Current sports nutrition guidelines recommend that athletes only take supplements following an evidence-based analysis of their value in supporting training outcomes or competition performance in their specific event. While there is sound evidence to support the use of a few performance supplements under specific scenarios (creatine, beta-alanine, bicarbonate, caffeine, nitrate/beetroot juice and, perhaps, phosphate), there is a lack of information around several issues needed to guide the practical use of these products in competitive sport. First, there is limited knowledge around the strategy of combining the intake of several products in events in which performance benefits are seen with each product in isolation. The range in findings from studies involving combined use of different combinations of two supplements makes it difficult to derive a general conclusion, with both the limitations of individual studies and the type of sporting event to which the supplements are applied influencing the potential for additive, neutral or counteractive outcomes. The repeated use of the same supplement in sports involving two or more events within a 24-h period is of additional interest, but has received even less attention. Finally, the potential for individual athletes to respond differently, in direction and magnitude, to the use of a supplement seems real, but is hard to distinguish from normal day to day variability in performance. Strategies that can be used in research or practice to identify whether individual differences are robust include repeat trials, and the collection of data on physiological or genetic mechanisms underpinning outcomes.
According to surveys and the experience of most sports nutrition professionals, there is a high prevalence of use of sports foods and supplements among competitive athletes . While there are some concerns associated with such observations, particularly around the indiscriminate use of performance supplements , many expert groups now take a pragmatic approach to the use of products and protocols which have passed a risk:benefit analysis of being safe, effective, and legal, while also being appropriate to the athlete’s age and maturation in their sport [2, 3]. Indeed, a number of supplements have received plentiful and insightful attention from sports scientists to produce robust evidence of the scenarios in which they can enhance sports performance. These include caffeine [4, 5], creatine monohydrate [6, 7], bicarbonate [8, 9], beta-alanine [10, 11], and beetroot juice/nitrate [12, 13].
While the evidence-base for the use of these products is generally sound, it typically produces a recommended protocol that is generic and isolated from other performance strategies that the athlete may also be implementing. Indeed, the laboratory situations in which most supplement studies are conducted often fail to include many of the important features associated with competitive sport. Earlier work identified a range of characteristics which should be included in investigations of strategies to enhance sports performance to allow them to be more easily applied to competitive athletes [14, 15]. These included using highly trained participants to whom the results are intended to apply, choosing performance protocols which mimic real-life sport, and incorporating other nutritional strategies or features according to the way they should be practiced in the targeted sport or event. Such features have been integrated into many recent investigations, including a number of field studies in which the effect of a performance supplement has been observed during simulated [16, 17] or actual  sporting events.
Despite these advances, there are several real-life issues related to the use of performance supplements that remain relatively ignored. Poor interrogation of such issues makes it difficult for athletes to undertake a thorough risk:benefit analysis of their potential use of a supplement or to implement a scenario-specific protocol for their product use that is truly evidence-based. These issues included the additive and interactive effects of combining the use of several performance supplements for a single event, considerations regarding the repeated use of a performance supplement within a relatively brief period, and the notion of individual responsiveness to supplement use. The aim of this review is to examine our current state of knowledge around these issues. It will focus on the performance supplements which were previously identified as enjoying strong support for their benefits to the performance of a single competitive event. In addition, phosphate will be considered in view of the emerging information about its potential benefits to sports performance  as well as the existence of several studies of its combined use with other evidence-based supplements. Protocols of use and mechanisms of action of these supplements are summarized in Table 1 to provide a backdrop to these discussions.
Additive and Interactive Effects of the Use of Combinations of Performance Supplements
Many studies of supplementation practices in sport note that athletes report the simultaneous use of a number of different products [20–22]. Undoubtedly, some athletes practice indiscriminate polypharmacy, consuming large numbers of products without apparent consideration of the cumulative quantity and range of ingredients that are ingested . However, the current review focusses on the deliberate combination of several supplements in a competition setting with the goal of optimizing performance benefits via an additive effect or positive interaction. It consciously excludes discussion of the growing number of multi-ingredient performance supplements which involve a blend of ingredients (sometimes up to 30 individual substances) due to a number of concerns. Many multi-ingredient performance supplements represent a practical risk for athletes because of their (sometimes undeclared and large) content of stimulants and/or banned substances [23, 24], failure to provide effective doses of evidence-based ingredients, or failure to disclose ingredients by claiming protection of their “proprietary blend.” As such they are problematic in relation to health, doping safety, and efficacy/value for money . Although studies of the performance effects of commercially available multi-ingredient supplements can be found in the literature [25–27], the results of such investigations are typically confounded by methodological flaws such as comparison to a single placebo or lack of independent verification of the product contents. Since these factors prevent detectable effects from being attributed to a single ingredient or allow interaction between ingredients to be isolated, they cannot contribute to the focus of this review.
Supplements can enhance the outcome of a competitive event if they reduce or delay the onset of the specific physiological factors that would otherwise cause fatigue or decay in performance throughout the event or towards its conclusion. Potential benefits could occur via mechanisms such as increased substrate availability, reduced perception of pain or effort, the buffering of disturbances in cell homeostasis such as changes in muscle pH and/or an increase in the efficiency of muscle contraction. In some sporting events, a number of these conditions or ergogenic opportunities occur, therefore, it is not surprising that several different supplements may be of benefit when used in isolation (see Table 1). The use of a combination of supplements for a single event can occur in several ways: the simultaneous use of several products with individual benefits in the acute scenario of the event, or the acute use of supplements in conjunction with a chronically applied supplement used to support training outcomes. A range of possible outcomes of the addition and interaction of supplements can be identified (see Table 2).
The studies located for this review were sourced via a thorough literature search of Medline and Google Scholar databases, as well as the reference lists from the sourced papers. Search terms for the database search were “supplement,” “caffeine,” beta-alanine,” “bicarbonate,” “creatine,” “nitrate,” “beetroot juice,” “phosphate,” “sport,” “performance,” “combination,” “interaction,” and “additive.” Papers were included in the featured analysis (Table 3) if they met each of the following three criteria: recruitment of athletes undertaking specific training for a sport/event, the single and combined application of the selected performance, and implementation of protocols that are applicable to the conduct and outcomes of a sporting event. Due to the scarcity of studies, some lenience was shown in the case of the performance protocol. Table 3 summarizes the available studies that met these criteria and includes information about the specific implementation and outcomes of the supplementation protocols as well as an indication of any apparent interactions.
