Cumulative Endocrine Dysfunction in Relative Energy Deficiency in Sport (RED-S)

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Unfortunately I continue to see athletes, both male and female, whose health and athletic performance is hampered due to Relative Energy Deficiency in Sports (RED-S). There have been some high profile athletes who have been very open about how RED-S has affected them, alerting younger athletes to potential pitfalls.

Does this issue warrant highlighting? Yes! The athletes I see and those that speak out are only just the tip of the iceberg. In a study of exercising females, half were found to have subtle menstrual hormone disruption such as luteal phase deficit or anovulation. A third were amenorrhoeic, with no periods at all. All women of reproductive age, whether an athlete or not, should have regular periods, otherwise there are potential serious health and performance sequaelae. However studies in both the USA and Australia have revealed that the majority of young exercising women are not aware of the link between menstrual disruption and deleterious, potentially irreversible effects on bone health.

The impact of non-integrated periodisation of training, nutrition and recovery has evolved since the early description of the female athlete triad. The constellation of amenorrhoea, disordered eating and osteoporosis is now considered to be a clinical spectrum. In turn the female athlete triad is part of a much broader picture of RED-S, which includes adverse multi-system effects beyond bone health and is also seen in male athletes.

Although an athlete may appear healthy, what are the underlying Endocrine disruptions occurring in RED-S that ultimately will impede both optimal health and performance to full potential? In general, female exercisers are more susceptible to internal and external perturbations as the female Endocrine system is more finely balanced than in males. Nevertheless, in a study of male athletes, in the short time period after completing a training session, bone turnover was adversely affected, with an increase in markers of resorption relative to formation, if an athlete did not refuel rapidly with protein and carbohydrate. In the now classic research by Loucks, 5 days of manipulated energy restricted availability, via dietary intake and exercise output, caused disruption in LH pulsatility in previously eumenorrhoeic women. From this research and subsequent studies, not only is the reproductive axis disrupted with reduced energy availability, in addition hypothalamus-pituitary-thyroid (decreased T3) and adrenal axes (increased cortisol) and decreased IGF1 due to relative GH resistance are all disrupted. These interactive hormonal dysfunctions occur even before reduction in sex steroids. A recent study demonstrated that beyond the average energy availability over a 24 hour time window, within day energy deficits in terms of duration and magnitude are associated with a greater degree of disruption of Endocrine and metabolic markers, in particular decreased oestradiol and increased cortisol. So consistency of nutrition, not only during a training season but from day to day is vital.

Although energy availability is the crucial factor in the pathophysiology of RED-S, measuring this is not practical for all athletes in terms of accuracy and cost. Clinical menstrual status in female athletes and basic Endocrine markers are proposed as being more reliable and accessible. The Endocrine system is very sensitive to internal and external perturbations, as described above, and presages performance consequences of RED-S, such as injury. An important starting point is for all female athletes is to ask themselves: are my periods regular? This is also a vital question that coaches and parents need to consider for athletes in their care. If the answer is no, then this needs to be assessed, ideally by those with experience in Sports Endocrinology.

Why are these clinical and biochemical markers of Endocrine dysfunction important for athletes? Essentially there are significant health and performance implications for athletes. As outlined in the stories of female athletes, by the time career limiting stress fractures become obvious, typically in early twenties, the Endocrine system has been in disarray for a significant time. Long term, irreversible poor bone health and adverse body composition have been established.

In my opinion, emphasis should be placed on the positive outcome of integrating periodised training, nutrition and recovery to support a functional Endocrine system and therefore optimal health and ability to reach full athletic potential. For example for female athletes, competing in sports where low body mass confers a performance advantage, such as ballet, gymnastics and road cycling, finely tuned neuromuscular skills are essential to reach maximal potential and minimise injury risk. Yet these are the athletes most at risk of developing RED-S, with consequential adverse effects on menstrual cycles, endogenous oestrogen secretion and neuromuscular function.

Rather than reading headlines about the concerning health issues amongst athletes, more guidance for athletes and those working with them, on the warning signs and how to combat RED-S are needed so that athletes can reach their full potential and the headlines become about athlete achievements.

For more discussion on the Endocrine and Metabolic aspects of Sport and Exercise Medicine, all members of multi-disciplinary team working with athletes, including athletes and coaches are welcome to the BASEM Spring Conference

BAsem2018_SpringConf_BJSM

References

Relative Energy Deficiency in Sports (RED-S) Practical considerations for endurance athletes

British middle-distance runner Bobby Clay is struggling with osteoporosis but wants her experience to act as a lesson for fellow young athletes Athletics Weekly 2017

In a special AW report, former English Schools champion Jen Walsh reveals the devastation that the female athlete triad can wreak Athletics Weekly 2017

Optimal Health: Especially Young Athletes! Part 3 – Consequences of Relative Energy Deficiency in Sports BASEM 2017

Prevalence High prevalence of subtle and severe menstrual disturbances in exercising women: confirmation using daily hormone measures. Human Repro 2010

Energy deficiency, menstrual disturbances, and low bone mass: what do exercising Australian women know about the female athlete triad? Int J Sport Nutr Exerc Metab. 2012

Female adolescent athletes’ awareness of the connection between menstrual status and bone health J Pediatr Adolesc Gynecol. 2011

Optimal health: including female athletes! Part 1 Bones BJSM 2017

Optimal Health: For All Athletes! Part 4 – Mechanisms BASEM 2017

Optimal health: including male athletes! Part 2 Relative Energy Deficiency in sports BJSM 2017

Sports Endocrinology – what does it have to do with performance? BJSM 2017

The Effect of Postexercise Carbohydrate and Protein Ingestion on Bone Metabolism Translational Journal of the American College of Sports Medicine 2017

Luteinizing hormone pulsatility is disrupted at a threshold of energy availability in regularly menstruating women JCEM 2003

Within-day energy deficiency and reproductive function in female endurance athletes Scandinavian Journal of Science and medicine in Sports 2017

Low Energy Availability is Difficult to Assess But Outcomes Have Large Impact on Bone Injury Rates in Elite Distance Athletes Sports Nutrition and Exercise Metabolism 2017

Body Composition for Health and Sports Performance

Reduced Neuromuscular Performance in Amenorrheic Elite Endurance Athletes Medicine & Science in Sports & Exercise 2017

Conferences in Sport/Dance, Exercise Science and Medicine 2018

Conferences for the New Year:

BAsem2018_SpringConf_BJSM

If you are interested in any aspects of Sport/Dance, Exercise and Lifestyle Medicine here are some suggestions:

British Association of Sport and Exercise Medicine Spring Conference 22 March 2018 “Health, Hormones and Human Performance” Covering the Endocrine and Metabolic aspects of Sport, Dance, Exercise Science and Medicine. From the elite athlete to the reluctant exerciser. Aimed at all those members of the multidisciplinary team working with athletes/dancers, plus athletes/dancers and their coaches/teachers.

CPD points awarded from Faculty of Sports and Exercise Medicine FSEM

BASES British Association of Sport and Exercise Sciences CPD awarded

British Journal of Sports Medicine Quality International Education Approved

CPD points from Royal College of Physicians

CPD from REP-S

 

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Why? The balance and timing of exercise, nutrition and recovery is key to optimising health and all aspects of human performance. Intricate network interactions between the Endocrine system and metabolic signalling pathways drive these positive adaptations. However, non-integration of these lifestyle factors can disrupt signalling feedback pathways and predispose to maladaptation and potentially disease states.

