Effects of a 10-Week Exercise and Nutritional Intervention with Variable Dietary Carbohydrates and Glycaemic Indices on Substrate Metabolism, Glycogen Storage, and Endurance Performance in Men: A Randomized Controlled Trial

A total of 121 males registered for the trial. After an initial telephone screening, where the study objectives were explained in detail and inclusion criteria (age, training sessions per week, and physical activity readiness) were checked, 87 men were invited for an initial medical examination, including a medical history questionnaire to ensure the inclusion criteria were met and that there was no medical condition that could be worsened by the study protocol.

Inclusion criteria included age ranging from 18 to 40 years and 2–3 training sessions per week (no professional level athlete) as well as the evaluation of readiness for physical activity (PAR-Q). Exclusion criteria were previous experience with one of the intervention diets, being a professional athlete, contraindications to physical activity according to the American College of Sports Medicine Guidelines diagnosed by a medical doctor [32], use of medications or dietary supplements that could affect measurements or are prohibited by the WADA Code, chronic diseases, and arterial hypertension. Additionally, screening for magnetic resonance spectrometry specific exclusion criteria was performed, which included claustrophobia, pacemaker, cochlear implant, subcutaneous injection system, stents, metal implants, piercings, and tattoos, or a body weight of more than 180 kg.

In total, 87 healthy recreationally active endurance athletes met all the criteria, provided their written informed consent, and were enrolled in the study. Regarding the sample size, previous studies with a comparable design [30, 31] as well as an a priori power analysis with G*power (version 3.1.9.7. for windows) were used [33]. An estimated partial eta square of 0.025 with a power of 0.8, α error probability of 0.05 and a surcharge for dropouts resulted in a sample size of 26 subjects per group, which was thought to be sufficient to reach significant results and adequate power. To achieve a power of 80% and reliable statistical analyses, 20 subjects per group must complete the study under the specified conditions.

During the first visit, anthropometric and demographic data, such as body composition measured by bioelectric impedance (Seca mBCA 514/515, seca GmbH & co. KG, Hamburg, Germany) and training status, were collected. At a second visit, a graded exercise test starting at 6 km h⁻¹ with increasing speed by 1.5 km h⁻¹ every three minutes until exhaustion was performed on a treadmill (Quasar med, h/p/cosmos sports & medical GmbH, Nussdorf-Traunstein, Germany). Capillary blood samples were collected and analysed using the Biosen lactate analyser (Biosen S-line, KF-diagnostic GmbH, Barleben/Magdeburg, Germany) at baseline, at the end of each step during the test and at exhaustion. The blood lactate thresholds (LT and individual anaerobic threshold IAT) were furthermore calculated from the blood lactate curve using Ergonizer software (Freiburg, Germany) in order to define the training zones for the prescribed training plan. LT is thereby defined as the earliest moment of an increase in blood lactate concentration with increasing exercise intensity. Moreover, Ergonizer software calculated the IAT according to the principle of the net increase via the lactate concentration at the LT. This means that the IAT is defined as the point that represents the LT plus 1.5 mmol L⁻¹. If the final increment could not be completed, the peak running speed (PRS) was calculated as proposed by [34]:\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$PRS=V \, com+ \frac{t}{3}* \Delta V$$\end{document}PRS=Vcom+t3∗ΔVin which V com is the last increment completed, t the number of minutes the final not completed speed was sustained, and ∆V the final speed increment (1.5 km h⁻¹). The duration of the graded exercise test was calculated as the total duration of the test from the first increment (6 km h⁻¹) on and is referred to as time to exhaustion (TTE).

