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The effects of date seed (Phoenix dactylifera) supplementation on exercise-induced oxidative stress and aerobic and anaerobic performance following high-intensity interval training sessions: a randomised, double-blind, placebo-controlled trial

Published online by Cambridge University Press:  14 July 2022

Elham Moslemi
Affiliation:
Student research committee, Faculty of Nutrition and Food Science, Tabriz University of Medical Sciences, Tabriz, Iran
Parvin Dehghan*
Affiliation:
Nutrition Research Center, Department of Biochemistry and Diet Therapy, Faculty of Nutrition and Food Science, Tabriz University of Medical Sciences, Tabriz, Iran
Mostafa Khani
Affiliation:
Faculty of Physical Education and Sport Sciences, University of Tabriz, Tabriz, Iran
Parvin Sarbakhsh
Affiliation:
Department of Statistics and Epidemiology, School of Public Health, Tabriz University of Medical Sciences, Tabriz, Iran
Bahareh Sarmadi
Affiliation:
Department of Nutrition and Dietetics, Faculty of Medicine and Health Sciences, University Putra Malaysia, 43400, Serdang, Selangor, Malaysia
*
*Corresponding author: Parvin Dehghan, email [email protected]
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Abstract

High-intensity interval training (HIIT) is an efficient method to improve vascular function, maximal oxygen consumption, and muscle mitochondrial capacity. However, acute HIIT overstresses the oxidative system and causes muscle soreness and damage. The aim of the present study was to investigate the effects of date seeds on exercise-induced oxidative stress and aerobic and anaerobic performance following HIIT sessions. Thirty-six physically active men and women aged 18–35 years were assigned to take 26 g/d of date seed powder (DSP, n 18) or wheat bran powder (placebo, n 18) before and after HIIT workouts for 14 d. Total antioxidant capacity (TAC), oxidative stress index (OSI), total oxidant status (TOS), superoxide dismutase (SOD), glutathione peroxidase (GPx), uric acid, malondialdehyde (MDA), and 8-iso-PGF2α were determined at baseline, at the end of the intervention, and 24-h post-intervention. We used the Cooper and running-based anaerobic sprint test to assess aerobic and anaerobic performance at the study’s beginning and end. Independent-samples Student’s t tests, ANCOVA and repeated-measures ANOVA were used to compare the quantitative variables. Positive changes were observed in TAC, TOS, OSI, GPx, MDA and visual analogue scale after intervention and at 24-h post-exercise (P < 0·05). Likewise, peak power and fatigue index were significantly improved in DSP in comparison with the placebo group. Levels of SOD, uric acid, 8-iso-PGF2α, VO2 max and average power were not changed after training. Our results showed that date seed supplementation in active participants performing HIIT bouts ameliorated oxidative stress and improved performance parameters.

Type
Research Article
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

As a highly nutritious food, dates (Phoenix dactylifera) are grown mainly in North Africa and the Middle East. Iran is the second largest producer of date fruits, accounting for 21 % of world production(Reference Zaid and de Wet1). Date seeds are waste products generated in large quantities in the production process of dates. Recently, it has been the focus of growing interest regarding its application as a functional food in both animal studies and clinical trials, owing to its high content of dietary fibre (75–80 g/100 g), antioxidants (phenolic acids (2697–5342 mg of gallic acid equivalents/100 g), total flavonoids (1224–1844 mg of rutin equivalents/100 g) and carotenoids) and considerable amounts of minerals, vitamins, protein and fat(Reference Bouaziz, Abbes and Mokni2,Reference Alem, Ennassir and Benlyas3) . Earlier studies highlighted flavanols (catechin, epicatechin and procyanidins) as the most important polyphenolic compounds found in date seeds(Reference Hilary, Tomás-Barberán and Martinez-Blazquez4). Several studies have reported health benefits of date seeds, including antioxidant activity, anticarcinogenic, antimutagenic and anti-inflammatory effects, as well as the amelioration of hyperglycaemia, hyperlipidaemia, and memory, and learning disorders(Reference Djaoudene, López and Cásedas5Reference Dehghanian, Kalantaripour and Esmaeilpour9). The safety of date seeds has been reported at a dose of 0·5 g/kg/d(Reference Platat, Hilary and Tomas-Barberan10).

