, and could be run on standard drug-screening laboratory equipment. The new test is announced in a special issue of the Journal of Mass Spectrometry that concentrates on detecting drugs in sports.

One of the roles of the masculinising hormone testosterone is to increase muscle size and strength. Taking extra testosterone, or taking a chemical that the body can use to create extra testosterone, could therefore enhance an athlete’s performance. For this reason taking it is banned by the World Anti-Doping Agency (WADA).

The exact level of testosterone varies considerably between different people, so simply measuring total testosterone in an athlete’s urine can not show whether he or she has deliberately taken extra. There is, however, a second chemical in the body, epitestosterone, which is normally present in approximately equal proportions to testosterone. Comparing the ratio of testosterone to epitestosterone can then indicate whether testosterone or a precursor has been taken.

The problem is that it is not always easy to measure these two substances, particularly as they are only present in urine at very low concentrations.

A team of scientists the Sports Medicine Research and Testing Laboratory at the University of Utah have developed a test that makes use of liquid chromatography-tandem mass spectrometry. This method has incredibly high sensitivity (down to 1 ng/ml) and increases the power with which officials can search for both testosterone and epitestosterone within a sample.

“Our system means that we can determine the testosterone/epitestosterone ratio in a sample with greater confidence, and therefore be in a better position to spot doping violations without falsely accusing innocent athletes,” says lead investigator Dr Jonathan Danaceau.

“Not only is the test more sensitive, it is also faster to perform,” says colleague Scott Morrison.

“Having this sort of test available makes cheating harder and lets us take one more step towards enabling free and fair competition,” says Laboratory Director Dr Matthew Slawson.

This paper is part of a special issue for the Olympic Games from the Journal of Mass Spectrometry which focuses of drug use in sport. The issue is available free of charge online for one month at http://www.interscience.wiley.com/journal/jms. The other articles publishing in this issue are:

 

  • History of Mass Spectrometry at Olympic Games (DOI: 10.1002/jms.1445)
  • Nutritional supplements cross-contaminated and faked with doping substances (DOI: 10.1002/jms.1452)
  • Hair analysis of anabolic steroids in connection with doping control results from horse samples (DOI: 10.1002/jms.1446)
  • Mass spectrometric determination of Gonadotrophin releasing hormone (GnRH) in human urine for doping control purposes by means of LC-ESI-MS/MS (DOI: 10.1002/jms.1438)
  • Liquid chromatographic-mass spectrometric analysis of glucuronide-conjugated anabolic steroid metabolites: method validation and inter-laboratory comparison (DOI: 10.1002/jms.1434)
  • Mass Spectrometry of Selective Androgen Receptor Modulators (DOI: 10.1002/jms.1438)
  • Can glycans unveil the origin of glycoprotein hormones? – human chorionic gonadotropin as an example (DOI: 10.1002/jms.1448)
  • A High-Throughput Multicomponent Screening Method for Diuretics, Masking Agents, Central Nervous System Stimulants and Opiates in Human Urine by UPLC-MS/MS (DOI: 10.1002/jms.1436)
  • The application of carbon isotope ratio mass spectrometry to doping control (DOI: 10.1002/jms.1437)
  • Identification of zinc-alpha-2-glycoprotein binding to clone ae7a5 anti-human epo antibody by means of nano-hplc and high-resolution highmass accuracy esi-ms/ms (DOI: 10.1002/jms.1444)
  • Low LC-MS/MS Detection of Glycopeptides Released from pmol Levels of Recombinant Erythropoietin using Nanoflow HPLC-Chip Electrospray Ionization (DOI: 10.1002/jms.1439)
  • Introduction of HPLC/Orbitrap mass spectrometry as screening method for doping control (DOI: 10.1002/jms.1447)

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Article adapted by MD Sports from original press release.
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Contact: Jennifer Beal
Wiley-Blackwell

University Park, Pa. — Girls and boys are now equally caught up in the social pressure for a muscular body image currently lauded in popular culture. A Penn State researcher contends those pressures are leading girls and boys down unhealthy avenues such as the misuse of anabolic steroids.

“Young girls have always had to struggle against the media stereotypes of stick-thin models or voluptuous sexuality, but with the rising popularity of women sports, girls are bombarded with buffed body images,” says Dr. Charles Yesalis, professor of health policy and administration, and exercise and sports science at Penn State, and editor of the newest edition of the book “Anabolic Steroids in Sports and Exercise.” “Now, young boys face pop culture musclemen like The Rock and Steve Austin, given the influence of professional wrestling shows.”

