Participants

This study was registered in advance with the University Hospital Medical Information Network Center (UMIN), a system for registering clinical trials (ID: UMIN000046210; URL: https://center6.umin.ac.jp/cgi-open-bin/ctr_e/ctr_view.cgi?recptno = R000052489). This study was conducted according to the guidelines laid down in the Declaration of Helsinki⁽³⁵⁾ and all procedures involving human participants were approved by the Ethics Committee on Human Research of Waseda University (approval number: 2021-306). Written informed consent was obtained from all nineteen participants. They were Japanese (i.e. self-reported ethnicity) healthy, middle-aged women. None of the participants were having habits of continued ‘exercise’ for at least 30 min/d and at least 2 d/week for at least a year.⁽³⁶⁾ However, their activities of daily living evaluated by a questionnaire were relatively active through their occupational and household works. The exclusion criteria of the present study were as follows: age < 30 or >59 years, taking any medication or supplement known to affect substrate metabolism, major illness, current smoker, and body mass that had not been stable for at least 3 months before the study or intention to lose weight during the study, participation in other studies while participating in the present study, history of an immediate allergic reaction to meals (i.e. each food item provided as a test meal in the present study), pregnancy and suspected pregnancy or within a year of parturition.

Study design and experimental protocol

Participants completed two, 1-day laboratory-based trials in random order: a high GI trial and a low GI trial. The lead investigator enrolled the participants in the research and randomly assigned the participants to each experiment in a counterbalanced manner using computer-generated random numbers. The interval between trials was at least 7 d. All trials were conducted during the follicular phase of the menstrual cycle (days 1–10), based on the self-reported onset of menstruation. A schematic illustration of the study protocol is shown in Fig. 1.

Fig. 1. Schematic illustration of the study protocol. GI, glycaemic index; VO₂max, maximum oxygen uptake; LFPQ-J, Leeds Food Preference Questionnaire in Japanese.

In both trials, all participants reported to the laboratory at 08.30 after a 10-h overnight fast (no food or drink, except water). Body mass was measured to the nearest 0⋅1 kg using a digital scale (MC-780A-N, Tanita Corporation, Tokyo, Japan). A heart rate monitor (Polar RCX3, Polar Electro, Kempele, Finland) was then fitted to measure heart rate continuously throughout the trial. After a 10-min seated rest, subjective appetite using a paper-based questionnaire (details in ‘Subjective appetite’), food reward using the LFPQ-J (details in ‘Food reward’), and baseline measurements of a 15-min resting expired gas sample were obtained sequentially. Thereafter, a cannula was inserted into the arm vein, and a fasting venous blood sample was collected in a seated position. The participants then consumed a high or low GI meal at 09.00. Participants were asked to consume the test meal over 20 min (i.e. the last bite was set at 09.20), and the order of food intake in each meal was standardised. Subsequently, they were required to rest for 100 min before performing the exercise. During the 60-min walking exercise on the treadmill at a speed eliciting 50 % of the estimated maximum oxygen uptake (determined from the preliminary test) (11.00–12.00), oxygen uptake, respiratory exchange ratio (RER), fat oxidation rate, and carbohydrate oxidation rate were measured using a stationary gas analyser (Quark RMR, COSMED Co. Ltd., Roma, Italy), and RPEs were assessed periodically.^{(Reference Borg37)} The participants were then asked to sit on a chair in a comfortable position for 60 min from 12.00 to 13.00. Further expired gas samples were collected every 30 min for 15 min prior to walking and were collected continuously throughout the walking and post-walking periods in both trials. Venous blood samples were collected using a cannula to measure the circulating concentrations of glucose, insulin, triglyceride (TG), non-esterified fatty acids (NEFA), glycerol, 3-hydroxybutyrate, total peptide tyrosine tyrosine (PYY), acylated ghrelin, and subjective appetite every 30 min, except during walking, throughout the trial. Furthermore, food rewards using the LFPQ-J were evaluated at 10.00 and 13.00 in both trials. The participants consumed water ad libitum during the first trial, and the volume ingested was replicated in subsequent trials. Average water intake was 366⋅3 ± 143⋅0 ml over 4 h.