What? Discussion, led by experienced clinicians and researchers will cover:

· Key role of Sports Endocrinology in health and performance

· Effects of exercise modalities on body composition and bone health

· Machine learning in interpreting biochemical & metabolomic patterns

· Endocrine & metabolic markers in assessing health & training status

· Gut metabolism in supporting health and performance

· Exercise as crucial lifestyle factor in pre-existing metabolic dysfunction

Who? This conference is relevant to all members of multidisciplinary teams supporting both reluctant exercisers and elite athletes. Medics, researchers, physiologists, physiotherapists, nutritionists, psychologists, coaches, athletes. All welcome.

Health, Hormones and Human Performance will be a conference of interest to all those involved with aspiring and elite athletes, including dancers (National Institute of Dance Medicine and Science NIDMS) and those supporting reluctant exercisers through Lifestyle Medicine.

Latest news from BASEM. Interview with BASEM Today Issue 41 – Winter 2017

 

Wales Exercise Medicine Symposium by Cardiff Sports & Exercise Medicine Society 27/1/18. This includes Dr Peter Brukner, founder of the Olympic Sports Medicine Park in Melbourne, and an afternoon session discussing the female athlete through the lifespan. CPD points applied for from the Royal College of Physicians, the Faculty of Sports and Exercise Medicine, REPs and the Royal College Of General Practitioners.

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Women in Sport and Exercise Conference 2018  13-14 June Organised by The Women in Sport and Exercise Academic Network and attracting British Association of Sport and Exercise Sciences (BASES) CPD points.

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Body Composition for Health and Sports Performance

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Body Composition from DEXA scan

Focusing on changes in body weight and body mass index (BMI) alone, as outcome measures of lifestyle interventions, ignores the beneficial multi-system and psychological effects of lifestyle medicine, in particular exercise. This includes advantageous changes in body composition for health and performance.

Why is body composition important? Because not all weight is equal in terms of tissue composition and distribution. To support optimal health, favourable levels of lean mass  versus fat mass decreases the risk of sarcopenia, associated bone loss and metabolic syndrome. For athletes, high lean mass coupled with low fat mass is related to improved athletic performance, especially in disciplines where strength to weight ratio a major consideration and/or those disciplines such as gymnastics and ballet where an aesthetic component confers a performance advantage.

The range of methods for measuring body composition have advantages and disadvantages in terms of accuracy, accessibility and expense. Although accurate in experienced hands, skin fold measurements are limited to giving a measure of subcutaneous fat. Impedance scales have the advantage of giving a measure of both total and visceral fat percentage, however accuracy is dependent on hydration status, amongst other variable factors. Dual-Energy X-Ray Absorptiometry (DEXA) scan is the “gold standard” for measuring body composition to include bone, lean and fat: both total and visceral. DEXA scan is relatively inexpensive and very low radiation dose compared to traditional X ray or computerised tomography (CT). This method of assessing body composition during training seasons is used by some professional sports teams. The illustration above shows a trained male with total fat in the athletic range. Although simple to measure, BMI does not accurately reflect body composition. All methods of assessing body composition can potentially have role in monitoring changes, for example over training seasons, and trends for individuals rather than relying on the absolute values of metrics measured.

How to go about optimising body composition? Combined exercise and nutritional strategies trigger and reinforce favourable metabolic and Endocrine signalling pathways. The detail of these lifestyle strategies will depend on the clinical context and the objectives of the individual: ranging from a sedentary person trying to improve health and well being, to an athlete aiming to improve sport performance. In all scenarios protein intake is an important factor in supporting lean mass, alongside tailored exercise/training. Temporal considerations for optimising body composition in athletes include the age of the athlete and targeting key competitions during a training cycle and in long term over athletic career. Ultimately optimising body composition has to translate to improved athletic performance for the endurance athlete. So aiming for “high quality weight loss” with retention or even improved lean mass, is more likely to support performance, rather than focusing on fat mass loss in isolation, which may occur in any case as a secondary consequence of integrated periodised training, nutrition and recovery. Striving for weight loss and reduced fat mass without careful monitoring and attention to effects on performance, can run the risk of athletes developing relative energy deficiency in sports (RED-S). Female athletes with functional hypothalamic amenorrhoea have been shown to decreased levels not only of lean and fat mass, but in addition reduced metabolically active brown fat and the associated hormone isirin which promotes fat “browning” and impacts bone mineralisation. In addition, there are differences between male and female athletes to be considered in terms of body composition and cycling performance.

From middle-age, both lean mass and bone mineral density (BMD) decline: sarcopenia and bone health intertwined. In order to mitigate against these changes, resistance exercise is particularly beneficial to stimulate muscle and load the skeleton and for metabolic and cognitive benefits. BMI is particularly misleading as a metric to assess risk of disease in menopausal women. Rather, the finer detail of body composition, for example visceral fat area, is more informative in terms of metabolic and psychological health.

Body composition is a more reliable indicator of health than body weight or BMI. Nevertheless body composition in isolation is not the sole determinant of health and performance. Rather body composition is just one of many multi-system effects mediated by integrated metabolic and Endocrine signalling pathways. These network effects are driven by lifestyle factors including exercise, nutrition and recovery, to determine health and sports performance.

For more discussion and debate on the role of body composition for health and performance BASEM Spring Conference 2018 6 CPD points from FSEM and BJSM approved for international education

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References

Challenging those hard to shift, big fat obesity risks BMJ 2017; 359: j5303 British Journal of Medicine 2017

Lifestyle Choices for optimising health: exercise, nutrition, sleep British Journal of Sport Medicine 2107

One road to Rome: Exercise British Journal of Sport Medicine 2107

Current Status of Body Composition Assessment in Sport Review and Position Statement on Behalf of the Ad Hoc Research Working Group on Body Composition Health and Performance, Under the Auspices of the I.O.C.Medical Commission

International society of sports nutrition position stand: diets and body composition Journal of the International Society of Sports Nutrition 2017
Case-Study: Body Composition Periodization in an Olympic-Level Female Middle-Distance Runner Over a 9-Year Career International Journal of Sport Nutrition and Exercise Metabolism 2017

Body composition assessment of English Premier League soccer players: a comparative DXA analysis of first team, U21 and U18 squads Journal of Sports Sciences

Protein Recommendations for Weight Loss in Elite Athletes: A Focus on Body Composition and Performance International Journal of Sport Nutrition and Exercise Metabolism 2017

Optimal Health: For All Athletes! Part 4 – Mechanisms British Association for Sport and Exercise Medicine 2017

Effect of Chronic Athletic Activity on Brown Fat in Young Women Plos One 2106

Irisin levels are lower in young amenorrheic athletes compared with eumenorrheic athletes and non-athletes and are associated with bone density and strength estimates Plos One

Kings and Queens of the Mountains Science4Performance

Low bone mineral density in middle-aged women: a red flag for sarcopenia Menopause 2017

Resistance training – an underutilised drug available in everybody’s medicine cabinet BJSM 2017

Benefits of resistance training in physically frail elderly: a systematic review Ageing Clinical and Experimental Research 2017

Is BMI a valid measure of obesity in postmenopausal women? Menopause 2017

Association of visceral fat area with the presence of depressive symptoms in Chinese postmenopausal women with normal glucose tolerance Menopause 2017

 

 

 

Health and Performance during Lifespan: latest research

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Your lifespan depends on genetic and key lifestyle choices

Lifespan is dependent on a range of genetic factors combined with lifestyle choices. For example a recent study reported that an increase in one body mass index unit reduced lifespan by 7 months, whilst 1 year of education increased lifespan by 11 months. Physical activity was shown to be a particularly important lifestyle factor through its action on preventing age-related telomere shortening and thus reducing of cellular ageing by 9 years. Nevertheless, even though males and females have essentially identical genomes, genetic expression differs. This results in different disease susceptibilities and evolutionary selection pressures. More studies involving female participants are required!