Even when the focus is restricted to a few supplements and the specific scenarios in which there is evidence-based justification of their use, a large number of permutations of supplement use combinations can be identified. Therefore it is not surprising that the current literature, which is relatively recent, fails to cover much of the potential interest. Furthermore, the literature presents an ad hoc collection of studies rather than a systematic coverage of key supplement interactions and is limited by the presence of methodological flaws in some studies. Nevertheless, a number of themes can be identified. Almost all of the available studies involved the investigation of the single or combined benefits of two performance supplements. Indeed, a systematic investigation of the interactions between three or more supplements used is understandably challenging, even though Table 1 identifies that such use could be justified in some sports/events. For example, each of the six performance supplements included in this review, when used in isolation, could theoretically provide a benefit to the preparation (beta-alanine, creatine) or performance (caffeine, beta-alanine bicarbonate, nitrate, phosphate) of a 4000-m track cycling pursuit, 400-m swim, or 2000-m rowing race. A sophisticated approach to field testing or research methodology would be needed to identify the optimal protocol for combining the use of some or all of these supplements.
To date, the most commonly studied combination of performance supplements has been bicarbonate and beta-alanine [28–33]; this represents an example of substances that might interact via a related mechanism of action in enhancing the muscle’s ability to buffer high rates of production of hydrogen ions (H+) (Table 1). The available literature, summarized in Table 3, involves variability in the types of athletes, protocols of supplement use, and measures of sporting performance included in investigations. Not surprisingly, there are a variety of observations ranging from neutral and positive effects on performance from each of the supplements individually, and interactions including counteractive, neutral, and additive (see Table 2). The lack of consistency in outcomes can be attributed partially to limitations in study designs including small sample sizes and the further loss of statistical power due to the need for a parallel group application of the chronic protocol of beta-alanine supplementation. However, the benefit of either supplement or their combined use is also likely to be dictated by the type of sporting event and the degree to which performance is limited by excessive acidosis.
Caffeine and bicarbonate have also received some attention as supplements that might be used in tandem for sporting events involving high-intensity exercise [34–38], with the separate effects of reduced perception of effort and enhanced buffering being able to combine to further enhance performance. Again, the literature shows a lack of consistency in findings, with observations of positive, neutral, and possibly negative outcomes from the individual substances, and a range of additive, neutral, and counteractive effects when they are used in combination (Table 3). Although one study involving a sports specific (judo) performance protocol has reported that the small and unclear positive effects of each supplement in isolation could be combined to produce a significant benefit , it appears there is also a potential for one product to cancel the need for the other when both are individually valuable. For example, whereas caffeine and bicarbonate supplementation protocols were both successful in improving the performance of a 3-km cycling time trial when used in isolation, there were no further benefits from their combined use . The mechanism of the performance enhancement with the bicarbonate-caffeine trial was not evident in this study so the nature of the interaction of these supplements remains unclear. However, interactions in other studies include a counteractive response of the positive effects of caffeine due to gastrointestinal disturbances arising from bicarbonate use , but also a beneficial effect of using bicarbonate to address greater acidosis associated with a faster effort due to caffeine support . Here again, the scarcity of studies makes it difficult to derive a general conclusion, with both the limitations of individual studies and the type of sporting event to which the supplements are applied governing the potential for misunderstanding the literature and drawing context specific outcomes, respectively.
Other supplement combinations that have received some attention in the literature include the pairing of nitrate/beetroot juice with caffeine [39, 40] or phosphate . In each case there has been a failure to see a benefit from the nitrate supplementation but an enhancement by the other performance supplement and a slight [39, 40] to apparent  reduction in the benefit of the combined supplementation protocol. While the former may simply be a quirk of the statistical analysis in a small sample size, there may be some interaction that requires further investigation. Similar findings regarding the combination of caffeine and phosphate [42, 43] also merit additional research.
Finally, although no publications sufficiently fitted the criteria around sports performance to be included in the targeted review in Table 3, the combination of creatine and caffeine supplements has received some attention. Although these supplements achieve performance benefits via independent mechanisms, previous reports indicated that the simultaneous use of caffeine and creatine (usually in the form of repeated use of both supplements over several days) caused a loss of the ergogenic properties of enhanced phosphocreatine stores [44, 45]. This outcome was attributed to opposing effects of the two supplements on muscle relaxation time [44, 45], although gastrointestinal effects from the acute intake of the combination of products were also reported, separately [46, 47]. However, more recent investigations of chronic creatine supplementation have reported that the acute addition of caffeine prior to a protocol of exercise capacity or performance does not impair the improvements due to caffeine supplementation [48–50]. Although additional sports-specific research on this combination of performance supplements is required, at present there does not seem to be good evidence to prevent athletes from using both of these products in their appropriate scenarios. Furthermore, in general summary on this topic, the combined use of performance supplements is a fertile area of research that requires robust investigation, with a call for careful choice of methodological design to enable clear outcomes to be produced.
Repeated Use of Supplements
In many sports, competition outcomes are decided through a series of heats and finals, stages in a race or games in a tournament. In other sports, gifted athletes may compete in more than one event in the competition program: for example, Michael Phelps raced 17 times over the 8-day program in which he won eight gold medals at the 2008 Beijing Olympic Games. In some cases, the interval between bouts is measured in hours and may fall within the half-life of a supplement or the body’s return to normal physiological status or homeostasis following the event. Whether the use of an acutely applied supplement known to enhance performance of an event can be repeated for a subsequent event with the same efficacy is therefore of practical importance to competitive sport. At least three different issues might need to be considered in the repeated use of a supplement (see Table 2). The carryover of the first dose to the subsequent event could lead to a modified second protocol, with possibilities ranging from a reduced dose (i.e., if there is still some presence from the first dose that needs to be topped up), to no use (i.e., the supplement is still exerting its full physiological effect in this time frame) as well an increased dose (i.e., if desensitization to the supplement requires a larger amount to achieve the same effect). Whether the use of the supplement for the first event allows a greater physiological effort with undesirable fatigue is also of consideration and may require special pacing strategies for the first event or a decision to use the supplement only for the subsequent (and possibly more important) competition bout.