“The current film ‘Charlie’s Angels’ sports karate-kicking women in cool clothes,” he added. “Today’s children look with envy at the physiques of actors Arnold Schwarzenegger, Jean-Claude Van Damme, Wesley Snipes, and Linda Hamilton, whose roles call for a muscular build. Hollywood stars are openly taking Human Growth Hormone (HGH) injections to combat aging.”

In addition, children are entering competitive sports at younger ages and many working families have children signed up in two or three sports. Parents, coaches and young athletes are facing growing violence in amateur athletics. The pressure to win at all costs continues to weigh heavily on children, Yesalis notes.

The concern is that many youths will take shortcuts to achieving a muscular build by using anabolic steroids. Female athletes also are pressured to achieve low body fat to excel in their sport. The Penn State researcher has seen evidence that the pressures are reaching down to young children. For example, the book cites figures from the Monitoring The Future Study, a national-level epidemiological survey conducted annually since 1975. Approximately 50,000 8th, 10th and 12 graders are surveyed each year.

The MTF data shows that during the 1990s, anabolic steroid use among 12 graders –both boys and girls – rose to an all-time high with more than 500,000 adolescents having cycled – an episode of use of 6 to 12 weeks – during their lifetime. And the percentage of girls alone doubled in the same period.

A 1998 study of 965 youngsters at four Massachusetts middle schools found that 2.7 percent admitted to taking illegal steroids for better sports performance. That included some boys and girls as young as 10 years old. “This year’s Olympic doping scandals and the epidemic of anabolic steroids in professional baseball just glorify and justify steroids to impressionable youths,” Yesalis notes. “The use of anabolic steroids has cascaded down from the Olympic, professional and college levels to high schools and junior high schools and now middle schools for athletes and non-athletes alike. ”

“Anabolic steroids are made to order for a female wanting to attain a lean athletic body. While most drug abuse has outcomes that tend to discourage use, females who use anabolic steroids may experience a decrease in body fat, increased muscle size and strength, and enhanced sports performance,” he says.

Girls and boys misusing anabolic steroids may win approval and rewards from parents, coaches and peers, but don’t realize there are long-term negative effects on their health, particularly girls, according to Yesalis. Young girls face potential permanent side effects of male hair growth or baldness, deepening of the voice, the enlargement of the clitoris as well as the known risks of heart and liver diseases.

Published by Human Kinetics, the book incorporates the latest research, experience and insights of 15 experts on the scientific, clinical, historical, legal and other aspects of steroid abuse and drug testing. New information looks at the effects of steroids on health, particularly that of women.

This year, trials of East German doctors, coaches and officials reveal records of systematic doping of young athletes without their own or parents’ knowledge. In 1974, officials’ plan to turn the tiny Communist nation into a superpower in sports included giving performance-enhancing drugs to all competing athletes including children as young as 10 years old. The indictments included 142 former East German athletes who now complain of health problems. In media reports, several female athletes report incidents of miscarriages, liver tumor, gynecological problems and enlarged heart, all showing up decades after the steroid misuse.

“Our society’s current strategy for dealing with the abuse of anabolic steroids in sport primarily involves testing, law enforcement and education,” Yesalis says. “But our efforts to deal with this problem have not been very successful. Unless we deal with the social environment that rewards winning at all costs and an unrealistic physical appearance, we won’t even begin to address the problem.”

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Article adapted by MD Sports Weblog from original press release.
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Contact: Vicki Fong
Penn State

Genetic research into athletic ability should be encouraged for its potential benefits in both sport and public health, a leading group of scientists meeting at the University of Bath said today.

Genetic research into athletic ability should be encouraged for its potential benefits in both sport and public health, a leading group of scientists meeting at the University of Bath said today.

However, ethical concerns, such as whether seeking information about differences between ethnic groups could be perceived as racist research, need to be properly addressed, they warn.

Their recommendations are published in a ‘position stand’ on genetic research and testing launched at the British Association of Sport & Exercise Sciences annual meeting today.

They call for more genetic research in the sport and exercise sciences because of the anticipated benefits for public health, but want researchers to take a more active role in debating the implications of their work with the public.

“If a powerful muscle growth gene was identified, on the one hand this could help develop training programmes that increase muscle size and strength in athletes, but even more importantly the knowledge could be used to develop exercise programmes or drugs to combat muscle wasting in old age,” said Dr Alun Williams from Manchester Metropolitan University, one of the report’s authors.

“We, as scientists investigating genetics, acknowledge a public concern about some genetic research and we believe scientists need to engage in public in debates about the potential benefits of their research.

“Research into the athletic success of East African distance runners or sprinters of West African ancestry might be perceived as unethical.

“But understanding the limits of human exercise capacity in sport could lead to the development of treatments for a range of diseases like cancer and cardiovascular disease.”