Circadian clock

Much evidence is emerging about the importance of paying respect to our internal biological clocks when considering the timing of lifestyle factors such as eating, activity and sleep. For example intermittent fasting, especially during the night, and time restricted eating during the day enables metabolic flexibility. In other words, eating within a daylight time window will support favourable metabolism and body composition. No midnight snacks!

For athletes, even more care needs be given to timing of nutrition to support athletic performance. In the short term there is evidence that rapid refuelling after training with a combination of carbohydrate and protein favours a positive balance of bone turnover that supports bone health and prevents injury in the longer term. Periodised nutrition over a training season, integrated with exercise and recovery, is important in order to benefit from training adaptations and optimise athletic performance.

Protein intake in athletes and non athletes

Recovering from injury can be a frustrating time and some athletes may be tempted to reduce food intake to compensate for reduced training. However, recommendations are to maintain and even increase protein consumption to prevent a loss of lean mass and disruption of metabolic signalling. In the case of combined lifestyle interventions, such as nutrition and exercise aimed at reducing body weight, these should be directed at improving body composition. Adequate protein intake alongside exercise will maintain lean mass in order to minimise the risk of sarcopenia and associated bone loss which can occur during hypocaloric regimes. Good protein intake is important for bone health to support bone mineral density and reduce the risk of osteoporosis and fracture.

Adolescent Athlete

In the young athlete, integrated periodisation of training, nutrition and recovery is of particular importance, not only to support health and performance, but as an injury prevention strategy.  Sufficient sleep and nutrition to match training demands are key.

Differences between circadian phenotype and performance in athletes

For everyone, whether athlete or reluctant exerciser, balancing and timing key lifestyle choices of exercise, nutrition and sleep are key for optimising health and performance. However there are individual differences when it comes to the best time for athletes to perform, according to circadian phenotype/chronotype. In other words personal biological clocks which run on biological time. An individual’s performance can vary by as much as 26% depending on the time of day relative to one’s entrained waking time.

Later in Life

Ageing can be can be confused with loss of fitness and ability to perform activities of daily living. Although a degree of loss of fitness does occur with increasing age, this can be prevented to a certain degree and certainly delayed with physical activity. Exercise attenuates sarcopenia, which supports bone mineral density with the added benefit of improved proprioception, helping to reduce risk of falls and potential fracture; not to mention the psychological benefits of exercise.

 

For more discussion on Health Hormones and Human Performance come to British Association of Sport and Exercise Medicine Spring Conference 

BAsem2018_SpringConf_BJSM

References

Genome-wide meta-analysis associates HLA-DQA1/DRB1 and LPA and lifestyle factors with human longevity Nature Communications 2017

Physical activity and telomere length in U.S. men and women: An NHANES investigation Preventive Medicine 2017

The landscape of sex-differential transcriptome and its consequent selection in human adults BMC Biology 2017

Temporal considerations in Endocrine/Metabolic interactions Part 1 British Journal of Sport and Exercise Medicine, October 2017

Flipping the Metabolic Switch: Understanding and Applying the Health Benefits of Fasting Obesity 2017

Temporal considerations in Endocrine/Metabolic interactions Part 2 British Journal of Sport and Exercise Medicine, October 2017

Time-restricted eating may yield moderate weight loss in obesity Endocrine Today 2017

The Effect of Postexercise Carbohydrate and Protein Ingestion on Bone Metabolism Translational Journal of the American College of Sports Medicine 2017

Periodized Nutrition for Athletes Sports Medicine 2017

Internal Biological Clocks and Sport Performance British Journal of Sport and Exercise Medicine, October 2017

Nutritional support for injuries requiring reduced activity Sports in Science Exchange 2017

Balance fat and muscle to keep bones healthy, study suggests NTU October 2017

Dietary Protein Intake above the Current RDA and Bone Health: A Systematic Review and Meta-Analysis Journal of the American College of Nutrition 2017

Too little sleep and an unhealthy diet could increase the risk of sustaining a new injury in adolescent elite athletes Scandinavian Journal of Medicine & Science in Sports

Sleep for health and sports performance British Journal of Sport and Exercise Medicine, 2017

The impact of circadian phenotype and time since awakening on diurnal performance in athletes Current Biology

Successful Ageing British Association of Sport and Exercise Medicine 2017

Focus on physical activity can help avoid unnecessary social care BMJ October 2017

Biochemical Pathways of Sarcopenia and Their Modulation by Physical Exercise: A Narrative Review Frontiers in Medicine 2017

 

Lifestyle Choices

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Lifestyle Choices: Exercise, Nutrition, Sleep

Lifestyle factors of exercise, nutrition and sleep are vital for optimising health. In the illustration shown, ideally we should be in the green zone representing a balance between these lifestyle factors. Slipping into the peripheral red zone represents an imbalance: either too much or too little of any of these three elements. In particular exercise is of paramount importance being the most effective way of producing beneficial, multi-system effects mediated via the Endocrine system to optimise health and playing an important role in chronic disease prevention. However, it is not just a matter of what, but when: timing is crucial in integrating lifestyle factors with internal biological clocks. Beyond these guiding principles, personal preference and choice is emerging as being just as important as the lifestyle factor itself.

In a fascinating study, 58 participants were given either a prescribed exercise session, or a choice of exercise. Afterwards the participants were presented with a choice of foods, which they believed was simply as way of thank you for taking part in the exercise study. Post exercise, in those given no choice exercise, higher energy intake of food was consumed with larger proportion of “unhealthy” food compared to choice exercise group. The choice exercise group reported greater value and enjoyment of the exercise session. Thus autonomous choice of exercise not only provides positive reinforcement of exercising, but subsequent food choice is improved.

This concept of facilitating self determination, particularly when it comes to exercise was explored at the the recent annual British Association of Sport and Exercise conference. “Practicalities of intervention design, adherence and motivation” was presented by Dr Carly McKay from Bath University, who described how empowering people to make choices is far more likely to mean they will adhere to those lifestyle options that will optimise health.

What about the optimal timing of exercise which might improve motivation and performance? Well this depends on the context and what you are trying to achieve. In the case of training for competition and competition itself, optimal performance tends to be early evening, providing the most favourable hormonal milieu. Although in theory the morning diurnal release of cortisol might help with exercise, the downside is that this may interfere with blood glucose regulation. Furthermore, focusing on just one hormone in the Endocrine system, rather than the integrated function of the hypothalamic-pituitary axis could be misleading. Although due respect should be paid to internal biological clocks, to prevent circadian misalignment between internal pacemakers and external factors; equally becoming too obsessive about sticking to a rigid schedule would psychologically take away that essential element of choice. Practicality is a very important consideration and a degree of flexibility when planning the timing of exercise. For example, my choice of cardiovascualar exercise is swimming, which I fit in according to work commitments and when public lane swimming is available. Fortunately whilst at the BASEM conference in Bath, these practical conditions were met during the lunch break to take advantage of the 50m pool at Bath University. Pragmatic, not dogmatic when it comes to timing of exercise.