A thorough literature search, adding the terms “repeated use,” “serial use,” and “subsequent use” to the search terms, was completed to identify sports-specific studies of the previously identified performance supplements that are acutely used (caffeine, bicarbonate, and beetroot juice/nitrate). The case of phosphate loading merits special mention since its application is neither acute (i.e., having a well-established protocol of use targeting a single occasion) nor chronic (i.e., requiring a period of more than several days to achieve the physiological goal and maintaining this status for weeks-months) as is the case for creatine and beta-alanine. Indeed, optimal protocols for the application of phosphate loading to sports performance are still being developed, but at the present time, they consist of 3–5 days of loading with the possible but unconfirmed maintenance of effects for several days . Therefore, there is insufficient information on which suggestions regarding use for repeated competitive events can be based.
The sparse literature on repeated use of well supported performance supplements is summarized in Table 4. Although there is only one specific study regarding the use of caffeine in a simulated two day sporting competition , there are several topical themes around serial use of this common dietary ingredient. Previously, the enhancement of exercise capacity associated with caffeine was believed to be reduced by habitual use, necessitating withdrawal from caffeine for several days to achieve a state of caffeine naivety for both the rigor of scientific study and the optimization of competition benefits . An extension of this belief would predict a diminished return for repeated caffeine use in multi-day competitions. Although we now know that caffeine withdrawal does not enhance the magnitude of performance benefits associated with caffeine supplementation , the repeated use of caffeine over multi-day sporting events raises other issues. These include the carryover of additional fatigue or muscle damage from the increased effort made possible by caffeine use on the first day, as well as interference with sleep patterns. The effects of performance-related caffeine use on sleep quality and recovery during multi-day competition has not been systematically studied, although it has been identified as a contributor to problems in other sporting situations (e.g., impaired recovery from night matches in team sports [53, 54]). Furthermore, there are anecdotal reports of cyclical use of caffeine and sleeping tablets in some multi-day competitions as athletes seek to counter the effects of each drug [55, 56]. Further research is needed to both identify and investigate such patterns objectively, and to remove the confounding variables that may otherwise affect sleep architecture such as competition arousal, high-intensity exercise and alterations in daily routines. In the meantime, the only available study of repeated use of caffeine in a simulated competition scenario  found that modest (3 and 4.5 mg/kg) doses, as recommended in current guidelines for caffeine use in sport, were associated with consistent and significant performance benefits (4–5% enhancement of work done in a cross country skiing time trial) when implemented on two occasions, 24 h apart (Table 4). This benefit occurred despite increased muscle damage and soreness from the first bout undertaken with caffeine, attributed to the greater exercise effort; presumably, the use of caffeine on the second occasions was able to mask these effects .
The only sports-specific study involving beetroot juice supplementation focused on the schedule for the team pursuit track cycling event on the London Olympic Games Program and involved different protocols that might be implemented for the semi-final and final races, separated by a 75-min interval . One treatment provided beetroot juice concentrate 2.5 h before the first cycling bout (4 min time trial), another delayed it until 2.5 h before the second time-trial, while the third active treatment involved a full dose prior to the first time trial, with a half dose “top up” immediately afterwards (Table 4). A limitation of this study, recognized in light of more recent work, is that the beetroot juice doses would now be considered too low to achieve clear and optimal effects, especially in high caliber athletes . However, it is noted that in comparison to the placebo trial, all beetroot juice trials appeared to provide a small but unclear improvement of the first time-trial but a potential negative effect in the second bout, perhaps due to residual fatigue from the extra demands of the initial effort . Clearly, further work is required around the repeated use of beetroot juice as well as the potential for a carryover effect from performance bouts.
Finally, repeated use of bicarbonate supplementation has been studied in several sports-specific study designs, simulating a successive day use in a swimming carnival  or repeated use in a rowing regatta where races may be separated by 48 h . Both studies (see Table 4) used the serial bicarbonate loading protocol in which 300–500 mg/kg of bicarbonate is taken daily in split doses to chronically elevate plasma bicarbonate concentrations . Although the principle underpinning this strategy is to allow the bicarbonate loading protocol to finish the day before competition, reducing the risk of gastrointestinal distress on the day of the event, it may also have relevance to multi-day or repeated events. Both studies failed to detect a positive effect of bicarbonate loading on either of the performance bouts, although issues with the caliber of athletes and the dosing protocol may have interfered with the potential of bicarbonate loading to enhance performance under these conditions. Indeed, a study involving the repetition of acute bicarbonate loading for five consecutive days reported that the benefits to high-intensity cycling were maintained over this period . Therefore, there is merit in further investigation.
Individual Responses to Supplement Use
The phenomenon of individual responses to supplement use is demonstrated by the life experience that there are two types of people in the world; those who drink coffee after 4 pm and those who would be awake all night if they did. Such (true) individual differences create a few challenges in research and real-life sports nutrition practices. First, they may interfere with the outcomes of a scientific investigation, masking the true potential of the supplement intervention to alter metabolism or performance. Because sport science research traditionally involves small sample sizes, the presence of one or two outliers or contrary responders within a group can render the mean finding from the intervention using probability statistics as a non-significant outcome. This may be compounded by the publication bias or reduced interest in studies that fail to find a clear or positive effect from the applied intervention ; preventing the fate of the majority of subjects who reported a potentially useful change from reaching the public domain. A second challenge awaits the expert panels who try to develop guidelines regarding sports nutrition—how definitive can they be when it is apparent that athletes do not all respond in the same way? And finally, there is the concern of each athlete and coach who wants to use their finite time and resources wisely; how can they know even in the case of performance supplements that have received broad scientific support if their own experience will be positive, negative or neutral? A number of important issues in distinguishing real differences in response and characteristics of athletes which might underpin such differences will now be explored.