During the test, oxygen uptake (VO₂) and respiratory exchange ratio (RER) were continuously measured by a breath-by-breath gas analyser (MetaLyzer 3B, Cortex Biophysik GmbH, Leipzig, Germany) to determine peak VO₂, which was defined as the 30 s rolling average maximum VO₂ value during the graded exercise test. Before each experimental session, the device was calibrated using procedures according to the manufacturer’s instructions. The average values of VO₂ (L min⁻¹) and RER were calculated in the last minute of each 3-min exercise stage. Based on their peak oxygen uptake, subjects were randomly assigned to one of three dietary groups to minimise baseline differences, as suggested by Hopkins [35]. Allocation to an intervention group was random, but was monitored to ensure that peak VO₂ values at the intervention were comparable in all three groups. Based on the average values of VO₂ and RER, fat and carbohydrate oxidation were calculated using stochiometric equations up to RER = 1.00 according to Péronnet and Massicotte [36], where:\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$${\text{VCO}}2 [{\text{L}} \, {{\text{min}}}^{-1}]=RER*VO2 [{\text{L}} \, {{\text{min}}}^{-1}]$$\end{document}VCO2[Lmin-1]=RER∗VO2[Lmin-1]\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$Fat \, oxidation \left[{\text{g}} \, {{\text{min}}}^{-1}\right]=1.695*VO2 \left[{\text{L}} \, {{\text{min}}}^{-1}\right]-1.701* {\text{VCO}}2 [{\text{L}} \, {{\text{min}}}^{-1}]$$\end{document}Fatoxidationgmin-1=1.695∗VO2Lmin-1-1.701∗VCO2[Lmin-1]\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$Carbohydrate \, oxidation \left[\mathrm{g } \, {{\text{min}}}^{-1}\right]=4.21*{\text{VCO}}2 [\mathrm{L } \, {{\text{min}}}^{-1}]-2.962* VO2 \left[{\text{L}} \, {{\text{min}}}^{-1}\right]$$\end{document}Carbohydrateoxidationgmin-1=4.21∗VCO2[Lmin-1]-2.962∗VO2Lmin-1

To assess and compare the parameters during the graded exercise test, for fat and carbohydrate oxidation, RER and blood lactate the area under the curve (AUC) was calculated between the start of the test and the final increment completed by all participants before exhaustion (t_n) using the following equation:\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$AU{C}_{0-{t}_{n}}=\frac{1}{2}\sum_{i=0}^{{t}_{n}}\left({t}_{i+1}-{t}_{i}\right)x\left({C}_{i}+{C}_{i+1}\right)$$\end{document}AUC0-tn=12∑i=0tnti+1-tixCi+Ci+1where t_n is the final completed increment, t_i the km h⁻¹ of the increment at which the parameter was measured and C_i the respective concentration/value to that timepoint. Due to the fact that the number of completed increments developed differently in the groups during the study, the AUC of lactate concentration was related to the time to exhaustion (TTE) in the graded exercise test. For this purpose, the corresponding AUC was divided by the TTE and multiplied by 100.

Additionally, running economy at the lactate threshold was calculated for each subject. Therefore, the VO₂ consumption in mL min⁻¹ at lactate threshold was divided by body weight. Relative VO₂ consumption and velocity at lactate threshold were used to calculate running economy in mL min⁻¹ km⁻¹, as proposed by [37].

In a third visit, a 5-km time trial (TT) on an outdoor 400 m track was performed. Body composition analyses, graded exercise test, as well as time trial were performed at the beginning and after the 10-week intervention under the same conditions and at the same time of day to minimise circadian influences. Body composition was measured in fasted state for all timepoints. For the time trial and the graded exercise test at the beginning all subjects were given a standardized nutritional guideline, for the 24 h prior to the test. They were instructed to fast and to restrain from caffeine 2 h prior to performing the test. Additionally, 48 h prior to the test intense exercise was not allowed. For the graded exercise test and the time trial at the end of the intervention nutrition was not controlled because of the different nutritional regimes that they followed. However, subjects were advised to fuel as they would fuel before a hard interval session and the last meal prior the test was eaten at the same timepoint like at the first examination. Again, no intense exercise took place 48 h prior to the tests.