Timing of nutrition post exhaustive exercise is an important factor in supporting bone health. Immediate, rather than delayed refuelling with carbohydrate and protein is more advantageous in the balance of bone turnover markers; favouring formation over resorption. In the longer term, prolonged low energy availability as in the situation of relative energy deficiency in sport (RED-S) has a potentially irreversible adverse effect on bone health. In terms of the timing of meals, not eating too close to going to sleep, ideally 2 hours before melatonin release, is best for metabolic health.

Backing up the lifestyle choices of exercise and nutrition is sleep. Timing, duration and quality of sleep is essential for many aspects of health such as hormonal release of growth hormone, functional immunity and cognitive function. Certainly it is well recognised that shift workers, with circadian misalignment: disturbed sleep patterns relative to intrinsic biological clocks, are more at risk of developing cardio-metabolic disease.

In summary, a prescriptive approach to lifestyle factors could be counter productive. Discussing options and encouraging individuals to make their own informed and personal choices is far more likely to enable that person to take responsibility for their health and adhere to changes in lifestyle that are beneficial for their health. Having worked in hospital based NHS diabetic clinics for many years, I appreciate that supporting reluctant exercisers is not always an easy task. Equally it can be difficult to distinguish between the effects of ageing and loss of fitness. However, this does not mean that this supportive and inclusive approach should be abandoned. Rather, encouraging people to participate in decision making that they feel leads to options that are realistic and beneficial, is the approach most likely to work, especially in the long term.

“If we could give every individual the right amount of nourishment and exercise, not too little and not too much, we would have found the safest way to health.”
— Hippocrates

 

For more discussion on Health Hormones and Human Performance come to British Association of Sport and Exercise Medicine Spring Conference 

BAsem2018_SpringConf_BJSM

References

Presentations

One road to Rome: Exercise Dr N. Keay, British Journal of Sports Medicine 2017

Endocrine system: balance and interplay in response to exercise training Dr N. Keay 2017

Temporal considerations in Endocrine/Metabolic interactions Part 1 Dr N. Keay, British Journal of Sports Medicine 2017

Temporal considerations in Endocrine/Metabolic interactions Part 2 Dr N. Keay, British Journal of Sports Medicine 2017

Internal Biological Clocks and Sport Performance Dr N. Keay, British Association of Sport and Exercise Medicine 2017

Providing Choice in Exercise Influences Food Intake at the Subsequent Meal Medicine & Science in Sports & Exercise October 2017

BASEM/FSEM Annual Conference 2017, Assembly Rooms, Bath

Addiction to Exercise – what distinguishes a healthy level of commitment from exercise addiction? Dr N. Keay, British Journal of Sports Medicine 2017

The Effect of Postexercise Carbohydrate and Protein Ingestion on Bone Metabolism Translational Journal of the American College of Sports Medicine October 2107

Optimal Health: For All Athletes! Part 4 – Mechanisms Dr N. Keay, British Association of Sport and Exercise Medicine 2017

Sleep for health and sports performance Dr N. Keay, British Journal of Sports Medicine 2017

Focus on physical activity can help avoid unnecessary social care British Medical Journal October 2017

Internal Biological Clocks and Sport Performance

A Nobel Prize was awarded this week to researchers who uncovered the molecular mechanisms controlling circadian rhythm: our internal biological clock.

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Circadian Hormone Release

These mechanisms rely on negative feedback loops found in many biological systems where periodicity of gene expression is key, such as the Endocrine system. Internal biological clocks allow for anticipation of the requirements from body systems at different times of the day and the ability to adapt to changes in external lifestyle factors. What is the clinical significance of biochronometers?

The importance of integration of lifestyle factors, such as timing of eating, activity and sleep with our internal biological clocks is revealed in situations of circadian misalignment that lead to suboptimal health and disease states in the longer term.

Consideration of our biochronometers is especially important for athletes in order to synchronise periodised training, nutrition and recovery and thus optimise health and sports performance.

Athletic Performance Performance in a cycle time trial was found to be better in the evening, rather than the morning, proposed to be due to a more favourable endogenous hormonal and metabolic internal milieu. Certainly there were some disgruntled swimmers at an international event, when the usual pattern of morning heats and evenings finals was switched, to accommodate television viewing spectators.

Female athletes: menstrual cycle/training season Women have an extra layer of endogenous biological periodicity in the form of the menstrual cycle controlled by temporal changes of hormone release in the hypothamalmus-pituitary-ovarian Endocrine axis. Changes in external factors of training load, nutrition and recovery are detected by the neuroendocrine gatekeeper, the hypothalamus, which produces an appropriate change in frequency and amplitude of GnRH (gonadotrophin releasing hormone), which in turn impacts the pulsatility of LH (lutenising hormone) release from the pituitary and hence the phases of the menstrual cycle, in particular ovulation. Even short term reduction of energy availability in eumenorrhoeic female athletes can inhibit LH pulsatility frequency and release of other hormones such as IGF1. Disrupted release of sex steroids and IGF1 has a negative effect on bone turnover: increased resorption and decreased formation. Active females have been found more susceptible to reduction in energy availability impacting bone metabolism than their male counterparts.

Another consequence of the phasic nature of the menstrual cycle relating to external factors such as exercise, is that injury risk could be linked to changes in the expression of receptors for for sex steroids oestrogen and progesterone in skeletal muscle. Certainly during pregnancy and the post partum period, relaxin hormone increases the laxity of soft tissues, such as ligaments, and hence maintenance stretching, rather than seeking to increase flexibility, is recommended to prevent injury, .

In order to produce desired temporal adaptive changes in response to exercise training, signalling pathways mediated by reactive oxidative species and inflammatory markers are stimulated in the short term, with supportive Endocrine interactions in the longer term. However, an over-response can impair adaptive changes and impact other biological systems such as the immune system. This maladaptive response could occur as a result of non-integrated periodisation of training, nutrition and recovery in athletes and, in the case of female athletes, oral contraceptive pill use has been implicated, as this effectively imposes a medical menopause, preventing the phasic release of endogenous hormones.

Considering a longer time scale, such as a training season, female athletes were found to have a more significant fall ferritin during than male athletes. Low normal iron does not necessarily correlate to iron deficiency anaemia, but low levels in athletes can impact bone health. Supplementation with vitamin C to improve absorption may help, although iron overload can have deleterious effects. As training intensity increases as the season progresses, six monthly haematological reviews for female athletes were recommended in this study.

Changes in set point feedback Feedback control of the Endocrine system, for example the hypothalamic-pituitary-thyroid axis is dynamic: both anticipatory and adaptive, depending on internal and external inputs. However, presentation of a prolonged stimulus can result in maladaptation in the longer term. For example, disruption of signalling pathways leading to hyperinsulinaemia results in insulin resistance, which represents the underlying pathophysiological mechanism of obesity and the metabolic syndrome. In other words a situation of tachyphylaxis, where prolonged, repeated stimulus over time results in insensitivity to the original stimulus. This also applies to the nature of exercise training over a training season and diets that exclude a major food type: temporal variety is key.

Lifespan (prematurity, ageing) Changes during the lifespan represent an important biochronometer. Premature and small-for-dates babies are at risk of long term metabolic and Endocrine dysfunction, potentially due to intrauterine reprogramming of the hypothalamic-pituitary axis. At the other end of the biological time scale, with advancing age, DNA methylation and changes in epigenetic expression occur. It has been suggested that this age related methylation drift could be delayed with calorie restriction. Melatonin, a key player in intrinsic biological time keeping has been proposed to attenuate bone resorption by reducing relative oxidative stress. This would potentially explain why shift workers with disrupted sleep patterns are reported to be at risk not only of metabolic dysfunction, but also impaired bone health. Disrupted sleep patterns are a concern for athletes, especially those whose training and competition schedule involve frequent international travel across time zones.