Challenges in Determining Real and Meaningful Responses to a Performance Supplement
Several recent trends in the reporting of studies of performance supplements are of relevance to the current review: the provision of individual results within group data for performance outcomes, and commentary around the significance of these results in terms of typical outcomes of real-life sporting competitions. To demonstrate several common misconceptions around these practices, Fig. 1 provides a fictional example with a simplistic account of the practical implications of the data. It is beyond the scope of this paper to fully review this topic, however, a brief explanation of the problem lies with the failure of researchers (and, presumably, readers) of such analyses to take into account the intrinsic variability in sports performance. The first error in interpretation involves the challenge of distinguishing the change in performance due to the use of the supplement from the normal day to day variability in exercise outcomes. Indeed, in the absence of any other data or context to the reliability of performance measures, it would be unwise to speculate on the cause of any performances differences/changes observed in the study.
The second misunderstanding is that the small inter-competitor differences in real-life sport, i.e., the narrow margins that thrill the spectators at competitive events—set the bar for the magnitude of change that a supplement needs to achieve to be considered effective. It is tempting to think that an athlete needs only to improve by the fractions of seconds or millimeters that frequently determine podium recognition to make the investment in a supplement worthwhile. Yet, as has been eloquently explained by sports statisticians , the within-individual differences in sports performance are equally important; these often overlap such that the re-running of many events would likely lead to a different outcome without any intervention being applied.
After modeling the results of a range of sports [14, 61], Hopkins et al. suggest that “worthwhile” changes to the outcome of most events require a performance difference equal to approximately 0.3–0.5 times the variability (coefficient of variation [CV]) of performance for that event. Furthermore, across a range of events the CV of performance of top athletes is usually within the range of 0.5–3%, with some variability according to the type of event and the caliber of the performer . However, an improvement of ~0.3–0.7 of the event CV does not guarantee a clear movement of the athlete from finalist to winner; rather, it may simply increase their likelihood of winning by an absolute increase of ~10–20% (for example, improving from a 40% chance of winning to a 50–60% chance) . Such a difference is still outside the realm of detection using probability statistics with the sample sizes normally associated with supplement studies in sports science. Nevertheless, scientists can interpret their results meaningfully by reporting the outcome as a percentage change in the measure of athletic performance and using 90–95% confidence limits to describe the likely range of the true effect of the treatment on the average athlete represented in the study . Despite some dissent on the topic , many applied sports scientists find the use of magnitude-based inference techniques, which provide qualitative determinations of the significance of the likely true chance in terms of real-world significance, to be valuable [14, 61, 62, 64].
Now that tools for better examining the overall effect of a performance supplement have been determined, there is opportunity to focus on strategies to differentiate true differences in response to supplements and day to day variability in performance. A logical starting point is consideration of characteristics that might underpin some of the common differences in response.
Effect of Sex on Responses to Supplements
Males and females differ in many ways that are important for sports nutrition outcomes—for example, differences in body size and body composition, and differences in hormonal profiles that affect metabolism. Although early sports nutrition guidelines featured recommendations in absolute amounts (e.g., an athlete should consume 50 g of carbohydrate after exercise), more recent statements have tried to reflect that a 45-kg female runner may have different needs or responses to a 90-kg male rower. Thus, just as macronutrient targets are now often given relative to body mass (BM) or fat free mass (e.g., an athlete should consume carbohydrate equivalent to 1 g/kg BM after the event), in many cases, doses of supplements are also scaled to body size (e.g., caffeine dose of 3 mg/kg, bicarbonate dose of 300 mg/kg) [4, 9].
Whether the hormonal characteristics of the female athlete and their fluctuations over the menstrual cycle, known to have measureable effects on physiology, create differences in the responsiveness of females to supplement strategies is of interest. In most cases, the literature on sports-specific uses of performance supplements has been largely undertaken with male subjects and research that directly compares male and female responses to interventions is sparse. Although some studies have reported apparent differences in male and female athletes to caffeine supplements [65, 66], issues such as a greater risk of gastrointestinal disturbances during exercise in females and difficulties in matching the athletic caliber and reliability of performance between groups of male and female athletes must also be taken into account in interpreting the results. Despite gaps in the evidence base regarding sex differences with respect to supplement use, we generally believe that female athletes respond similarly to their male counterparts when circumstances are matched.
Effect of Training Status and Athletic Caliber on Response to Supplements
Most sports nutrition studies are undertaken on participants who range in caliber/training history from recreational to well-trained. Indeed, very few studies are undertaken on world-class athletes. There are suspicions, based on testimonials and some literature, that elite and highly trained athletes may respond differently to some sports nutrition strategies than their lesser trained or less successful counterparts. This issue has been recently examined in relation to beetroot juice/nitrate supplements, where it has been proposed that they may be less effective in enhancing the performance of elite competitors than lower level athletes .
As usual, there are issues with the robustness of the available literature that can make it dangerous to make firm conclusions. Nevertheless, there is evidence to support the hypothesis within from single studies in which the benefits of supplementation were inversely correlated with maximal aerobic capacity , as well as from a meta-analysis of studies which showed greater effect sizes of performance enhancement with lower caliber athletes . Furthermore, there are credible explanations of how highly competitive sports people might differ from the rest of the athletic population due to the effects of years of training adaptations or the genetic differences that have selected them to be so suited to perform in their event. For example, it has been speculated that compared to moderately trained individuals, elite athletes have a different muscle fiber type composition, greater muscle capillarization and adaptation which reduce the development of hypoxia and metabolic acidosis, and a more developed pathway to produce nitric oxide from arginine; these conditions may reduce the benefit of an enhanced activity of the nitrate-nitrite-nitric oxide pathway .
Do these findings mean that elite athletes should not bother to experiment with beetroot juice supplements? A considered cost:benefit analysis finds that many sports scientists would err on the side of the potential benefits . Given that “responders” are still apparent in studies involving elite cohorts and few side-effects other than pink urine/stools following beetroot juice ingestion have been reported, nitrate consumption may still be a useful nutritional strategy for high-caliber athletes . The efficacy of this strategy is likely to be associated with the specific conditions of the sporting event. Shorter, high-intensity events may benefit more due to the greater hypoxic and acidic stress favoring the nitrate-nitrite-nitric oxide pathway and the relatively greater involvement of type II fibers. In particular, the localization of these conditions in smaller muscle groups may favor effects during upper-body dominant exercise , explaining observations of benefits to competitive athletes in kayaking and rowing [70, 71]. Applying this strategy to situations of hypoxia, such as altitude training or competition in high altitude environments (e.g., cross-country skiers, mountainous cycling stages) where O2 availability is challenged also bears consideration and further study . Therefore, even if there is general evidence that nitrate supplementation is valuable to lesser trained or lower caliber athletes, there are perhaps certain sports, events and conditions where it may assist elite competitors .