High-intensity interval training (HIIT) is a useful exercise condition that facilitates metabolic adaptations improves muscle mitochondrial capacity, vascular function, maximal oxygen consumption, and alleviates hyperglycaemia, cardiometabolic risk factors, and body fat(Reference Kessler, Sisson and Short11Reference Khalafi, Ravasi and Malandish14). However, during a HIIT session, exercise-related physiological responses incline muscles to produce more reactive oxygen species (ROS), which results in the development of oxidative stress(Reference Powers, Nelson and Hudson15). Oxidative stress is regarded as an imbalance between the generation and degradation of reactive molecules that results in predomination of pro-oxidants over antioxidants and disruption of redox signalling and molecular damage(Reference Sies, Berndt and Jones16,Reference Farhangi, Dehghan and Namazi17) . In HIIT sessions, oxidative stress reduces Ca uptake by the sarcoplasmic reticulum, influences muscle contraction, and consequently, causes an acute decrease in physical performance (namely muscle soreness and fatigue)(Reference Vollaard, Shearman and Cooper18).

Antioxidant supplements can reduce exercise-induced oxidative stress. However, the antioxidants effects on exercise performance can be antagonistic which depends on the dose, type and duration of the antioxidant administration. Several studies have shown that isolated bioactive compounds (e.g. vitamin C, vitamin E and lipoic acid) may have adverse effects on signs and adaptive responses to exercise(Reference Gomez-Cabrera, Salvador-Pascual and Cabo19,Reference Vidal, Robinson and Ives20) . In contrast, no evidence of such relations following the consumption of antioxidant-rich foods and/or extracts was reported(Reference Gholami, Antonio and Evans21,Reference Koivisto, Olsen and Paur22) . Furthermore, studies suggest that consuming polyphenols during exercise, regardless of the length of the intervention(Reference McLeay, Barnes and Mundel23), may provide antioxidant protection and thus may minimise the negative physiological responses that occur during and following exercise, like fatigue and muscle pain(Reference Martin-Rincon, Gelabert-Rebato and Galvan-Alvarez24). A study reported a significant increase in urinary polyphenol metabolites as biomarkers of date seed polyphenol intake for up to 24 h in the urine samples(Reference Platat, Hilary and Tomas-Barberan10). Limited clinical trials(Reference Isworo6,Reference Jubayer, Kayshar and Rahaman8,Reference Platat, Hilary and Tomas-Barberan10,Reference Saryono, Rahmawati and Proverawati25) and animal studies(Reference Meqbaali and Saif26Reference Abdelaziz and Ali31) have reported modulating effects of date seed on metabolic parameters, oxidative stress and inflammation. To our knowledge, no previous study has investigated the impact of date seed powder (DSP) supplementation on oxidative stress and aerobic and anaerobic performance in humans performing HIIT. Therefore, this study aimed to examine the effects of date seeds as a rich source of polyphenol antioxidants on oxidative stress markers, muscle pain, and aerobic and anaerobic performance following HIIT.

Materials and methods

Ethical approval

This research was performed following the principles of the Declaration of Helsinki. After a detailed explanation of the study methodology, all volunteer participants signed an informed consent form at the beginning of the study. The ethics committee at Tabriz University of Medical Sciences approved the study plan (IR.TBZMED.REC.1399·1011), which was then registered on the Iranian Registry of Clinical Trials (https://www.irct.ir/) with the number IRCT20150205020965N9.

Participants

Between October and November 2021, thirty-eight healthy and physically active men and women (recreational runners, Image 1) participated in this study. Their eligibility to participate actively in the study was determined by the Physical Activity Readiness Questionnaire (PAR-Q)(Reference Shephard32) under the supervision of a physician. The study protocol followed the Consolidated Standards of Reporting Trials (CONSORT) checklist, and Fig. 1 shows the diagram of the study protocol(Reference Schulz, Altman and Moher33). The inclusion criteria were as follows: male and female aged between 18 and 35 years; physically active subjects based on a) 3 d of vigorous activity (minimum of 20 min/d), or b) 5 d of any combination of walking, vigorous-intensity or moderate-intensity activities (minimum of 600 MET-min.week–1), or c) 5 d of walking or moderate-intensity exercise (for the minimum of 30 min/d); stable BMI (changes of < 3 kg were acceptable) within the last 5 months; BMI of 18·5–25 kg/m2; no HIIT in the past 3 months; and willingness of subjects to participate in this study. The exclusion criteria were as follows: light-intensity activities; a history of chronic diseases such as CVD, thyroid, gastrointestinal, kidney, diabetic, cancer or pancreatic disease; infectious diseases; cognitive disorders; smoking; pregnancy or lactation; anaemia (Hb < 13 g/dl); musculoskeletal injuries; antacids; taking antibiotics; antidiarrhoeals; anti-inflammatory; antihypertensive, or laxative medications, anabolic steroids, ergogenic agents (arginine, carnitine, creatine and caffeine), or other medications during the previous month; subjects with special diets or dietary restrictions; and recent consumption of antioxidants. Also, during the study, if an individual lost more than 10 % of the supplementation packets and did not attend at least 90 % of each week’s training sessions, he/she was considered non-compliant and was consequently excluded from the study.