Anthropometry

Body mass and body fat percentage were measured to the nearest 0⋅1 kg and 0⋅1 %, respectively, using a digital scale (TANITA MC780, Tanita Corporation, Tokyo, Japan). Height was measured using a stadiometre (YS-OA, Yoshida Seisakusho Ltd., Gifu, Japan) to the nearest 0⋅1 cm. Body mass index was calculated by dividing body mass in kilogrammes by the square of height in metres.

Screening and preliminary tests

Following the anthropometric assessments, the Japanese version of the Three Factor Eating Questionnaire (TFEQ)^{(Reference Adachi, Fujii and Yamagami38)} was conducted (details in ‘Three Factor Eating Questionnaire’). Thereafter, a screening test of the Leeds Food Preference Questionnaire in Japanese (LFPQ-J), which was developed specifically for the Japanese population, was conducted^{(Reference Hiratsu, Thivel, Beaulieu, Finlayson, Nagayama and Kamemoto39)} (details in ‘Food reward’). The purpose of the screening test was to ask participants about the names of the sixteen foods used in the LFPQ-J, their allergies, whether they had ever eaten them, and whether they could eat them. After the screening test, participants practiced the tasks performed on the LFPQ-J. Then, resting heart rate was recorded for 1 min after 5 min of seated resting using a short-range telemetry (Polar RCX3, Polar Electro, Kempele, Finland). After familiarisation with the treadmill (JOG NOW 700, Technogym, Cesena, Italy), each participant was asked to perform a submaximal preliminary exercise test. This test consisted of a 16-min, four-stage incremental walk test to establish the relationship between treadmill speed and oxygen uptake, or heart rate. The initial walking speed was set to 4⋅0 km/h and was increased by 1⋅0 km/h every 4 min. The treadmill inclination was set to 0 % throughout the test. Oxygen uptake, carbon dioxide production, and RER were measured breath-by-breath using a stationary gas analyser (Quark RMR, COSMED, Rome, Italy). Heart rate was measured continuously using a short-range telemetry (Polar RCX3, Polar Electro, Kempele, Finland). Ratings of perceived exertion (RPEs) were recorded during the final 15 s of each stage using the Borg scale.^{(Reference Borg37)} Data from the preliminary exercise test were used to estimate the walking workload (i.e. walking speed) corresponding to 50 % of each participant's estimated maximum oxygen uptake, and this workload was used for the main trials.

Three Factor Eating Questionnaire

The 51-item TFEQ is a self-assessment tool that measures eating behaviour and consists of three factors: cognitive restraint, disinhibition, and hunger.^{(Reference Stunkard and Messick40)} The Japanese version of the TFEQ^{(Reference Adachi, Fujii and Yamagami38)} was used to assess participants’ eating behaviour traits in the present study. Although no clear criteria were provided, a score of 14 for cognitive restraint, 14 for disinhibition, and 7 for hunger were considered elevated.^{(Reference Stunkard and Messick40)}

Standardisation of dietary intake and physical activity

The participants weighed and recorded all the food and drinks consumed the day before each main trial and refrained from drinking alcohol during this period. They replicated their energy intake from the first to the second trial to ensure that it was standardised across trials. Food diaries were analysed using a nutrition analysis software (Excel Eiyoukun Ver 9.0, Kenpakusha, Tokyo, Japan) by a registered dietician to determine the energy intake and macronutrient content of the foods. Participants were asked to avoid strenuous exercise for 1 d before each main trial. They wore a uniaxial accelerometer (Lifecoder-EX, Suzuken Co. Ltd., Nagoya, Japan) on their hips to objectively monitor their daily activities during this period. The reliability of this accelerometer was validated against whole body indirect calorimetry.^{(Reference Kumahara, Schutz, Ayabe, Yoshioka, Yoshitake and Shindo41)} The accelerometer defined eleven levels of activity intensity (0, 0⋅5, and 1–9), with 0 indicating the lowest intensity and 9 indicating the highest intensity. A level of 4 corresponds to an intensity of approximately 3 metabolic equivalents.^{(Reference Kumahara, Schutz, Ayabe, Yoshioka, Yoshitake and Shindo41)} Levels 1–3 correspond to light physical activity, levels 4–6 correspond to moderate physical activity, and levels 7–9 correspond to vigorous physical activity. On the day before each main trial, the participants received text messages from a researcher asking them to replicate their energy intake and physical activity patterns. Their compliance with replicating each main test condition was verified upon arrival at the laboratory during the main trials.