In addition to performance tests, 24 (8 from each group) randomly selected subjects underwent magnetic resonance spectroscopy (MRS) of the vastus lateralis (VL) muscle at baseline and after the intervention to determine muscle glycogen and intramyocellular lipid (IMCL) content. After an overnight fast, measurements were performed in a 7 T whole-body magnetic resonance system (Magnetom, Siemens Healthcare, Erlangen, Germany). Spectroscopy measurements and calculations were done according to previous studies [38, 39]. In more detail, ¹³C MRS for the assessment of tissue glycogen was performed with ¹H/¹³C body surface coil (STARK CONTRAST MRI coils Research, Erlangen, Germany) consisting of a slightly curved 18 cm transmitter loop with two smaller (14 cm) receiver elements combined with quadrature detection operating at ¹³C resonance frequency (74.73 MHz) and a 16 cm Tx/Rx loop for ¹H imaging and shimming (297.2 MHz) applying 13^C pulse-acquire sequence (pulse length = 500 µs, flip angle = 90° in coil plane, repetition time = 500 ms, spectral bandwith = 10,000 Hz, number of acquisitions: 3 blocks of 512). Absolute glycogen concentrations were quantified by comparing the C1 glycogen doublet (100.5 ppm) integral of muscle spectra with that of a glycogen solution standard taken under identical conditions. Corrections for loading of the coil, coverage of sensitive volume of the coil on the muscle and subcutaneous adipose tissue thickness were performed. Intramyocellular lipids were quantified after repositioning the volunteers using a 28-channel knee coil (QED, Mayfield Village, OH, USA) by single voxel ¹H MRS. T1 weighted, multi-slice localizer images were acquired and used for volume-of-interest (VOI) positioning. Spatial selection was achieved using a STEAM localization sequence and the VOI 15 × 15 × 30 mm³ was carefully placed in the VL muscle. Voxel positioning was guided by images to properly adjust voxel geometry and orientation to fit the actual shape of subject’s muscle, avoiding the boundaries of muscle and subcutaneous fat. Localized shimming was performed automatically followed by manual inspection and readjustments. The final linewidth of the water signal was in the range of 28–38 Hz in the magnitude mode. Signals of IMCL were measured with the following parameters: repetition time (TR)/echo time (TE) = 2000/20 ms; spectral bandwidth = 3 kHz; number of averages (NA) = 16. For acquisition of a concentration reference, the water signal was measured with a TR = 2000 ms and a TE = 20 ms; NA = 1.

Under the supervision of trained dieticians, participants were instructed to follow the dietary pattern according to their respective group and previous pilot studies [30, 31]:LOW-GI: 50–60% carbohydrates with ≥ 65% of energy from low glycaemic index (GI < 50) carbohydrates per dayHIGH-GI: 50–60% carbohydrates with ≥ 65% of energy from high glycaemic index (GI > 70) carbohydrates per dayLCHF: ≥ 65% fat, maximum of 50 g carbohydrates per day

The dietary requirements were integrated into the test person's daily routine, and the meals were selected and prepared by the test person themselves. Food specifications for the LOW-GI group included among other things wholemeal bread, wild rice, vegetables other than potatoes or wholemeal pasta combined with an adequate protein (around 15% of total energy intake) and fat (around 30% of total energy intake) intake. For the HIGH-GI group, macronutrient distribution was comparable to the LOW-GI group with the advice to preferably consume white bread, pasta, rice, fruits, and potatoes along with other high GI foods. For the LCHF group the restrictions were the most drastic. For example, cereal products, carbohydrate sources, such as bread, pasta and rice, and sweet fruits had to be omitted and vegetable consumption was restricted to low-starch vegetables such as cabbage, cucumbers, and peppers. Only meat, fish and eggs were not restricted. To measure ketosis, the subjects in LCHF group carried out urine analyses with reagent strips (Ketostix, Acensia Diabetes Care Austria GmbH, Vienna, Austria) during the study. In addition, the level of ketone bodies in the capillary blood was measured with a ketone meter (On Call GK Dual, Acon Laboratories Inc., San Diego, California, USA) at the end of the intervention in fasted state. Additional file 1 showing the guidelines and example meals for each group was provided to the participants (see Additional file 1). All diets were ad libitum diets and subjects were advised not to restrict their energy intake. If they stuck to their dietary requirements, the test subjects were allowed to eat until they were full. In the event of concerns or questions about the nutritional regime, dieticians were contacted. Before starting the study, participants were asked to complete a 24-h recall and a food frequency questionnaire (FFQ). The validated DEGS1-FFQ was used and collects the frequency and quantity of 53 food items eaten in the last 4 weeks [40]. The questionnaire was completed online and converted to nutritional intake according to previous proposed methods [41]. 24-h recall and FFQ were combined to assess nutrition prior to the intervention. During the study, participants were asked to protocol one weekday and one weekend day per week. The protocols were reviewed by trained dieticians using nut.s software (Dato Denkwerkzeuge, Wien, Austria). The mean of 20 24-h recalls per subject was calculated to assess compliance during the study and used for further calculations.