Image 1. Experimental design.

Fig. 1. Flowchart of study.

Sample size

The sample size was estimated based on the changes in the parameter malondialdehyde (MDA) as the main outcome following Platat et al.(Reference Platat, Hilary and Tomas-Barberan10). Using Stata software (version 16), the sample size in this study was estimated to be at least sixteen subjects for each group, with a power of 90 % and 95 % CI. Based on a 25 % decrease in the level of expected MDA through supplementation and a 10 % dropout rate for each group, the sample size in each group increased to 18.

Randomisation and allocation concealment

After a run-in period, we used the PAR-Q, which is a pre-study screening questionnaire to assess a person’s medical history, lifestyle, eating habits and physical fitness in several areas(Reference Shephard32). When the participant answered ‘yes’ to a question on the questionnaire, he or she was excluded from the study. According to the PAR-Q analysis, thirty-six eligible volunteers from Tabriz stadiums were randomly allocated to the intervention group (DSP, n 18) and the placebo group (n 18) for 14 d. The randomisation procedure was performed into the two groups (1:1) following stratified randomisation based on sex and VO2 max. We used random allocation software to perform randomised blocks of sizes 2 and 4. To ensure blinding of the study, a third person allocated the subjects into groups. The main researcher was blinded to the groups of subjects until the end of the analysis.

Intervention

The intervention group received DSP at a dosage of 26 g/d (date seeds, Flavinea Co.) for 14 d according to a pilot study of DSP for 2 weeks in active people (data not reported). The placebo group received the same amount of placebo (wheat bran powder, Nazhvangiah Co.). The powder was divided into two 13-g packages, and it was given to subjects 1 h before HIIT activity and 1 h after HIIT with a cup of water. Both date seed and placebo powder were tasteless, odourless brown powders distributed to participants in identical opaque packages. The powders were delivered to participants weekly for 2 weeks. The main researcher was in daily contact with the subjects via text message to emphasise physical activity maintenance, clarify supplement use problems and ensure compliance. Participants were also given a checklist to tick off after each powder intake to check for non-compliance.

Exercise protocol

Based on the American College of Sports Medicine (ACSM) recommendations for physical activity, a HIIT exercise protocol was established for each participant in both groups(Reference Roy34). The first phase involved habituation to the intensity of the HIIT programme. After consuming DSP or a placebo, the HIIT sessions in the following phases followed the same pattern. The subjects ate a standardised breakfast 2 h before the HIIT session. The intervention was given to subjects 1 h prior to HIIT activity and 1 h later. Subjects participated in a 2-week HIIT programme (five exercise sessions per week; ten sessions during the study period). Each session began with a 15-min warm-up at 50 % heart rate (HR) reserve (including various stretches, flexibility, walking and running). Both groups’ main actives comprised two sessions of three to four repetitions and 30 s of running at 90–100 % of the HR reserve on each repetition. There were 90–180 s of active rest after each repetition and 2·5–4 min of active recovery after each phase, respectively. Also, each session finished with a 5-min cool-down with 45 % HR reserve(Reference Moslemi, Dehghan and Khani35). This strategy has been demonstrated to be effective in causing oxidative stress in physically active individuals(Reference Bogdanis, Stavrinou and Fatouros36).

Also, HR was continuously monitored during the supervised exercise intervention, and participants’ HR was recorded using a Polar heart rate (Polar, RS800CX) to ensure training at the intended intensity. The Karvonen formula was used to calculate the target heart rate zone for each participant, and mean target heart rate was reported:

Max HR = 220 – age

Target Heart Rate = [(max HR – resting HR) × % Intensity)] + resting HR(Reference Goldberg, Elliot and Kuehl37).

Throughout the trial, the research team kept in touch with individuals daily. A blinded researcher conducted the 17-min HIIT sessions about the consumption of DSP or a placebo. All participants were guided to make their cooperative decisions during high-intensity exercise training. The number of sessions attended is used to assess adherence to the training programme.

Primary and secondary outcomes

Changes in total antioxidant capacity (TAC), total oxidant status (TOS), oxidative stress index (OSI), superoxide dismutase (SOD), glutathione peroxidase (GPx), uric acid, MDA, 8-iso-PGF2α and muscle pain are the primary outcomes of the current research. VO2 max, peak power, average power and fatigue index (FI) were considered the secondary outcomes.