Test meals

The contents of the high GI and low GI meals are presented in Table 1. Briefly, the high GI meal consisted of corn flakes containing granulated sugar, skim milk, white bread, margarine, instant mashed potatoes, and carbonated drinks (GI = 73). The low GI meal comprised brown rice with seasoning, skim milk, yogurt, canned peaches, cherry tomatoes, and apple juice (GI = 41). The energy density of the test meal was 5⋅4 and 2⋅9 kJ/g for the high and low GI meals, respectively. The high and low GI meals were adjusted to contain the same energy (33 kJ/kg body mass) and macronutrient content (1⋅5 g/kg body mass for carbohydrate, 0⋅1 g/kg body mass for fat, and 0⋅3 g/kg body mass for protein). Individual GI values for the foods in the meals were adapted from the International Table of Glycaemic Index and Glycaemic Load Values 2002^{(Reference Foster-Powell, Holt and Brand-Miller42)} and 2008.^{(Reference Atkinson, Foster-Powell and Brand-Miller43)} The GI of all meals was calculated from the weighted mean of the GI values for the food components.^{(Reference Wolever and Jenkins44)}

Table 1. The nutritional contents of the high and low glycaemic index (GI) meals (for a 50 kg participant)

CHO, carbohydrate.

^a Calculated by the method previously described^{(Reference Wolever and Jenkins44)} with GI values from the International Table of Glycaemic Index and Glycaemic Load Values: 2002^{(Reference Foster-Powell, Holt and Brand-Miller42)} and 2008.^{(Reference Atkinson, Foster-Powell and Brand-Miller43)}

Blood collection and analysis

For plasma glucose measurements, blood samples were collected in tubes containing sodium fluoride-EDTA (Venoject 2, Terumo Corporation, Tokyo, Japan) and stored at 4 °C for later analysis. For plasma insulin, total PYY, and glycerol measurements, venous blood samples were collected in dipotassium salt-EDTA tubes (Venoject 2, Terumo Corporation, Tokyo, Japan) and were centrifuged immediately at 1861 g for 10 min at 4 °C. Plasma samples were then removed, aliquoted and stored at −80 °C for later analysis. For plasma-acylated ghrelin measurements, blood samples were immediately transferred to EDTA tubes containing aprotinin (Neo tube, Nipro Corporation, Osaka, Japan) to prevent degradation of ghrelin by proteases and were immediately centrifuged as described above. For serum TG, NEFA, 3-hydroxybutyrate, total cholesterol (Total-C), low-density lipoprotein cholesterol (LDL-C), and high-density lipoprotein cholesterol (HDL-C) measurements, venous blood samples were collected in tubes containing clotting activators for serum isolation (Venoject 2, Terumo Corporation, Tokyo, Japan). The samples were allowed to clot for 30 min at approximately 22–23 °C and then centrifuged at 1861 g for 10 min at 22 °C. Thereafter, the samples were stored at 4 °C for later analysis. Enzymatic colourimetric assays were used to measure plasma glucose (GLU-HK(M), Shino-Test Corporation, Kanagawa, Japan), serum TG (Pure Auto S TG-N, Sekisui Medical Co. Ltd., Tokyo, Japan), serum NEFA (NEFA-HR, Wako Pure Chemical Industries Ltd., Osaka, Japan), serum 3-hydroxybutyrate (KAINOS 3-HB, Kainos Laboratories, Inc., Tokyo, Japan), serum Total-C (Total-C Determiner L TC II, Hitachi Chemical Diagnostics Systems Co Ltd., Tokyo, Japan), serum LDL-C (Matabo Lead LDL-C, Hitachi Chemical Diagnostics Systems Co Ltd., Tokyo, Japan), and serum HDL-C (Matabo Lead HDL-C, Hitachi Chemical Diagnostics Systems Co Ltd., Tokyo, Japan). Enzyme-linked immunosorbent assays (ELISA) were used to measure plasma insulin (Mercodia Insulin ELISA, Mercodia AB, Uppsala, Sweden), total PYY (YK080, Yanaihara Institute Inc., Shizuoka, Japan), plasma glycerol (Glycerol Colorimetric Assay Kit, Cayman Chemical Company, MI, USA), and acylated ghrelin (A05306, Bertin Pharma, Montigny-le-Bretonneux, France). The intra-assay coefficients of variation were 0⋅7 % for glucose, 2⋅2 % for insulin, 1⋅2 % for TG, 0⋅7 % for NEFA, 1⋅3 % for 3-hydroxybutyrate, 0⋅7 % for Total-C, 1⋅0 % for LDL-C, 1⋅2 % for HDL-C, 4⋅2 % for glycerol, 3⋅9 % for total PYY, and 7⋅5 % for acylated ghrelin.