True Individual Responses Including Genetic Differences
In any supplementation study, the performance outcomes will include a mixture of results around the mean effect, with the experience of some participants clustering around the “typical” response and other subjects showing a greater or lesser response. Depending on the magnitude and direction of the mean effect, the absolute changes seen among individuals might span from a negative effect through to a very large performance gain. The occurrence of side-effects can also be an individual experience. Although some of these observations can be attributed to random day to day variability in performance which occurs even in the face of attempts to standardize or minimise extraneous variables, there is also the possibility that some of differences are robust and reproducible.
Real differences in responsiveness to a supplement can arise due to a number of factors. These include differences in background nutritional status; for example, creatine loading achieves greater increases in muscle creatine stores in vegetarians than omnivores, associated with their lower starting/baseline stores . Furthermore, caffeine supplementation produces a smaller benefit in endurance protocols in which carbohydrate availability is high (i.e., when carbohydrate is consumed during the exercise protocol compared with placebo/water) . However, there is growing interest in, and awareness of, genetic differences which may also account for variability in responsiveness to a range of interventions. In the general health and nutrition literature, we now appreciate that well-known differences in reactions to the intake of caffeine (an adenosine antagonist) can be explained by differences in the type, number, and site of adenosine receptors around the body, as well as differences in liver metabolism of caffeine which alter its half-life . There is emerging evidence that genetic differences affect caffeine’s ability to enhance sports performance. A study of 36 competitive cyclists subdivided the group according to their expression of a single nucleotide polymorphism of a gene associated with cytochrome P450 (CYP1A2), a family of proteins involved in hepatic metabolism of drugs [75, 76]. Overall, the 16 athletes who were AA homozygotes of this gene achieved a 4.7% improvement in 40-km time (75.1 ± 6.1–71.6 ± 4.3 min, p < 0.05), the 19 athletes who carried the C allele achieved only a trend to a performance benefit (73.1 ± 4.5–71.6 ± 4.4 min, non-significant difference). Although this research is in an embryonic phase, it is likely that future work will target the influence of various gene polymorphisms on metabolism of caffeine and other performance supplements and confirm anecdotal observations of differences in the effectiveness of these products.
A final issue in conducting research on performance supplements is to identify techniques that can confirm the presence of individual responsiveness to a sports nutrition intervention. As in all robust research, the starting point is to control study conditions so that the supplement intervention is the only variable that is changing, and to choose or practice a performance outcome to achieve high and known levels of reliability. Such conditions may provide a stable background against which biochemical or physiological markers correlated with the supplement and the change in performance can be clearly detected, and meaningful differences between individuals noted. For example, in a study of creatine supplementation, five of eight subjects showed a meaningful increase in work completed in a repeated sprint cycling test . Examination of muscle substrates identified a significant correlation between the increase in muscle creatine content and the change in work achieved during the cycling test, and showed that only the five “responsive” cyclists achieved a substantial increase in total creatine content as a result of the rapid loading protocol. In a separate study of bicarbonate loading, researchers found that the benefits to high-intensity cycling capacity were associated with both the absence of gastrointestinal symptoms and the magnitude of pre-post exercise changes to plasma pH, base excess and bicarbonate . Studies which include large numbers of subjects and undertake co-variate analysis of various characteristics including genetic profiling or physiological parameters can provide a sophisticated (albeit resource-intensive) opportunity to investigate individual responsiveness.
A simpler strategy is to undertake repeated interventions of the strategy within the trial to investigate the robustness of the response. Studies undertaken by Spriet et al. on caffeine supplementation have achieved this in various ways. An early study of exercise capacity in well-trained runners  involved four separate trials in which subjects consumed 9 mg/kg caffeine or a placebo 1 h before either a run or a cycle to exhaustion at 85% of their maximal aerobic capacity (VO2max). Although the study was focused on effect of caffeine on exercise metabolism and capacity rather than individual responses to this performance supplement, the authors noted that one of the seven subjects showed a consistent and markedly reduced response to the caffeine treatment compared with the other subjects (see Fig. 2). In a more recent study of the effect of low to moderate caffeine doses on performance, well-trained cyclists performed four randomized trials involving placebo, 100 mg, and 200 mg caffeine doses, plus a repeat of one of these trials . Such research design provides confidence in its observations of both the overall benefits of the caffeine treatment as well as any potential differences between subjects.
Within real life practice, high performance athletes who receive sports science support may have access to information about their signature responses to supplement interventions to enable them to identify successful strategies or tweak characteristics. For example, the athlete may be able to track blood pH and bicarbonate levels following bicarbonate loading strategies to optimize the right timing and dose to achieve an ergogenic benefit in a sustained high-intensity event. In the future, it may become possible to receive a genetic profiling report that could identify potential responsiveness to different kinds of strategies. For the moment, the most pragmatic way for an athlete to investigate a sports nutrition intervention is to consider best practice guidelines as a starting point that will cover most individuals. Further to this, they may identify if they are a non-responder or responder to the intervention via trial and error, aided by standardized application and systematic reporting of the outcomes of their activities.
The use of evidence-based performance supplements may form a small but important part of an athlete’s nutrition plan to maximize the outcomes of training and optimize competition performance. Athletes who are interested to use such supplements are advised to make decisions on several accounts, including the evidence that this will be of specific benefit to their event. However, despite advances in sports nutrition research to improve the methodological rigor of supplement studies, the applicability of such interventions to competitive sport, and the practical interpretation of the results, there are still several issues that remain relatively unexplored. A major real life interest is whether there are additive and/or interactive effects from combining the use of several supplements, based on evidence that each supplement provides a benefit to the event in question when used in isolation. Indeed, there are many justifiable proposals for combinations and permutations of well-supported performance supplements, such as bicarbonate, beta-alanine, creatine, caffeine, nitrate, and phosphate, based on the literature around their individual uses. Some of the potential combinations that could be justified and, indeed, observed in practice within the athletic community, are potentially too complex to be systematically studied in a conventional research design.