Determination of the GI of the consumed foods was based on Atkinson, Foster-Powell [42] and Atkinson, Brand-Miller [43]. To calculate the GI of a meal, the amount of carbohydrates in grams per meal was determined. The GI of the individual foods in the meal was then calculated proportionately and added together. Thus, a GI was determined for each meal of the day. These were added and divided by the number of meals. Finally, the average GI of all protocols was determined for each subject.

The endurance training plan was the same for all groups and the training zones were customised for each subject based on the lactate thresholds resulting from the graded exercise test. An example week can be found in the Additional file. The plan consisted of five running sessions per week, three of which were steady-state and two of which were interval sessions. The steady-state runs were completed at the specified heart rate zones (below, at LT or between LT and IAT). For the intervals, the participants were guided by the pace specifications according to the prescribed zone (at or above IAT). Training sessions were distributed independently over the week, but long runs and the interval sessions were not performed on consecutive days. Additionally, there was be at least one rest day between the two interval sessions. During the first 4 weeks of the training plan, the focus was on training basic endurance, whereas in the second 4 weeks the focus was on interval sessions. The last 2 weeks were for maintenance. Basically, participants were encouraged to complete all training sessions. To be able to control this, all training sessions were recorded with a sports watch (Polar Vantage M, Polar Electro Oy, Kempele, Finland) and a heart rate belt (Polar H10, Polar Electro Oy, Kempele, Finland) and checked weekly by the study management. Nevertheless, it was established and communicated prior to commencement that a minimum requirement of 75% of the prescribed training minutes was necessary for inclusion in the final analysis. 1

Throughout the intervention phase, general condition, gastrointestinal well-being, and perceived effort were assessed daily using a visual analogue scale (VAS). This VAS is an assessment tool that quantitatively measures conditions on a scale ranging from 0 (optimal condition) to 100 (worst condition). The distance between the two conditions was marked by the participant and given in mm by the VAS [44].

Statistical analyses were performed using Statistical Package for the Social Sciences Software (SPSS for Windows, Version 28, SPSS Inc., Chicago, IL) and figures were created using GraphPad Prism (GraphPad Prism Version 8.0.2 for Windows, GraphPad Software, San Diego, California, USA). The level of significance was set at α = 0.05. The results of the descriptive analyses are shown as mean ± standard deviation (SD).

The normal distribution of the metric variables was tested by the Shapiro Wilk test. Continuous data without normal distribution, which cannot be transformed to normal distribution, were tested by a nonparametric method. Differences between groups at baseline were tested by one-way ANOVA. If normal distribution was not given, Kruskal–Wallis test was used. The Tukey post hoc test was performed to identify groups that differed significantly. For the assessment of the time (within subject factor), group (between subject factor) and time x group interaction effects, a two-way mixed ANOVA with Tukey-corrected post hoc analyses was used. In case of a significant group x time interaction, simple main effects for group and time were analysed. To compare the rate of changes from pre-intervention to post-intervention, the differences were calculated (post–pre) and further examined by one-way ANOVA. The effect sizes for one-way ANOVA (ηp²) and simple time effects (Cohen’s d) are displayed for significant results.

For nutrition, the two-way mixed ANOVA revealed significant interaction effects for energy and macronutrient intake (p < 0.050, respectively). Total energy intake was significantly reduced in the LOW-GI group (− 394 ± 491 kcal, p < 0.001, d = 0.802), while no significant differences were found in the other two groups. The energy intake during the study differed significantly between the HIGH-GI (2124 ± 462 kcal) and the LCHF group (1755 ± 468 kcal) with a higher energy intake in the HIGH-GI group (p = 0.043, ηp² = 0.109). Changes in energy intake due to the study were significantly different between the LOW-GI (− 394 ± 491 kcal) and the HIGH-GI group (+ 52 ± 379 kcal, p = 0.005, ηp² = 0.112), while no difference in change was observed between LOW-GI and LCHF group (− 199 ± 444 kcal, p = 0.118). Relative carbohydrate intake increased during the study in the HIGH-GI group (+ 3.3 ± 4.7%, p = 0.005, d = 0.711), decreased in the LCHF group (− 34.8 ± 10.0%, p < 0.001, d = 3.503) and remained unchanged in the LOW-GI group (+ 0.3 ± 6.7%, p = 0.839). The relative carbohydrate intake during the study differed significantly between LCHF and the two carbohydrate groups (p < 0.001, ηp² = 0.941). The relative protein intake changed significantly in all groups due to the intervention (p < 0.050 for all groups) and differed significantly during the study (for all pairwise comparisons p < 0.050, ηp² = 0.773). For LOW-GI (+ 3.4 ± 2.4%, p < 0.001, d = 1.452) and LCHF (+ 9.3 ± 4.7%, p < 0.001, d = 1.975) protein intake increased significantly. On the contrary, protein intake decreased in the HIGH-GI group (− 1.1 ± 2.3%, p = 0.042, d = 0.487). Relative fat intake was significantly reduced in LOW-GI group (− 3.1 ± 6.9%, p = 0.034, d = 0.461), remained unchanged in the HIGH-GI group (− 2.0 ± 5.2, p = 0.104) and increased significantly in the LCHF group (+ 27.9 ± 8.9%, p < 0.001, d = 3.152). During the study, fat intake differed significantly between the LCHF group and the two carbohydrate groups (p < 0.001, ηp² = 0.906).