Food reward

Food reward was measured using the LFPQ-J, a computer-based task that assesses the different components of food preference and reward.^{(Reference Hiratsu, Thivel, Beaulieu, Finlayson, Nagayama and Kamemoto39)} The LFPQ-J measures explicit liking and wanting directly and implicit wanting indirectly, using sixteen images of foods that are either high fat savoury, low fat savoury, high fat sweet, or low fat sweet. The sixteen food images used in the present study are presented in Supplementary Table S1.

The LFPQ-J consists of two tasks: single- and paired-food tasks. Food reward was evaluated using the following four parameters: explicit liking, explicit wanting, implicit wanting, and relative preference. In the single-food task, participants were asked to rate the extent to which they thought they were liking or wanting each randomly presented food item on a 100-mm visual analogue scale to measure explicit liking and wanting. Briefly, single-food images were randomly shown to the participant, and participants responded according to the following two questions: ‘How pleasant would it be to taste some of this food now?’ (explicit liking) and ‘How much do you want some of this food now?’ (explicit wanting), anchored at each end with ‘not at all’ and ‘extremely’. In the paired-food trials, each food image was presented in turn with a food image from the other category, and participants were instructed to select the food they ‘most want to eat now’ as quickly as possible. Implicit wanting was measured using the reaction time of the test and selected categories, and relative preference was measured using the number of selections per category.^{(Reference Oustric, Thicel, Dalton, Beaulieu, Gibbons and Hopkins45)} Briefly, a series of food image pairs were presented to participants, who were asked, ‘Which food do you most want to eat now?’. These food pairs were presented in ninety-six pairs, such that all food images from one category were presented with each food from the other categories. The participants were asked to select the food they wanted to eat the most at that moment as quickly and accurately as possible using a keyboard press. The exclusion criteria for response time were shorter than 100 ms or longer than 8000 ms. The frequency of choice and non-choice and the reaction time of each task for each food category were recorded, and the implicit wanting score was calculated using the following formula.^{(Reference Oustric, Thicel, Dalton, Beaulieu, Gibbons and Hopkins45)} A positive score indicates a greater preference for a given food category relative to the alternatives in the task, whereas a negative score indicates the opposite. A score of zero indicates that the category is equally preferred.