The potential applications of genetic testing in sport and exercise also raise some ethical concerns, for example in identifying potential athletic ability before birth.

An Australian company already offers the first genetic performance test (for the ACTN3 gene) which has been linked to sprint and power performance.

The report authors are sceptical about whether this test is useful but anticipate that more advanced versions of these tests will be available in future.

“We are not yet at a point where we can identify a potential future Olympic champion from genetic tests but we may not be very far away,” said Dr Williams, who wrote the report with Drs Henning Wackerhage (Aberdeen University), Andy Miah (University of Paisley), Roger Harris (University of Chichester) and Hugh Montgomery (University College London).

They highlight two dangers of genetic performance tests. Firstly, genetic performance tests might later be linked to disease. For example, a muscle growth gene may later be linked to cancer growth.

“Not all people may want to know, while young that they are at increased risk of cancer by early middle age, but they might inadvertently become aware of that just because they had a ‘sport gene’ test,” said Dr Williams.

Secondly, genetic performance tests can be performed even before birth and this may lead to the selection of foetuses or to abortions based on athletic potential.

The report recommends genetic counselling and that the testing should be confined to mature individuals who fully understand the relevant issues.

Genetic tests might also be used to screen for health risks during sport such as genes that are linked to sudden cardiac death.

Genetic tests for sudden cardiac death are already available but the report recommends that such testing should not be enforced on athletes.

Problems with mandatory testing are highlighted by the case of the basketball player Eddy Curry, who had an irregular heart beat.

Curry was asked by his club, the Chicago Bulls, to perform a predictive genetic test for a heart condition. The athlete refused and was traded to the New York Knicks who did not make such a demand.

In future, genetic tests might be used to identify those that respond with the biggest drop in cholesterol, blood pressure or glucose to exercise.

In a personalised medicine approach, such tests could be used to select subjects for therapeutic exercise programmes but scientists are concerned that this might undermine the ‘exercise for all’ message that already seems difficult to get across to the public.

The authors say that genetic testing might also be used to detect gene doping, which may be a real threat by the time of the London Olympics in 2012, or to show that positive doping tests are the result of a genetic mutation in an athlete.

The report recommends that genetic testing should be used for anti-doping testing as long as the genetic samples are destroyed after testing.

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Article adapted by MD Sports from original press release.
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Contact: Andrew McLaughlin
University of Bath

Experts at The University of Nottingham are to investigate the effect of nutrients on muscle maintenance in the hope of determining better ways of keeping up our strength as we get old.

The researchers, based at the School of Graduate Entry Medicine and Health in Derby, want to know what sort of exercise we can take and what food we should eat to slow down the natural loss of skeletal muscle with ageing.

The team from the Department of Clinical Physiology, which has over 20 years experience in carrying out this type of metabolic study, need to recruit 16 healthy male volunteers in two specific age groups to help in it’s research.

Skeletal muscles make up about half of our body weight and are responsible for controlling movement and maintaining posture. However, at around 50 years of age our muscles begin to waste at approximately 0.5 per cent to one per cent a year. It means that an 80 year old may only have 70 per cent of the muscle of a 50 year old.

Since the strength of skeletal muscle is proportional to muscle size, such wasting makes it harder to carry out daily activities requiring strength, such as climbing stairs and leads to a loss of independence and an increased risk of falls and fractures.

In order for skeletal muscles to maintain their size, the large reservoirs of muscle protein require constant replenishment in the way of amino acids from protein contained within the food we eat. In fact, amino acids from our food act not only as the building blocks of muscle proteins but also actually ‘tell’ our muscle cells to build proteins.

Recent research from the clinical physiology team has shown that the cause of muscle wasting with ageing appears to be an attenuation of muscle building in response to protein feeding. In other words, as we age we lose the ability to covert the protein in the food we eat in to muscle tissue. The proposed research will investigate the mechanisms responsible for this deficit.

Dr Philip Atherton, who is currently recruiting volunteers, said: “I am really excited to be involved in this project because if we can determine ways to better maintain muscle mass as we age it will greatly benefit us all.”

The researchers are looking for 16 healthy, non-smoking, male volunteers aged 18 to 25 and 65 to 75.

Initially, the volunteers will undergo a health screening and then on a different day, under the supervision of a doctor, will be infused with an amino acid mixture to simulate feeding along with a ‘tagged’ amino acid that allows them to assess muscle building. To make these measures, blood samples will be taken from the arm and muscle biopsies from the thigh muscle under local anaesthesia. Volunteers will receive an honorarium to cover their expenses.

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Article adapted by MD Sports from original press release.
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Contact: Lindsay Brooke
University of Nottingham

 

The study will take place at The University of Nottingham’s Medical School which based at the City Hospital in Derby.