In both carbohydrate groups, the glycaemic index changed significantly during the study. In the LOW-GI group, the glycaemic index was reduced from 62 ± 10 before the intervention to 41 ± 3 during the intervention (p < 0.001, d = 1.469). For the HIGH-GI group, the glycaemic index increased from 57 ± 8 to 64 ± 3 (p < 0.001, d = 0.993). The glycaemic index differed significantly between the groups (p < 0.001, d = 7.555). Compliance to the LCHF diet was good. Fasted ketone bodies concentration measured at the end of the intervention was 0.8 ± 0.4 mmol L⁻¹.

No differences in training minutes were found neither in total (LOW-GI: 2125 ± 294 min, HIGH-GI: 2072 ± 285 min, LCHF: 2101 ± 255 min, p = 0.824), nor when splitting the minutes in steady-state (LOW-GI: 1468 ± 196 min, HIGH-GI: 1450 ± 210 min, LCHF: 1460 ± 183 min, p = 0.469) and interval (LOW-GI: 657 ± 122 min, HIGH-GI: 622 ± 120 min, LCHF: 641 ± 85 min, p = 0.731) sessions.

For AUC of fat and carbohydrate oxidation significant time group interactions were found (Fig. 3). Before the intervention, AUC of fat oxidation was significantly lower in LOW-GI (2.6 ± 0.1 g min⁻¹ × km h⁻¹) compared to LCHF (3.6 ± 0.7 g min⁻¹ × km h⁻¹, p = 0.003, ηp² = 0.171). No baseline differences for AUC of carbohydrate oxidation, maximum fat oxidation (MFO) and intensity at MFO (FAT_max) were observed. Fat oxidation during the incremental exercise test remained unchanged in LOW-GI (− 0.3 ± 1.0 g min⁻¹ × km h⁻¹, p = 0.240), decreased significantly in HIGH-GI (− 1.1 ± 1.0 g min⁻¹ × km h⁻¹, p < 0.001, d = 1.113) and increased in LCHF (+ 0.8 ± 1.6 g min⁻¹ × km h⁻¹, p = 0.027, d = 0.522). After the intervention, AUC of fat oxidation was significantly higher in LCHF compared to both carbohydrate groups (p < 0.001, ηp² = 0.429). AUC of carbohydrate oxidation remained unchanged in LOW-GI (− 0.1 ± 3.4 g min⁻¹ × km h⁻¹, p = 0.923) and HIGH-GI (− 0.2 ± 2.4 g min⁻¹ × km h⁻¹, p = 0.769) and decreased significantly in LCHF (− 2.8 ± 4.6 g min⁻¹ × km h⁻¹, p = 0.012, d = 0.601). In terms of MFO and FAT_max statistical analysis revealed a significant increase in MFO in LCHF (+ 0.4 ± 0.2 g min⁻¹, p < 0.001, d = 1.605) while in the carbohydrate groups no changes were observed. MFO was significantly higher in LCHF (0.9 ± 0.2 g min⁻¹) compared to LOW-GI (0.6 ± 0.2 g min⁻¹) and HIGH-GI (0.5 ± 0.2 g min⁻¹, p < 0.001, ηp² = 0.489) after the intervention (Fig. 3). FAT_max showed no different change or time x group interaction (p > 0.05). Nevertheless, FAT_max showed an improvement over time regardless of the intervention group (+ 3 ± 12% VO_{2 peak}, p = 0.025, ηp² = 0.079, Table 4).

