Eleven healthy, endurance-trained participants (eight men, three women) accustomed to cycling exercise, provided written informed consent and met the eligibility criteria to undertake the study that was approved by the Science, Technology, Engineering and Mathematics Ethics Committee, University of Birmingham, UK (Ethics code: ERN_17-1236). Their mean age, body mass, height, maximal oxygen uptake (V°O₂peak), and maximal cycle ergometer power output (Wmax) were 31 ± 5 years, 68 ± 9 kg, 173 ± 7 cm, 3.86 ± 0.52 L O₂·min⁻¹ (56.9 ± 4.8 mL O₂·min⁻¹·kg⁻¹), and 338 ± 47 W (5.0 ± 0.5 W·kg⁻¹), respectively. These participants all completed preliminary testing and their data are included for estimation of ¹³C bicarbonate elimination (further details below). Three participants dropped out after the preliminary or familiarization visits: two due to time commitments; one due to GI discomfort during the familiarization trial. Thus eight participants successfully finished all trials. Their mean age, body mass, height, maximal oxygen uptake (V°O₂peak), and maximal cycle ergometer power output (Wmax) were 31 ± 5 years, 71 ± 7 kg, 175 ± 8 cm, 4.04 ± 0.44 L O₂·min⁻¹ (56.8 ± 5.0 mL O₂·min⁻¹·kg⁻¹), and 352 ± 41 W (5.0 ± 0.5 W·kg⁻¹), respectively.

Participants underwent preliminary testing that consisted of a V°O₂peak test and a steady state exercise bout. The latter was used to estimate elimination rate of ingested ¹³C bicarbonate. Participants then completed a familiarization trial and two experimental trials consisting of a glycogen-reducing exercise bout in the morning followed by a 4-h recovery period and a 1-h steady state exercise bout (SS) immediately followed by a time trial (TT) with a predicted duration of 40-min. The experimental trials differed in the diet provided during the 4-h recovery window. On both occasions participants received carbohydrates at a rate of 1.2 g·kg⁻¹·h⁻¹ during a 4-h re-feeding period with a difference in the composition of carbohydrates. On one occasion they received a mixture of glucose-based carbohydrates, namely dextrose and maltodextrin (GLU + MD) and on another fructose and maltodextrin (FRU + MD), both in a 1:1.5 ratio. The order of the trials was randomized, the study was double-blinded, and the trials were separated by at least 6 days.

Participants came to the laboratory at ~07:00 h after an overnight fast. They performed an incremental test to exhaustion to determine V°O₂peak and Wmax on a cycle ergometer (Excalibur Sport; Lode, Groningen, Netherlands). The test started at a power output of 100 W and the workload increased by 30 W every 2 min. During the test, gas exchange measurements were made using an automated online gas analysis system (Vyntus, Vyaire Medical, Ottawa, IL, US). Gas analyzers were calibrated with a known gas mixture (15.04% O₂, 5.06% CO₂; BOC Gases, Surrey, UK) and the volume transducer was calibrated with a 3-liter calibration syringe (Jaeger, Wurzburg, Germany) prior to each trial. The highest 30-s average of O₂ uptake was considered to represent V°O₂peak. Wmax was calculated as the power output from the last completed stage plus the fraction of the time spent in the next stage multiplied by 30 W.