The small number of sports-specific studies which have investigated the combination of two of these supplements, in a scenario in which additive benefits might be predicted, have reported a range of outcomes including positive, neutral, or counteractive effects. This range of outcomes may reflect methodological issues (under-powered sample sizes, sub-optimal protocols of supplement use, poor reliability of performance) or differences in the ability of the performance protocol/scenario to achieve a physiological/biochemical challenge of sufficient magnitude to be addressed by the supplements. Further work is needed to add to this body of literature before clear messages can be identified about successful combinations of supplements and when they might be used.
A second issue that has received even less attention arises in sports in which multiple events are carried out within reasonably short periods to decide the final outcome of the event, and in which the athlete might desire to repeat the use of an evidence-based performance supplement. The sparse literature on this issue suggests that there is a range of potential considerations around the successive use of supplements, including overlapping half-lives of the products, the accumulation of fatigue or the desensitization to the effect.
Finally, the issue of individual responsiveness to supplement use represents a challenge both to researchers of studies with small sample sizes and to the athlete who needs to make a decision about whether a product provides a benefit to his/her performance. Part of the bigger challenge of undertaking and interpreting research on sports supplements is to distinguish real and robust effects from the daily variability of performance. However, implementing rigorous standardization protocols and performance measures with high reliability can help to increase the “signal-to-noise” ratio and thus the ability to detect real and worthwhile effects. Other strategies include underpinning observations of performance changes with mechanistic measurements such as physiological or genetic characteristics, or undertaking repeat interventions on the same individual to investigate the consistency of the effect.
In summary, supplement use by athletes is wide-spread and potentially useful to sports performance. Therefore, sports nutrition research should tackle the important questions that athletes and coaches need to consider to make evidence-based decisions about if and how to use a specific product. The use of several supplements in combination and the use of same supplement over successive events provide examples of issues that require further investment with robust and practical research methodologies. Strategies to isolate the variability of benefits to individuals are also a topic for future interrogation.
Knapik JJ, Steelman RA, Hoedebecke SS, et al. Prevalence of dietary supplement use by athletes: systematic review and meta-analysis. Sports Med. 2016;46:103–23.
Burke LM, Cato L. Dietary supplements and nutritional ergogenic aids. In: Burke LM, Deakin V, editors. Clinical sports nutrition. 5th ed. Sydney: McGraw-Hill; 2015. p. 493–582.
Thomas DT, Erdman KA, Burke LM. Position of the academy of nutrition and dietetics, dietitians of canada, and the american college of sports medicine: nutrition and athletic performance. J Acad Nutr Diet. 2016;116:501–28.
Burke LM, Desbrow B, Spriet LL. Caffeine and sports performance. Champaign: Human Kinetics; 2013.
Spriet LL. Exercise and sport performance with low doses of caffeine. Sports Med. 2014;44S:175–84.
Buford TW, Kreider RB, Stout JR, et al. International Society of Sports Nutrition position stand: creatine supplementation and exercise. J Int Soc Sports Nutr. 2007;4:6.
Bemben MG, Lamont HS. Creatine supplementation and exercise performance: recent findings. Sports Med. 2005;35:107–25.
Carr AJ, Hopkins WG, Gore CJ. Effects of acute alkalosis and acidosis on performance: a meta-analysis. Sports Med. 2011;41:801–14.
Burke LM. Practical considerations for bicarbonate loading and sports performance. Nestle Nutr Inst Workshop Ser. 2013;75:15–26.
Blancquaert L, Everaert I, Derave W. Beta-alanine supplementation, muscle carnosine and exercise performance. Curr Opin Clin Nutr Metab Care. 2015;18:63–70.
Trexler ET, Smith-Ryan AE, Stout JR, et al. International society of sports nutrition position stand: beta-Alanine. J Int Soc Sports Nutr. 2015;12:30.
Hoon MW, Johnson NA, Chapman PG, et al. The effect of nitrate supplementation on exercise performance in healthy individuals: a systematic review and meta-analysis. Int J Sport Nutr Exerc Metab. 2013;23:522–3.
Jones AM. Dietary nitrate supplementation and exercise performance. Sports Med. 2014;44:S35–45.
Hopkins WG, Hawley JA, Burke LM. Design and analysis of research on sport performance enhancement. Med Sci Sports Exerc. 1999;31:472–85.
Burke LM. Caffeine and sports performance. Appl Physiol Nutr Metab. 2008;33:1319–34.
Lara B, Gonzalez-Millán C, Salinero JJ, et al. Caffeine-containing energy drink improves physical performance in female soccer players. Amino Acids. 2014;46:1385–92.
Del Coso J, Pérez-López A, Abian-Vicen J, et al. Enhancing physical performance in male volleyball players with a caffeine-containing energy drink. Int J Sports Physiol Perform. 2014;9:1013–8.
Del Coso J, Portillo J, Muñoz G, et al. Caffeine-containing energy drink improves sprint performance during an international rugby sevens competition. Amino Acids. 2013;44:1511–9.
Buck CL, Wallman KE, Dawson B, et al. Sodium phosphate as an ergogenic aid. Sports Med. 2013;43:425–35.
Baylis A, Cameron-Smith D, Burke LM. Inadvertent doping through supplement use by athletes: assessment and management of the risk in Australia. Int J Sport Nutr Exerc Metab. 2001;11:365–83.
Erdman KA, Fung TS, Doyle-Baker PK, et al. Dietary supplementation of high-performance Canadian athletes by age and gender. Clin J Sport Med. 2007;17:458–64.
Shaw G, Slater G, Burke LM. Supplement use of elite Australian swimmers. Int J Sport Nutr Exerc Metab. 2016;26:249–58.
Cohen PA, Travis JC, Venhuis BJ. A methamphetamine analog (N, α-diethyl-phenylethylamine) identified in a mainstream dietary supplement. Drug Test Anal. 2014;6:805–7.