Unlike TTE and PRS, VO₂ peak did not show any significant changes in the time course of the study (p > 0.050 for time*group interaction and main effects). Similar results were found for the 5-km time trial (TT). Participants in all groups were able to enhance time compared to the beginning of the intervention (main effect of time: p < 0.001, ηp² = 0.550). The rate of change showed no significant difference between the groups (p = 0.189). However, it should not go unmentioned, that the highest improvement was found in the LOW-GI (− 121 ± 65 s, p < 0.001, d = 1.862), followed by the HIGH-GI (− 91 ± 120 s, p = 0.003, d = 0.753) and the LCHF (− 70 ± 96 s, p = 0.003, d = 0.724) group. No simple group effects were found before or after the intervention. In line with these results, no significant time*group interaction was found for running economy at lactate threshold (p = 0.444). Moreover, no different changes were observed between the groups (LOW-GI: T-0: 224 ± 27 vs. T-10: 220 ± 30 mL min⁻¹ km⁻¹, HIGH-GI: T-0: 228 ± 27 vs. T-10: 217 ± 24 mL min⁻¹ km⁻¹, LCHF: T-0: 214 ± 35 vs. T-10: 214 ± 25 mL min⁻¹ km⁻¹).

Of the 24 subjects examined by magnetic resonance imaging at the beginning of the study, only 7 participants were analysed in the LOW-GI, 5 participants in the HIGH-GI, and 6 participants in the LCHF group at the end of the intervention, since the other subjects were dropouts. As shown in Fig. 4, the muscle glycogen content remained unchanged in the LOW-GI group (+ 35.4 ± 56.9 mmol L wet-tissue⁻¹, p = 0.151) and increased significantly for participant of the HIGH-GI group (+ 42.6 ± 28.0 mmol L wet-tissue⁻¹, p = 0.027, d = 1.522). In the LCHF group the glycogen content was reduced by − 21.5 ± 32.6 mmol L wet-tissue⁻¹, but the reduction was not significant (p = 0.166). ANOVA revealed a significantly higher rate of change in the LCHF group compared to the HIGH-GI group (p = 0.043, ηp² = 0.342). The glycogen content after the intervention was significantly lower in LCHF compared to LOW-GI (151.9 ± 26.5 vs. 95.8 ± 29.3 mmol L wet-tissue⁻¹, p = 0.014, ηp² = 0.435).

Two-way mixed ANOVA showed no significant interaction for intramyocellular lipids (p = 0.093). Main effect of time showed a significant increase in IMCL (T-0: 0.39 ± 0.19% of water signal, T-10: 0.43 ± 0.15% of water signal, p = 0.001, ηp² = 0.521) independent of the nutritional intervention. The rate of change for the IMCL during the intervention did not differ significantly between the groups (p = 0.093).

This trial also has some limitations. Diet for the study period was monitored using self-reported 24-h recalls, which may be susceptible to reporting bias, recall bias and training bias [94]. 24 h recalls were completed two times per week, reducing the likelihood of random errors, and furthermore, this method is less likely to be affected by underreporting than other methods, such as food records [95]. It is also known that the first recall could be a significant point of bias [96]. To minimise this error, an additional food frequency questionnaire was used to assess diet before the study [97].

Although previously assumed, we did not observe any differences between the diets during the 5 km TT. A possible reason for this could be that compared to cycling more muscle mass is addressed during running and less glycogen is broken down in the leg muscles and the m. gastrocnemius is not depleted for glycogen at exhaustion [98]. It might be anticipated that the differences in muscular glycogen stores will become more pronounced during shorter more intense bouts of exercise. However, the groups with the higher glycogen stores showed higher effects on improvement in performance at 5 km TT.

Furthermore, future investigations should include different sex groups and use different periodisation of macronutrient intake to better understand underlying mechanism. The analysis with metabolomics methods could further shed light on the ongoing adaptions in metabolism.

Additional file 1. Table 1. Nutritional guidelines for each intervention group. Table 2. Example meal plan for one day for every intervention group. Table 3. Example week of the prescribed endurance training plan.