In summary, respecting your internal biological clocks and integrating your lifestyle and your training, nutrition and recovery with these intrinsic pacemakers in mind will optimise health and performance.

References

The Nobel Prize in Physiology or Medicine 2017

Circadian clock control of endocrine factors Nat. Rev. Endocrinol

Temporal considerations in Endocrine/Metabolic interactions Part 1 Dr N. Keay, British Journal of Sports Medicine 2017

Temporal considerations in Endocrine/Metabolic interactions Part 2 Dr N. Keay, British Journal of Sports Medicine 2017

Athletic Fatigue: Part 2 Dr N. Keay 2017

Effect of Time of Day on Performance, Hormonal and Metabolic Response during a 1000-M Cycling Time Trial Plos One 2017

Optimal Health: For All Athletes! Part 4 – Mechanisms Dr N. Keay, British Association of Sport and Exercise Medicine 2017

Effects of reduced energy availability on bone metabolism in women and men Bone 2017

Expression of sex steroid hormone receptors in human skeletal muscle during the menstrual cycle Acta Physiol (Oxf). 2017

Endocrine system: balance and interplay in response to exercise training

Kynurenic acid is reduced in females and oral contraceptive users: Implications for depression Science Direct 2017

Oxidative Stress in Female Athletes Using Combined Oral Contraceptives Sports Medicine

Iron monitoring of male and female rugby sevens players over an international season J Sports Med Phys Fitness. 2017

Thyroid Allostasis–Adaptive Responses of Thyrotropic Feedback Control to Conditions of Strain, Stress, and Developmental Programming Frontiers in Endocrinology 2017

Stress- and allostasis-induced brain plasticity Annu Rev Med

Optimising Health and Athletic Performance Dr N. Keay 2017

Long-term metabolic risk among children born premature or small for gestational age Nature Reviews Endocrinology 2017

Caloric restriction delays age-related methylation drift Nature Communications 2017

Melatonin at pharmacological concentrations suppresses osteoclastogenesis via the attenuation of intracellular ROS Osteoporosis International 2017

Sleep for health and sports performance Dr N. Keay, British Journal of Sports Medicine 2017

 

Optimising Health and Athletic Performance

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In order to improve sports performance, athletes periodise their training, nutrition and recovery within the context of a training season. For those not in exercise training, these controllable lifestyle factors correspond to exercise, diet and sleep, which require modification during the lifespan. In old money, this was called preventative medicine. Taking this a step further, rather than preventing disease, this proactive, personalised approach optimises health. Health should be a positive combination of physical, mental and social well being, not simply an absence of illness.

Failure to balance these lifestyle factors in an integrated fashion leads to negative outcomes. An athlete may experience maladaptation, rather than the desired adaptations to exercise training. For non-athletes an adverse combination of lifestyle factors can lead to suboptimal health and a predisposition to developing chronic disease.

What are the fundamental pathophysiological mechanisms involved in the aetiology of the clinical spectrum of suboptimal health, suboptimal sports performance and chronic disease?

Inflammation A degree of systemic inflammation and oxidative stress induced by exercise training is required to drive desired adaptations to support improved sport performance. However, prolonged, elevated levels of inflammation have adverse effects on health and underpin many chronic disease states. For example, inflammation is a contributing pathophysiological factor in the development of atherosclerosis and atherothrombosis in cardiovascular disease. What drives this over-response of the inflammatory process? Any combination of adverse lifestyle factors. Adipose tissue has an Endocrine function, releasing a subgroup of cytokines: adipokines which have peripheral and central signalling roles in energy homeostasis and inflammation. In a study of Belgian children, pro-inflammatory energy related biomarkers (high leptin and low adiponectin) were associated with decreased heart rate variability and hence in the long term increased risk of cardiovascular disease. For those with a pre-existing chronic inflammatory condition, response to treatment can be optimised with personalised lifestyle interventions.

Metabolism Non-integrated lifestyle factors can disrupt signalling pathways involved in glucose regulation, which can result in hyperinsulinaeamia and insulin resistance. This is the underlying pathological process in the aetiology of metabolic syndrome and metabolic inflexibility. Non-pharmacological interventions such as exercise and nutrition, synchronised with endogenous circadian rhythms, can improve these signalling pathways associated with insulin sensitivity at the mitochondrial level.

Intriguingly, evidence is emerging of the interaction between osteocalcin and insulin, in other words an Endocrine feedback mechanism linking bone and metabolic health. This is reflected clinically with increased fracture risk found amongst type 2 diabetics (T2DM) with longer duration and higher HbA1C.

Hormone imbalance The hypothalamus is the neuroendocrine gatekeeper of the Endocrine system. Internal feedback and external stimuli are integrated by the hypothalamus to produce an appropriate Endocrine response from the pituitary gland. The pathogenesis of metabolic syndrome involves disruption to the neuroendocrine control of energy homeostasis with resistance to hormones secreted from adipose tissue (leptin) and the stomach (ghrelin). Further evidence for the important network effects between the Endocrine and metabolic systems comes from polycystic ovarian syndrome (PCOS). Although women with this condition typically present to the Endocrine clinic, the underlying aetiology is metabolic dysfunction with insulin resistance disrupting the hypothamic-pituitary-ovarian axis. The same pathophysiology of disrupted metabolic signalling adversely impacting the hypothalamic-pituitary-gonadal axis also applies to males.

In athletes, the exact same signalling pathways and neuroendocrine systems are involved in the development of relative energy deficiency in sports (RED-S) where the underlying aetiology is imbalance in the periodisation of training load, nutrition and recovery.

Gastrointestinal tract In addition to malabsorption issues such as coeliac disease and non-gluten wheat sensitivity, there is emerging evidence that the composition and diversity of the gut microbiota plays a significant role in health. The microbiome of professional athletes differs from sedentary people, especially at a functional metabolic level. Conversely, an adverse gut microbiome is implicated in the pathogenesis of metabolic dysfunction such as obesity and T2DM, via modulation of enteroendocrine hormones regulating appetite centrally and insulin secretion peripherally.

Circadian disregulation As previously discussed, it is not just a question of what but WHEN you eat, sleep and exercise. If there is conflict in the timing of these lifestyle activities with internal biological clocks, then this can disrupt metabolic and endocrine signally. For example, in children curtailed sleep can impact glucose control and insulin sensitivity, predisposing to risk of developing T2DM. Eating too close to the onset of melatonin release in the evening can cause adverse body composition, irrespective of what you eat and activity levels. In those with pre-existing metabolic dysfunction, such as PCOS, timing of meals has an effect on insulin levels and hence reproductive Endocrine function. The immune system displays circadian rhythmicity which integrated with external cues (for example when we eat/exercise/sleep) optimises our immune response. For athletes competing in high intensity races, this may be more favourable in terms of Endocrine and metabolic status in the evening.

Psychology Psychological stress impacts the key pathophysiological mechanisms outlined above: metabolic signalling, inflammation and neuroendocrine regulation, which contribute to Endocrine and metabolic dysfunction. Fortunately stress is a modifiable lifestyle risk factor. In the case of functional hypothalamic amenorrhoea (where nutrition/exercise/sleep are balanced), psychological intervention can reverse this situation.

Conclusion Putting this all together, if the modifiable lifestyle factors of exercise, nutrition, sleep are optimised in terms of composition and timing, this improves metabolic and Endocrine signalling pathways, including neuroendocrine regulation. Preventative Medicine going beyond preventing disease; it optimises health.