Cohen PA, Travis JC, Venhuis BJ. A synthetic stimulant never tested in humans, 1,3-dimethylbutylamine (DMBA), is identified in multiple dietary supplements. Drug Test Anal. 2015;7:83–7.
Ormsbee MJ, Mandler WK, Thomas DD, et al. The effects of six weeks of supplementation with multi-ingredient performance supplements and resistance training on anabolic hormones, body composition, strength, and power in resistance-trained men. J Int Soc Sports Nutr. 2012;9:49.
Kreipke VC, Allman BR, Kinsey AW, et al. Impact of four weeks of a multi- ingredient performance supplement on muscular strength, body composition, and anabolic hormones in resistance-trained young men. J Strength Cond Res. 2015;29(12):3453–65.
Lowery RP, Joy JM, Dudeck JE, et al. Effects of 8 weeks of Xpand® 2X pre workout supplementation on skeletal muscle hypertrophy, lean body mass, and strength in resistance trained males. J Int Soc Sports Nutr. 2013;10:44.
Tobias G, Benatti FB, De Salles Painelli V, et al. Additive effects of β-alanine and sodium bicarbonate on upper-body intermittent performance. Amino Acids. 2013;45:309–17.
Ducker KJ, Dawson B, Wallman KE. Effect of β alanine and sodium bicarbonate supplementation on repeated-sprint performance. J Strength Cond Res. 2013;27:3450–60.
De Salles Painelli V, Roschel H, De Jesus F, et al. The ergogenic effect of β-alanine combined with sodium bicarbonate on high-intensity swimming performance. Appl Physiol Nutr Metab. 2013;38:525–32.
Mero AA, Hirvonen P, Saarela J, et al. Effect of sodium bicarbonate and β-alanine supplementation on maximal sprint swimming. J Int Soc Sports Nutr. 2013;10:52.
Hobson RM, Harris RC, Martin D, et al. Effect of beta-alanine, with and without sodium bicarbonate, on 2000-m rowing performance. Int J Sport Nutr Exerc Metab. 2013;23:480–7.
Bellinger PM, Howe ST, Shing CM, et al. Effect of combined β-alanine and sodium bicarbonate supplementation on cycling performance. Med Sci Sports Exerc. 2012;44:1545–51.
Felippe LC, Lopes-Silva JP, Bertuzzi R, et al. Separate and combined effects of caffeine and sodium-bicarbonate intake on judo performance. Int J Sports Physiol Perform. 2016;11:221–6.
Christensen PM, Petersen MH, Friis SN, et al. Caffeine, but not bicarbonate, improves 6 min maximal performance in elite rowers. Appl Physiol Nutr Metab. 2014;39:1058–63.
Kilding AE, Overton C, Gleave J. Effects of caffeine, sodium bicarbonate, and their combined ingestion on high-intensity cycling performance. Int J Sport Nutr Exerc Metab. 2012;22:175–83.
Carr AJ, Gore CJ, Dawson B. Induced alkalosis and caffeine supplementation: effects on 2,000-m rowing performance. Int J Sport Nutr Exerc Metab. 2011;21:357–64.
Pruscino CL, Ross ML, Gregory JR, et al. Effects of sodium bicarbonate, caffeine, and their combination on repeated 200-m freestyle performance. Int J Sport Nutr Exerc Metab. 2008;18:116–30.
Glaister M, Pattison JR, Muniz-Pumares D, et al. Effects of dietary nitrate, caffeine, and their combination on 20-km cycling time trial performance. J Strength Cond Res. 2015;29:165–74.
Lane SC, Hawley JA, Desbrow B, et al. Single and combined effects of beetroot juice and caffeine supplementation on cycling time trial performance. Appl Physiol Nutr Metab. 2014;39:1050–7.
Buck CL, Henry T, Guelfi K, et al. Effects of sodium phosphate and beetroot juice supplementation on repeated-sprint ability in females. Eur J Appl Physiol. 2015;115:2205–13.
Kopec BJ, Dawson BT, Buck C, et al. Effects of sodium phosphate and caffeine ingestion on repeated-sprint ability in male athletes. J Sci Med Sport. 2016;19:272–6.
Buck C, Guelfi K, Dawson B, et al. Effects of sodium phosphate and caffeine loading on repeated-sprint ability. J Sports Sci. 2015;33:1971–9.
Vandenberghe K, Gillis N, Van Leemputte M, et al. Caffeine counteracts the ergogenic action of muscle creatine loading. J Appl Physiol. 1996;80:452–7.
Hespel P, Op’t Eijnde B, Van Leemputte M. Opposite actions of caffeine and creatine on muscle relaxation time in humans. J Appl Physiol. 2002;92:513–8.
Quesada T, Gillum T. Effect of Acute creatine supplementation and subsequent caffeine ingestion on ventilatory anaerobic threshold. J Exerc Physiol Online. 2013;16:112–20.
Trexler ET, Smith-Ryan AE, Roelofs EJ, et al. effects of coffee and caffeine anhydrous intake during creatine loading. J Strength Cond Res. 2016;30:1438–46.
Doherty M, Smith PM, Davison RC, et al. Caffeine is ergogenic after supplementation of oral creatine monohydrate. Med Sci Sports Exerc. 2002;34:1785–92.
Lee CL, Lin JC, Cheng CF. Effect of caffeine ingestion after creatine supplementation on intermittent high-intensity sprint performance. Eur J Appl Physiol. 2011;111:1669–77.
Lee CL, Lin JC, Cheng CF. Effect of creatine plus caffeine supplements on time to exhaustion during an incremental maximum exercise. Eur J Sport Sci. 2012;12:338–46.
Stadheim HK, Spencer M, Olsen R, et al. Caffeine and performance over consecutive days of simulated competition. Med Sci Sports Exerc. 2014;46:1787–96.
Irwin C, Desbrow B, Ellis A, et al. Caffeine withdrawal and high-intensity endurance cycling performance. J Sports Sci. 2011;29:509–15.
Nédélec M, Halson S, Abaidia AE, et al. Sleep and recovery in elite soccer: a critical review of the literature. Sports Med. 2015;45:1387–400.
Fullagar HH, Skorski S, Duffield R, et al. Impaired sleep and recovery after night matches in elite football players. J Sports Sci. 2016;34:1333–9.