Participants then rested for 30-min before undertaking an exercise session assessing kinetics of ¹³C labeled bicarbonate elimination as previously described (19). Stable isotope methodology is commonly used to assess oxidation rates of ingested carbohydrates. However, after their oxidation, labeled carbon atoms previously constituting carbohydrate molecules can be for some time held within the body pool of bicarbonate and thus oxidation rates of ingested carbohydrates underestimated. Thus, it is common to calculate the time required for the bicarbonate pool to be turned over. Briefly, immediately after ingestion of 0.23 ± 0.08 mg · kg body weight of ¹³C labeled bicarbonate (99% purity, Cambridge Isotope Laboratories, Inc.; Andover, USA) participants exercised at 50% Wmax for 60 min. ¹³CO₂ production, reflecting ¹³C labeled bicarbonate excretion was determined throughout the exercise by measurement of CO₂ production (as described above using indirect calorimetry) and by quantification of ¹³CO₂/¹²CO₂ ratio in expired breath using isotope ratio mass spectrometry (IsoAnalytical Ltd., Crewe, UK). Breath was collected into 10-mL evacuated tubes (Exetainer Breath Vial, Labco Ltd.; Buckinghamshire, UK). Cumulative excretion of labeled bicarbonate was quantified at 2, 5, 10, 20, 30, 45, and 60 min.

A familiarization trial was performed ~7 days after preliminary testing. It followed the same protocol as the experimental trials in GLU + MD condition without blood sampling. As well as familiarization, this trial was used to quantify any background shift in ¹³CO₂ production during the SS exercise period to enable a more accurate determination of ingested carbohydrate oxidation rates (further described below).

Participants entered the laboratory at ~7:00 after not eating from 22:00 the day before. They were asked to replicate the diet and activity patterns of the day preceding each experimental trial. On entering the laboratory a blood sample was taken using venepuncture from an antecubital vein. Then they performed a high-intensity-interval exercise protocol as described previously (13, 20). This protocol has previously been shown to effectively reduce muscle glycogen concentration (13). After a 5-min warm-up at 50% Wmax participants cycled at alternating workloads of 90 and 50% Wmax, respectively, each lasting 2 min. Once 90% workload was deemed too demanding for participants to be able to cycle at a cadence of more than 60 revolutions per minute (RPM) despite strong verbal encouragement, 90% intensity was first reduced to 80% and then to 70%. When blocks at 70% Wmax could not be completed at the cadence >60 RPM, the exercise session was terminated. Immediately post-exercise an indwelling cannula was placed in an antecubital arm vein and a blood sample taken. Participants then started the 4-h recovery period.

During recovery, participants passively rested for 4 h, during which time sedentary activities such as reading and use of laptops were permitted. Immediately upon obtainment of the blood sample post exercise, participants commenced ingesting a 15% carbohydrate containing drink every 30 min with a carbohydrate ingestion rate of 1.2 g·kg⁻¹·h⁻¹. Composition of the drink was either glucose (Roquette, Lestrem, France or Myprotein, The Hut Group, Cheshire, UK for familiarization and experimental trials, respectively) and maltodextrin (Avebe, Veendam, The Netherlands or Myprotein, The Hut Group, Cheshire, UK for familiarization and experimental trials, respectively) (GLU + MD) or fructose (Peak Supps, Bridgend, UK) and maltodextrin (FRU + MD) in a 1:1.5 ratio. Carbohydrates ingested during recovery of the familiarization trial were of naturally low ¹³C abundance [−26.17δ ¹³C_V−PDB (%0)] whereas during the experimental trials they were naturally high ¹³C abundance [−11.18 δ ¹³C_V−PDB (%0) for FRU + MD and −11.14 δ ¹³C_V−PDB (%0) for GLU + MD]. A venous blood sample was obtained every 1 h during the recovery with the cannula flushed with saline every 30 min to maintain patency.

During the 1-h long SS at 50% Wmax, participants breathed for 3 min every 15 min into a mouthpiece connected to the metabolic cart (as described above) for the determination of V°O₂ and V°CO₂ and breath samples were collected into Exetainers as described above for subsequent mass spectroscopy analysis of ¹³C enrichment in the expired breath. In addition to that, blood samples were collected every 15 min during the SS and at the end of the TT. Immediately on completion of the SS, the cycle ergometer was set to a linear mode (workload increases linearly with the cycling cadence) and the TT started. Participants had to perform a set amount of work (equal to ~40 min of cycling at 65% W_max) as quickly as possible. The amount of work for each participant was calculated according to the following equation:

Total amount of work = 0.65 Wmax × 2,400 J

The ergometer was set in the linear mode and the linear factor calculated according to the formula:

Where L is a linear factor, W is predicted power and RPM is the cycling cadence. RPM was set to 80, where W represented 65% Wmax. During the TT, participants were displayed the total amount of work to be completed, remaining work and % of work completed, while the cadence and the power output were recorded but not visible to the participants. As per recommendations (17), the TT took place in silence with no verbal encouragement given. Following the TT, a final blood sample was collected.

Venous blood samples (~6 mL) were collected into EDTA tubes, stored on ice and then centrifuged at 4°C and 1,006 × g for 15 min. Aliquots of plasma were then stored at −70°C and later analyzed for glucose (Glucose kit; Randox, London, UK) and lactate (Lactate kit; Randox, London, UK) using an automated photometric based clinical chemistry analyzer RX Daytona+ (Randox, London, UK).

Fat and carbohydrate oxidation rates were calculated using stoichiometric equations of Jeukendrup and Wallis (21) with the following equations assuming protein oxidation to be negligible:

Where V∙CO₂ and V∙O₂ are expressed in L·min⁻¹ and oxidation rates (CHO and fat) are calculated in g·min⁻¹.

The isotopic enrichment was expressed as δ per milliliter difference between the ¹³C/¹²C ratio of the sample and a known laboratory reference standard.

The percentage of elimination of ingested ¹³C bicarbonate was calculated according to the following equation (19):

Where 85 represents molecular weight of ingested sodium bicarbonate, V∙13CO2 volume of expired ¹³CO₂ (L), 22.4 L is volume of air occupied by 1 mol of CO₂ and m_bicarb mass (mg) of ingested bicarbonate. V∙13CO2was calculated by multiplying the volume of expired gas and the atom per cent excess of ¹³CO₂.

The ingested carbohydrate oxidation rate during SS, representing oxidation of the carbohydrates ingested during recovery, were calculated according to the following equation (22):

Where δ Exp represents ¹³C enrichment of expired gas sample, δ Ing represents ¹³C represents enrichment of ingested carbohydrate, Exp_bkg represents enrichment of expired gas sampled during the familiarization session at the corresponding timepoint, and 0.7467 V∙CO₂ of 1 g glucose oxidation.

During recovery, gastrointestinal comfort (GC) was assessed every hour using a 10-point Likert scale (23) that included assessment of experience of nausea, stomach fullness and abdominal cramping. Heart rate (HR) values were obtained at 15-min intervals during the SS via a heart rate strap (H7, Polar, Kempele, Finland) which was connected via Bluetooth® to a watch (Ambit 3 Sport, Suunto, Vantaa, Finland). Simultaneously, every 15-min participants were asked to report the rate of perceived exertion (RPE) using 6–20 scale (24) and GC using the same questionnaire as during the recovery.

Sample size was determined using g^*power software (25) assuming an effect size of 1.84 as observed previously for differences in subsequent exercise capacity between the two carbohydrate conditions (14). It was calculated that to achieve statistical power of 80% to detect differences between the two conditions, a minimum of seven subjects should complete both experimental trials. A two-way ANOVA for repeated measures was used to compare differences in substrate utilization and blood metabolites at different time points. Where significant effects were observed by ANOVA for time x condition interaction, post-hoc comparisons were made with paired t-tests with the Tukey test applied to account for multiple comparisons. TT performance and amount of work completed during glycogen reducing exercise sessions were initially tested for normality using Shapiro-Wilk test. If normality was met, a t-test was used to analyse the data, otherwise the nonparametric Wilcoxon signed-rank test was used. All values are presented as mean ± SD. Statistical significance was set at p < 0.05. Data analysis was performed using SPSS (Version 24; SPSS Inc., Chicago, IL, US), Prism (Version 8; GraphPad Software, San Diego, CA, US) and Microsoft Excel (Microsoft, Redmond, Washington, USA).