BASEM annual conference 22/3/18: Health, Hormones and Human Performance

Presentations

References

Athletic Fatigue: Part 2 Dr N. Keay

From population based norms to personalised medicine: Health, Fitness, Sports Performance Dr N. Keay, British Journal of Sports Medicine 2017

Endocrine system: balance and interplay in response to exercise training Dr N. Keay

Saturated fat does not clog the arteries: coronary heart disease is a chronic inflammatory condition, the risk of which can be effectively reduced from healthy lifestyle interventions British Journal of Sports Medicine 2017

Longitudinal Associations of Leptin and Adiponectin with Heart Rate Variability in Children Frontiers in Physiology 2017

A Proposal for a Study on Treatment Selection and Lifestyle Recommendations in Chronic Inflammatory Diseases: A Danish Multidisciplinary Collaboration on Prognostic Factors and Personalised Medicine Nutrients 2017

Assessment of Metabolic Flexibility by Means of Measuring Blood Lactate, Fat, and Carbohydrate Oxidation Responses to Exercise in Professional Endurance Athletes and Less-Fit Individuals Sports Medicine 2017

Skeletal muscle mitochondria as a target to prevent or treat type 2 diabetes mellitus Nature Reviews Endocrinology

Insulin and osteocalcin: further evidence for a mutual cross-talk Endocrine 2017

HbA1c levels, diabetes duration linked to fracture risk Endocrine Today 2017

The cellular and molecular bases of leptin and ghrelin resistance in obesity Nature Reviews Endocrinology 2017

Metabolic and Endocrine System Networks Dr N. Keay

Adiponectin and resistin: potential metabolic signals affecting hypothalamo-pituitary gonadal axis in females and males of different species Reproduction 2017

Optimal Health: For All Athletes! Part 4 – Mechanisms Dr N. Keay, British Association of Sport and Exercise Medicine 2017

Ubiquitous Microbiome: impact on health, sport performance and disease Dr N. Keay

The microbiome of professional athletes differs from that of more sedentary subjects in composition and particularly at the functional metabolic level Gut. BMJ

Interplay between gut microbiota, its metabolites and human metabolism: Dissecting cause from consequence Trends in Food Science & Technology 2016

Temporal considerations in Endocrine/Metabolic interactions Part 1 Dr N. Keay, British Journal of Sports Medicine 2017

Temporal considerations in Endocrine/Metabolic interactions Part 2 Dr N. Keay, British Journal of Sports Medicine 2017

Sleep Duration and Risk of Type 2 Diabetes Paediatrics 2017

Later circadian timing of food intake is associated with increased body fat Am J Clin Nutr. 2017

Effects of caloric intake timing on insulin resistance and hyperandrogenism in lean women with polycystic ovary syndrome Clin Sci (London)

Immunity around the clock Science

Effect of Time of Day on Performance, Hormonal and Metabolic Response during a 1000-M Cycling Time Trial PLOS

Type 2 diabetes mellitus and psychological stress — a modifiable risk factor Nature Reviews Endocrinology 2017

Recovery of ovarian activity in women with functional hypothalamic amenorrhea who were treated with cognitive behaviour therapy Fertil Steril

 

Relative Energy Deficiency in Sports (RED-S) Practical considerations for endurance athletes

EnergyBalance

Introduction Relative Energy Deficiency in Sport (RED-S) has evolved from the previously described Female Athlete Triad (menstrual dysfunction, disordered eating and decreased bone mineral density). The reason for the development of this clinical model of RED-S is that it has become apparent that low energy availability, ie not eating enough calories to support the combined energy demands of health and training, has more widespread adverse impacts on health and consequently performance in athletes and dancers than previously recognised. Furthermore, the RED-S model includes both male and female athletes– so if you are a male athlete, please do not stop reading! Low energy availability can impact male and female exercises of all levels and of all ages. Young developing athletes can be at particular risk of RED-S as this represents a time of growth and development, which entails many nutritional demands, in addition to those to support training. This represents a time to set up the template for health into adulthood.

Why does RED-S occur? RED-S is particularly prevalent in sports where low body weight confers a performance advantage or for aesthetic reasons. For example: long distance running, triathlon, gymnastics, dance and cycle road racing. However, RED-S could also occur not as an intentional strategy to control body weight, but rather during cycles of increased training load where periodised nutrition has not been synchronised with the increased demand on the body.

What is RED-S? Fundamentally there is a mismatch between food intake (in terms of energy and micronutrients) and the demand for nutrition required to cover expenditure, both of exercise training and for basic “housekeeping” tasks in the body to maintain health. If there is insufficient energy availability, then the body switches into an energy saving mode. This “go slow” mode has implications for hormone production and metabolic processes, which impacts all systems throughout the body. The reason why RED-S was originally described as the Female Athlete Triad is that in women the “energy saving mode” involves menstrual periods being switched off: a pretty obvious external sign as all women of child bearing age should have periods (apart from when pregnant). Low oestrogen levels have an adverse effect on bone health, resulting in decrease in bone mineral density. This effectively renders young women at increased risk of both soft tissue and bone injury, as seen in post-menopausal women. As described in the IOC statement published 2014 and updated 2018 in British Journal of Sports Medicine , the Female Athlete Triad is now recognised as just the tip of the iceberg. Disruption of hormone levels does not only adversely impact menstrual periods and bone health. There are knock on effects impacting the immune system, cardiovascular system, muscles, nervous system, gut health and the list goes on. Importantly, it is recognised that this situation is also seen in male athletes: low energy availability resulting in adverse health and performance consequences. Although exercise/dance is known to have many beneficial effects on health, all these beneficial effects are negated by low energy availability. For example, whether or not a sport is weight bearing, which traditionally improves bone health, in RED-S the predominant effect of disrupted hormones is to decrease bone density, leading to increased fracture risk.

Male cyclists Road cyclists are doubly at risk of the detrimental effects of RED-S on bone health. Performing a non-weight bearing form of exercise deprives the skeleton of the positive effect of mechanical skeletal loading on bone health. Furthermore being low body weight is a performance advantage for road cyclists when it comes to riding up hills/mountains in order to produce higher Watts/Kg over 60 minutes (60 minute functional threshold power FTP). This puts cyclists at risk of developing low energy availability, endocrine dysfunction and consequent impairment of bone health. In weight bearing sport the warning sign of suboptimal bone health if often stress fracture. This will be absent in cyclists. Hence low energy availability may go unrecognised until a bike fall results in serious fracture and indeed fractures appears as the most common type of injury amongst cyclists. Furthermore, the lumbar spine is recognised as the site most susceptible to endocrine dysfunction in RED-S. Vertebral fracture is recorded as the type of fracture in cyclists requiring the longest time off the bike. In a recent study, it was found that the factor most indicative of 60 minute FTP, was training load and NOT low body fat. Furthermore, training in low energy availability state will not result in the expected 60 minute FTP performance. So far more effective to train with sufficient nutrition on board, rather than restricting intake which will render training less effective.

What is the significance of RED-S? Do these effects of RED-S matter? Yes: there is a detrimental effect on not only health, but on all elements of sports performance. These include an inability to improve as expected in response to training and increased risk of injury. In the long-term there are potential implications for health with inability to reach peak bone mass for young athletes and at the other end of the scale, irreversible bone loss being seen in retired athletes.

Here is a summary of the potential impact of RED-S:

• Endocrine dysfunction: decreased training response

• Metabolic disruption: decreased endurance performance

• Bone health: increased risk bone stress injuries

• Decreased functional immunity: prone to infection

• Gut malfunction: impaired absorption of nutrients

• Decreased neuromuscular co-ordination: injury risk

• Psychological impact: inability to recognise risk developing RED-S

As you can see, these adverse effects are all relevant to performance in endurance sport.