Smith W (2012). Stilnox cost Grant Hackett Gold at Beijing, coach reveals. The Australian. http://www.theaustralian.com.au/sport/stilnox-cost-grant-hackett-gold-at-beijing-olympics-coach-reveals/news-story/79fff8d53d9cf59197f06d87504424f9. Accessed May 10 2016.
Racik G. AOC confirms ban on sleeping tablet. The Age. http://www.theaustralian.com.au/sport/stilnox-cost-grant-hackett-gold-at-beijing-olympics-coach-reveals/news-story/79fff8d53d9cf59197f06d87504424f9. Accessed 10 May 2016.
Hoon MW, Hopkins WG, Jones AM, et al. Nitrate supplementation and high-intensity performance in competitive cyclists. Appl Physiol Nutr Metab. 2014;39:1043–49.
Joyce S, Minahan C, Anderson M, et al. Acute and chronic loading of sodium bicarbonate in highly trained swimmers. Eur J Appl Physiol. 2012;112:461–9.
Mueller SM, Gehrig SM, Frese S, et al. Multiday acute sodium bicarbonate intake improves endurance capacity and reduces acidosis in men. J Int Soc Sports Nutr. 2013;10:16.
Song F, Parekh S, Hooper L, et al. Dissemination and publication of research findings: an updated review of related biases. Health Technol Assess. 2010; 14:iii, ix–xi, 1–193.
Malcata RM, Hopkins WG. Variability of competitive performance of elite athletes: a systematic review. Sports Med. 2014;44:1763–74.
Batterham AM, Hopkins WG. Making meaningful inferences about magnitudes. Int J Sports Physiol Perform. 2006;1:50–7.
Welsh AH, Knight EJ. “Magnitude-based inference”: a statistical review. Med Sci Sports Exerc. 2015;47:874–84.
Buchheit M. The numbers will love you back in return—I promise. Int J Sports Physiol Perform. 2016;11:551–4.
Ferrauti A, Weber K, Strüder HK. Metabolic and ergogenic effects of carbohydrate and caffeine beverages in tennis. J Sports Med Phys Fit. 1997;37:258–66.
Paton C, Costa V, Guglielmo L. Effects of caffeine chewing gum on race performance and physiology in male and female cyclists. J Sports Sci. 2015;33:1076–83.
Jonvik KL, Nyakayiru J, van Loon LJC, et al. Viewpoint: can elite athletes benefit from dietary nitrate supplementation? J Appl Physiol. 2015;119:759–61.
Porcelli S, Ramaglia M, Bellistri G, et al. Aerobic fitness affects the exercise performance responses to nitrate supplementation. Med Sci Sports Exerc. 2015;47:1643–51.
Hultström M, Amorim de Paula C, Antônio Peliky Fontes M, et al. Commentaries on Viewpoint: can elite athletes benefit from dietary nitrate supplementation? J Appl Physiol. 2015;119:762–9.
Hoon MW, Jones AM, Johnson NA, et al. The effect of variable doses of inorganic nitrate-rich beetroot juice on simulated 2,000-m rowing performance in trained athletes. Int J Sports Physiol Perform. 2014;9:615–20.
Peeling P, Cox GR, Bullock N, et al. Beetroot juice improves on-water 500 m time-trial performance, and laboratory-based paddling economy in national and international-level kayak athletes. Int J Sport Nutr Exerc Metab. 2015;25:278–84.
Watt KK, Garnham AP, Snow RJ. Skeletal muscle total creatine content and creatine transporter gene expression in vegetarians prior to and following creatine supplementation. Int J Sport Nutr Exerc Metab. 2004;14:517–31.
Conger SA, Warren GL, Hardy MA, et al. Does caffeine added to carbohydrate provide additional ergogenic benefit for endurance? Int J Sport Nutr Exerc Metab. 2011;21:71–84.
Yang A, Palmer AA, de Wit H. Genetics of caffeine consumption and responses to caffeine. Psychopharmacology. 2010;211:245–57.
Womack CJ, Saunders MJ, Bechtel MK, et al. The influence of a CYP1A2 polymorphism on the ergogenic effects of caffeine. J Int Soc Sports Nutr. 2012;9:7.
Womack CJ, Saunders MJ, Bechtel MK, et al. Erratum to: the influence of a CYP1A2 polymorphism on the ergogenic effects of caffeine. J Int Soc Sports Nutr. 2015;12:24.
Casey A, Greenhaff PL. Does dietary creatine supplementation play a role in skeletal muscle metabolism and performance? Am J Clin Nutr. 2000;72:607S–17S.
Saunders B, Sale C, Harris RC, et al. Sodium bicarbonate and high-intensity-cycling capacity: variability in responses. Int J Sports Physiol Perform. 2014;9:627–32.
Graham TE, Spriet LL. Performance and metabolic responses to a high caffeine dose during prolonged exercise. J Appl Physiol. 1991;71:2292–8.
Talanian JL, Spriet LL. Low and moderate doses of caffeine late in exercise improve performance in trained cyclists. Appl Physiol Nutr Metab. 2016;41:850–5.
Research undertaken by this author in relation to performance supplements was funded by grants from the Australian Institute of Sport. This article was published in a supplement supported by the Gatorade Sports Science Institute (GSSI). The supplement was guest edited by Lawrence L. Spriet who attended a meeting of the GSSI expert panel in November 2015 and received honoraria from the GSSI for his participation in the meeting. He received no honoraria for guest editing the supplement. Dr. Spriet selected peer reviewers for each paper and managed the process. Dr. Louise Burke also attended the meeting of the GSSI expert panel in November 2015 and her workplace (Australian Institute of Sport) received an honorarium from the GSSI, a division of PepsiCo for her meeting participation and the writing of this manuscript. The views expressed in this manuscript are those of the author and do not necessarily reflect the position or policy of PepsiCo, Inc.
About this article
Cite this article
Burke, L.M. Practical Issues in Evidence-Based Use of Performance Supplements: Supplement Interactions, Repeated Use and Individual Responses. Sports Med 47, 79–100 (2017). https://doi.org/10.1007/s40279-017-0687-1
- Female Athlete
- Performance Supplement
- Creatine Supplementation
- Competitive Sport