The D-max method (26) was used to determine the point when a plateau in excretion of ¹³C atoms had been reached. This point occurred at 21.04 ± 0.87 min. An example of the calculation for one participant can be seen in Figure 1.

Participants completed 1,367 ± 421 and 1,298 ± 571 kJ of work during the glycogen reducing sessions in GLU + MD and FRU + MD, respectively, without any statistically significant differences between the trials (p = 0.662). Neither were there any differences in the number of completed stages at 90, 80, and 70% W_max between all three conditions (p = 0.458).

Results for TT can be seen in Figure 2, Participants finished the TT in 37.41 ± 3.45 (GLU + MD) and 37.96 ± 5.20 min (FRU + MD) without any significant difference between them (p = 0.547).

Ingested and endogenous (i.e., carbohydrates stored in the body before the onset of carbohydrate ingestion during recovery) carbohydrate oxidation rates are presented in Figure 3. There was no difference in total carbohydrate oxidation rates between GLU + MD and FRU + MD (p = 0.080). There was only a main effect of time for overall carbohydrate oxidation (p < 0.001). Based on the findings that oxidation of ingested carbohydrates could only be accurately determined after ~21 min of exercise, statistical analysis for oxidation of ingested and endogenous carbohydrates has only been calculated from 30-min time point onwards. There was a time × condition interaction in ingested carbohydrate oxidation rates (p = 0.003) with higher oxidation rates of ingested carbohydrates at 30 and 45-min time points in FRU + MD as compared to GLU + MD (p < 0.001). Inversely, there was a trend toward higher endogenous carbohydrate oxidation rates in GLU + MD at 30-min time point during SS (time × condition interaction; p = 0.061) Furthermore, there was a tendency for higher fat oxidation rates in GLU + MD vs. FRU + MD (p = 0.054) and an overall main effect of time for fat oxidation (p < 0.001).

There was no difference in oxygen uptake (V∙O₂) (p = 0.157), RPE (p = 0.366) or HR (p = 0.570) between both conditions (Table 1). However, there was a main effect of time for RPE (p < 0.001).

Plasma metabolites (Figure 4) were analyzed separately for the recovery and subsequent exercise bout. Although care was taken to maintain patency of inserted cannulas, it was sometimes not possible to obtain blood samples from all participants. Thus, we were only able to analyse samples for five and six participants' during recovery and the subsequent exercise bout, respectively.

There were no differences in glucose concentrations between trials during recovery (p = 0.163), however there was a main effect of time (p < 0.001). For lactate concentrations there was a significant interaction between condition and time (p = 0.006) and post-hoc analysis showed significantly higher concentrations 1-h (p = 0.03), 2-h (p < 0.001), and 3-h (p = 0.01) into recovery in FRU + MD.

During the SS, there was a condition x time interaction for glucose (p < 0.001). Concentrations of plasma glucose were higher in GLU + MD at 45-min (p < 0.001), 60-min (p < 0.001) and at the end of the TT (p < 0.001), whereas there was only a significant effect of time for lactate (p < 0.001).

There was no difference in GI comfort between trials in any of the measures (p > 0.05). During recovery average values for nausea, stomach fullness and abdominal cramping were 1.0 ± 0.0 and 1.0 ± 0.0; 1.2 ± 0.4 and 1.0 ± 0.1; and 1.6 ± 1.6 and 1.9 ± 1.7 for GLU + MD and FRU + MD, respectively. Average values during exercise for nausea, stomach fullness and abdominal cramping being 1.3 ± 0.4 and 1.2 ± 0.4; 1.0 ± 0.1 and 1.1 ± 0.2; and 1.8 ±1.3 and 1.6 ± 1.0 for GLU + MD and FRU + MD, respectively.