What to do if you are concerned you may have RED-S?

Health Considerations:

• Women: even if your adult weight is steady, if you are a female athlete of reproductive age whose periods have stopped, then do not ignore this! In the first instance, you need to exclude any other causes (for example polycystic ovary syndrome and other hormone issues) in conjunction with your doctor. Then take a look at how you are eating in line with your training load – see the nutritional considerations section below.

• Men: if you are a male athlete struggling to improve sport performance, then review both your training load and your periodised nutrition and recovery. If the cause is RED-S then do not wait until your sport performance drops or you get injured before taking action. You may also want to consider having your testosterone levels measured to check that these are in the normal range.

Nutritional Considerations: From colleague Jo Scott-Dalgleish BSc (Hons), mBANT, CNHC

It is important to consider whether the energy deficiency that you are experiencing is intentional or unintentional.

Intentional: you may be deliberately restricting your calorie intake to lose weight and body fat, although you are already a healthy weight, as you believe this will improve your power-to-weight ratio or run speed.

  • If you are trying to lose weight – or anxious about gaining weight – and experiencing issues with hormones (such as missing your periods or not experiencing morning erections) or bone health (such as getting a stress fracture) or finding that your performance is declining rather than improving, it may be time to seek support.
  • This is particularly important if your eating patterns have become disordered, eg exclusion of multiple food groups, binge eating and/or purging, or deliberately avoiding social situations around food.
  • Please visit the resources section of an excellent campaign website that has been put together to help athletes talk more openly about their experiences with food, disordered eating and RED-S and find help: https://trainbrave.org/resources/.
  • Another great resource to learn more about RED-S and how it can adversely affect your health is http://health4performance.co.uk/athlete-dancer/

Unintentional: eating fewer calories than your body needs when you are training hard is common in endurance athletes and often not deliberate.

  • You may not yet be experiencing the symptoms of RED-S outlined as above, but you are greatly at risk of doing so if you continue to under-eat relative to your training over a period of months or years.
  • You do not need to be losing weight to be energy deficient, as your body’s metabolism adjusts to a lower intake but compromises on other functions while your weight stays the same. For example, you may experience constipation or bloating due to slowed digestive function. Here are some tips to help you meet your energy needs.

Here are some tips to help you to better manage your energy intake if you are at unintentional risk of RED-S.

  • Track your food intake vs energy expenditure for a short period. Use My Fitness Pal or a similar app to track these daily over the course of week. On any day when you train, if you are consuming fewer than 2500 calories as a male endurance athlete and 2000 calories as a female endurance athlete after taking your energy expenditure through training into account, your intake is likely to be inadequate as these are the guidelines for the general population. Use this data to learn more about appropriate food choices and serving sizes and introduce some changes to increase your intake in line with your training load. But I do not suggest using apps like these on a long-term basis as they may encourage an unhealthy obsession with your food intake.
    • Periodise your carbohydrate intake in line with your training. Increase your intake of starches and sugars (including vegetables and fruit) on your heavier training days. A low daily carbohydrate intake might be in the range of 2-4 g/kg of body weight. This is OK for lower volume training days but should be increased to 5-8 g/kg when training for 2-3 hours or more in a single day. This would include use of sports nutrition products like bars, gels and sports drinks during training. Again, use an app like My Fitness Pal for a week to help you assess your carbohydrate intake.
  • Pay attention to your recovery nutrition. Consuming 15-25g of protein and 45-75g of carbohydrate in the hour after exercise, whether as a snack or as part of a meal will help you to each your energy intake goals, restock your glycogen stores for your next training session and protect lean muscle mass.
  • Avoid excluding foods, whole food groups or following ‘fad diets’. Unless you have a genuine allergy or a diagnosed medical condition such as coeliac disease or lactose intolerance. Or you have been advised to avoid certain foods by a dietician or other well-qualified nutrition practitioner to help manage a health condition such as Irritable Bowel Syndrome. If you are vegetarian or vegan, see my blog here [link to https://www.endurancesportsnutritionist.co.uk/blog/vegan-diets-guide-endurance-athlete/] for tips on ensuring a well-balanced approach.
  • Focus on nutrient density. Make good quality food choices to help you get enough vitamins and minerals as well as carbohydrates, protein, fat and fibre. Try to eat fresh, minimally processed foods rather than too much packaged food, including 3-5 servings of vegetables and 2-3 pieces of fresh fruit each day.

If you are experiencing relative energy deficiency, avoid following approaches like fasted training, where the training benefits are likely to be outweighed by the pitfalls of inadequate calorie intake. I also suggest avoiding low carb-high fat diets (LCHF) due to potential adverse effects on thyroid hormones, particularly T3, which may slow down metabolism and impact on performance. It can also be difficult to obtain adequate calories from these types of diets due to the near exclusion of a whole food group – which is why they may be very effective for weight loss in people who are overweight – and the lack of carbohydrate may harm performance through a loss of metabolic flexibility, ie ability to utilise carbohydrate as fuel when required for high intensity efforts.

Conferences in Sport/Dance, Exercise Science and Medicine 2018

References

Raising Awareness of RED-S in Male and Female Athletes and Dancers Dr N. Keay, British Journal of Sport Medicine 2018

2018 UPDATE: Relative Energy Deficiency in Sport (RED-S) Dr N. Keay, British Journal of Sport Medicine 2018

Low energy availability assessed by a sport-specific questionnaire and clinical interview indicative of bone health, endocrine profile and cycling performance in competitive male cyclists. Keay N, Francis G, Hind K. BMJ Open Sport & Exercise Medicine 2018

Optimal health: including female athletes! Part 1 Bones Dr N. Keay, British Journal of Sport Medicine 2017

Optimal health: including male athletes! Part 2 Relative Energy Deficiency in sports Dr N. Keay, British Journal of Sport Medicine 2017

Optimal Health: Especially Young Athletes! Part 3 – Consequences of Relative Energy Deficiency in Sports Dr N. Keay, British Association of Sport and Exercise Medicine 2017

Mechanisms for optimal health…for all athletes! Dr N. Keay, British Journal of Sport Medicine 2017

The IOC consensus statement: beyond the Female Athlete Triad—Relative Energy Deficiency in Sport (RED-S) British Journal of Sports Medicine 2014

Nutritional considerations for vegetarian endurance athletes Jo Scott-Dalgleish, Endurance Sports Nutrition 2017

 

What has your gut microbiome ever done for you?

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Our body acts as a host to vast array of micro-organisms. Often, we are only aware of these micro-organisms causing unwanted infection: for example when a cut on the skin becomes infected, or we suffer with a bout of infective gastro-intestinal upset. Actually, this perception of the micro-organisms, living both on and inside, only causing unwanted infections is very biased. The microbiome (all the micro-organisms, their genetic material and metabolites produced) plays a vital role in keeping us healthy.

Recent research demonstrates that elite level cyclists host distinct clusters of microbiome communities when compared to controls which contribute to more effective metabolic pathways.

The gut microbiota consist of the range of micro-organisms living in our gut, mainly the colon. Recent research reveals that the diversity and functions of the gut microbiota have far reaching impact on health. For example, there is an important interaction between these micro-organisms and mitochondria, which are the organelles in cells responsible for producing energy. This cross talk is of particular consideration for athletes who seek to optimise energy production for training and competition. The gut microbiota also interact with the immune system and central nervous system function, including behaviour. There is evidence that the gut microbiota even influences brain development.