$${\rm Frequency}\hbox{-}{\rm weighted}\,{\rm algorithm\colon }\;I_A = \mathop \sum \limits_{i = 1}^{N_{{\rm choice}}} \displaystyle{{\bar{t}} \over {t_i}}-\mathop \sum \limits_{i = 1}^{N_{{\rm non\hyphen}{\rm choice}}} \displaystyle{{\bar{t}} \over {t_i}}$$

where I_A denotes implicit wanting for category A; N _choice denotes the number of times category A was selected; N _non-choice denotes the number of times category A was not selected; and $\bar{t}$ denotes the mean of all reaction times.^{(Reference Oustric, Thicel, Dalton, Beaulieu, Gibbons and Hopkins45)}

For the parameters measured in all food-reward measurements, the fat appeal bias for foods with different fat contents and the taste appeal bias for foods with different tastes were evaluated. Bias scores for fat content and taste were computed by subtracting the mean low fat scores from the mean high fat scores and the mean savoury scores from the mean sweet scores. Positive values indicate a preference for high fat and/or sweet foods; negative values indicate a preference for low fat and/or savoury foods; and a score of 0 indicates an equal preference between fat content and taste categories.^{(Reference Oustric, Thicel, Dalton, Beaulieu, Gibbons and Hopkins45)}

Subjective appetite

Subjective appetite (satiety, fullness, hunger, and prospective food intake) was assessed on a 100-mm visual analogue scale using a paper-based questionnaire (each end of the line represents the most extreme sensation experienced by the participant).^{(Reference Flint, Raben, Blundell and Astrup46)} The overall subjective appetite score was calculated from the results of the four appetite ratings using the following equation: Satiety + fullness + (100 – hunger) + (100 – prospective food intake)/4,^{(Reference Gibbons, Hopkins, Beaulieu, Oustric and Blundell47)} where 100 indicates low appetite and 0 indicates high appetite.

Calculations and statistical analysis

We calculated the required sample size based on data from a previous study^{(Reference Stevenson, Williams, Mash, Phillips and Nute18)} using G*Power 3.1.9.6.^{(Reference Faul, Erdfelder, Lang and Buchner48)} The previous study reported a between-trial difference in the total amount of fat oxidation throughout the exercise (10⋅4 ± 6⋅5 g/h, mean ± sd) between the high GI trial and the low GI trial.^{(Reference Stevenson, Williams, Mash, Phillips and Nute18)} Based on this study with eight participants, we calculated that an estimated total sample size of 11 was needed to provide 80 % power to detect between-trial differences, with an alpha level set at 0⋅05 and a correlation of 0⋅5. This sample size estimation was powered to detect an effect size (ES) of 0⋅94 (Cohen's d), using a paired t-test for comparisons between the two trials. Based on this calculation, nineteen participants were recruited to allow for potential withdrawals. Data were analysed using IBM SPSS Statistics for Windows version 28.0 (IBM Corp., NY, USA). The rates of fat and carbohydrate oxidation and gross energy expenditure were estimated from oxygen uptake and carbon dioxide production using stoichiometric equations.^{(Reference Frayn49)} Total fat and carbohydrate oxidation during the 60-min walking exercise was estimated from the cumulative rate of oxidation for each participant. The total and incremental area under the curve (AUC) were calculated using GraphPad Prism version 9.2.0 for Windows (GraphPad Software Inc., CA, USA). Generalised estimating equations were used to examine the between-trial differences for all parameters. Where values were different at baseline, generalised estimating equations were used to adjust for baseline values when examining differences over time between trials. Where a significant trial-by-time interaction was found, post-hoc pairwise comparisons were performed using the Bonferroni method. Where statistically significant differences in baseline values were found, statistical analysis was performed by adjusting for baseline covariates. The 95 % confidence intervals (95 % CI) for the mean absolute pairwise differences between trials were calculated using the t-distribution and degrees of freedom (n–1). Effect sizes (Cohen's d) were calculated to describe the magnitude of differences between trials. Effect sizes of 0⋅2 are considered the minimum important differences in all outcome measures, 0⋅5 moderate, and 0⋅8 large.^{(Reference Cohen50)} Statistical significance was accepted at the <5 % level. Results are reported as mean ± sd.