Microbiome Mitochondria Feedback

On the other side of the coin, any disruption in the beneficial types of gut microbiota have been linked to chronic disease states including obesity, metabolic syndrome and mental health issues. What causes imbalances in gut microbiota to produce such problems? A possible aetiology is a poorly balanced diet, or the side effect of medication which does not support the growth and function of beneficial bacteria. Rather an overgrowth of potentially harmful bacteria is favoured: dysbiosis. In athletes there is a condition know as “leaky gut” which can result from endurance training. In this scenario, blood is diverted away from the gut during exercise to the exercising muscles. After stopping exercise, blood flow is restored to the gut resulting in a mild reperfusion injury. This results in a slightly “leaky gut” so that unwanted bacteria in the gut are able to pass into the body and provoke an inflammatory response. Equally this situation can also mean desirable nutrients in the gut as less well absorbed. Although a degree of inflammatory response supports desirable adaptations to exercise, clearly an over-response will be counter productive to improving sports performance.

The gut microbiota have been reported to regulate immune function. Athletes in heavy training can experience suppressed functional immunity so any strategies to support the gut microbiota will potentially be beneficial in preventing infection.

What can you do to support a beneficial gut microbiota to support health and sport performance?

  • Try to include at least one fermented food source in your diet every day to boost your probiotic bacteria. Try sourdough bread, yogurt, kefir (similar to yogurt), sauerkraut, kimchi (Korean fermented vegetables), tempeh and miso (fermented soya products) and kombucha (fermented teas). These products can be found in health food shops and are becoming more widely available in some supermarkets and lunch places.
  • Regularly eat pre-biotic foods like garlic, onion, leeks, chickpeas, beans and lentils. These provide fuel for your probiotic bacteria, enabling them to proliferate.
  • Have adequate fibre in your diet from a wide variety of plant foods: eg wholegrains, legumes, vegetables, fruits, nuts, seeds. Dietary fibre is fermented by your probiotic bacteria to produce short chain fatty acids (SCFAs) which play a key role in keeping your gut healthy.
  • Consume foods and drinks rich in polyphenols: eg berries, green tea, coffee, black tea, red wine, dark chocolate, apples. Polyphenols, found in many plant foods, have been shown to help increase probiotic bacteria in the gut.
  • Take a good quality, multi-species probiotic supplement during winter, heavy training blocks and when travelling abroad, especially for races. To find out more about the potential benefits of probiotic supplementation for athletes, see this blog by nutritional therapist Jo Scott-Dalgleish: http://www.endurancesportsnutritionist.co.uk/blog/probiotics-guide-endurance-athlete/

To find out more about the interaction between Health, Hormones and Human Performance come to the British Association of Sport and Exercise Medicine annual conference

References

Community characteristics of the gut microbiomes of competitive cyclists Microbiome August 2017

Ubiquitous Microbiome: impact on health, sport performance and disease

Endocrine system: balance and interplay in response to exercise training

Inflammation: Why and How Much? Dr N. Keay, British Association of Sport and Exercise Medicine 2017

Medically young, older athletes

Spot the differences?

Screen Shot 2017-04-05 at 14.22.03

You don’t have to be a Radiologist to see that there are some differences between the two X-rays above. Both are from adults of the same age 51 years. Female on left as you look at screen and male on right. In both cases, these adults would be described as “medically young”. Always physically active and reasonably accomplished as athletes in their respective sport disciplines. Never smoked, never overweight, good nutrition.

As discussed at the recent conference at the Royal Society of Medicine (RSM) on “Sports Injuries and Sports Orthopaedics” in the session on the “Ageing Athlete”, there are challenges for athletes in Masters’ age groups, including mechanical joint issues associated with increasing age.

Looking at the male X-ray on right there is small gap between femoral head (ball-like structure) and acetabulum (socket in which femoral head lies). This gap is where the articular cartilage reduces friction between articulating surfaces of this ball and socket joint. In contrast in female X-ray on left of screen, this gap is reduced as cartilage has been worn away so that on right hip (left as you look at screen) bone is grinding on bone. Ouch!

Look again at the femoral heads (ball like structures). In the male these have smooth contours and are symmetrical on both sides. In contrast, in the female there is marked asymmetry with squashed appearance on right side (left of screen) of the femoral head with honeycomb appearance suggesting that there is cyst formation and impaction into socket of joint. This results in shorter leg and weakness of the bone architecture so more likely to compress further. Strangely the blood supply to femoral head is retrograde, meaning it flows backwards from origin of supplying blood vessel to provide vital nutrients to bone, which is a living tissue. If this blood supply is disrupted then the bone dies (avascular necrosis) and become more fragile. The femoral neck (slim area below femoral head) where blood supply courses, has been telescoped down and looks stubby compared to opposite side in female.

Although in the female, the right hip aches and is stiff, it is actually the left hip (right as you look at screen) that hurts more, both at rest and when trying to exercise. Why? If you look carefully on the upper boarder of acetabulum (socket) you will see small cysts. I imagine that pain is caused when the synovial fluid (lubricating fluid) in joint is forced into exposed bone, in hydraulic action especially when moving the hip joint.

So what to do? Total hip replacement (THR) is the only feasible option for the female above, due to extensive damage to the hip joints. Why are some people more prone to this type of joint damage? Apart from underlying medical pathologies that damage joints, the nature of some types of exercise can contribute. For example Ballet is demanding on the hip joint in terms of range of movement and load bearing. The individual can also be predisposed in biomechanical terms to joint issues: in the female X-ray above the femoral head is more exposed than the male.

Although the perception is that THR is more for the elderly wishing to be able to walk to the shops, with improvements in materials and technology used in hip protheses, there are examples of young athletes successfully returning to previous pre-operative levels of exercise training without pain. Recently a 28 year old male soloist dancer of the Paris Opera Ballet had a THR and returned to professional dancing. The medically young athlete will probably have the required motivation and physical ability to rehab effectively. A house in the south of France with private pool and climate for rehab outside would certainly add to motivation. Nevertheless, return to dancing at a professional level in a top level Ballet company after THR is remarkable as classical dance requires a unique combination of outstanding strength, control, proprioception and flexibility. At the conference at the RSM, during the lecture on “Can I run after my hip replacement?” hip replacements in the medically young, active population were reported to have good success rate with athletes able to return to previous level of sport with predicted lifespan of replacement of up to 25 years. Of course every individual athlete should weigh up the pros and cons. Taking up a new impact sport would probably not be sensible. Delaying surgery too long, apart from increasing pain, can compromise biomechanics and therefore replacement outcome. On the other hand, any operation carries a risk, however small and THR requires extensive rehabilitation in order to return to sport.

Deciding on the timing of THR in medically young, older athlete is not straight forward, especially if considering your own hips. Ultimately in such a person, the decision to go for surgery is based on quality of life and limitation to current sport activity, combined with the desire to return to previous level of activity, without the pain. What would you do?

For further discussion on Endocrine and Metabolic aspects of SEM come to the BASEM annual conference 22/3/18: Health, Hormones and Human Performance

References

Successful Ageing Dr N. Keay, British Association of Sport and Exercise Medicine 2017

Conference: Sports Injuries and Sports Orthopaedics, Royal Society of Medicine, 18/1/17, Session “The Ageing athlete”. Including lectures on: “Can I run after my hip replacement? Current recommendations for impact exercise following joint replacement” Mr Konan and “Managing acute injuries in worn joints” Mr Oussedik