Assessment of dietary intake

A dietary protocol was used to check the intake of macronutrients and antioxidants (vitamin A, vitamin C, vitamin E, α- tocopherol, β-carotene, lycopene, β-cryptoxanthin, Zn and Se) to ensure that they were having their habitual diet and were not consuming additional antioxidants via diet. The regular food and beverage intake was assessed using 3-d food records (two weekdays and one weekend) before starting the HIIT protocol and supplements and at the study’s end during the last week(Reference Yang, Kim and Hwang38). At the beginning of the interview, a dietitian informed the participants about the recording procedure and asked them to record their consumed beverages and foods. The information recorded by the subjects during home measurements was standardised and converted to grams and/or millilitres of the foods and/or drinks. The ‘Nutritionist 4’ software (First Databank Inc., Hearst Corp.) was used to analyse the nutritional data.

Characterisation of study subjects

Anthropometric parameters (height, weight and BMI) were assessed at the baseline and at the end of the study. A reliable scale (Seca) was used to measure weight while barefoot and wearing light clothing to the nearest 0·5 kg. A centimetre tape with a precision of 0·1 cm was used to measure height with no shoes. The BMI was calculated by the weight (kg) divided by the height (m) squared. Based on the WHO’s classifications, BMI has been adopted as a measure of nutritional status(39).

We determined their physical activity level using the International Physical Activity Questionnaire (IPAQ – short version)(Reference Ács, Veress and Rocha40). The following formula was used to calculate the physical activity rate: moderate activity = (4·0 × moderate activity minutes’ × d) and vigorous activity = (8·0 × vigorous activity minutes × d). The cut-off levels were divided into three groups based on the IPAQ scoring protocol’s current PA guidelines: 1. Low: some activities were reported but not enough to meet categories 2 or 3, 2. Moderate: 5 or more days of any combination of walking, moderate- or vigorous-intensity activities (at least 600 MET-min.wk–1 accumulatively), and 3. High: 7 or more days of any combination of walking, moderate-intensity, or vigorous-intensity activities (at least 3000 MET-min.wk–1 accumulatively)(Reference Moghaddam, Aghdam and Jafarabadi41). The intensity of pain was quantified using a visual analogue scale (VAS). On a 10-cm ruler, ‘0’ represented the absence of pain and ‘10’ the maximum pain level that active men or women can tolerate(Reference Ueda, Nabetani and Teramoto42). Each participant was instructed to record the VAS at baseline (after the Cooper 12-min run test and running-based anaerobic sprint test), after the intervention, and 24 h later.

Blood samples

Blood samples (10 ml) were collected at three time points: at the beginning, at the end of the study (day 14) and 24 h after that. Blood samples were taken at each time point from the intermediate vein of the forearm into tubes with/without EDTA. Aliquots of plasma were used to analyse TAC and TOS using the colorimetric method (TAC: RANDOX kits; TOS: ZellBio GmbH), and the OSI was calculated using TAC and TOS as follows: OSI = 100 × (TOS/TAC)(Reference Yirün, Kübranur and Şen43). The SOD and GPx activities were determined via a commercially available kit (Randox Laboratories Ltd). Uric acid was measured by using the enzymatic method by an autoanalyser using kits (Pars-Azmoon Co.). Serum levels of 8-iso-PGF2α were determined using an ELISA kit (Abcam). The spectrofluorimeter was used to determine MDA levels (Kontron, model SFM 25A)(Reference Jentzsch, Bachmann and Fürst44).

Aerobic and anaerobic performance parameters

The Cooper 12-min run test was used to measure aerobic endurance. Participants ran continuously for 12 min in the 400-m running track before and after the intervention period, and the next covered distance was used to determine VO2 max using Cooper’s equation(Reference Bandyopadhyay45):

VO2 max (ml/kg/min) = (Distance – 504·9) ÷ 44·73.

We also measured anaerobic endurance prior and subsequent to the intervention using the running-based anaerobic sprint test. The running-based anaerobic sprint test consists of six parallel 35-m sprints separated by a 10-s rest period. Participants completed the running-based anaerobic sprint test, and an electronic timing device automatically recorded the time spent on each attempt. Then, we calculated anaerobic power output using the formula, as well as FI as a measure of performance degradation:

• Power (watts) = (Weight ×Distance2) ÷ Time3

• Peak Power (watts) = the highest power (the fastest sprint)

• Average Power (watts) = the sum of all six values ÷ 6

• FI (watts/s) = (Maximum Power – Minimum Power) ÷ Time spent in six sprints(Reference Adamczyk46).

During the orientation session, all participants were reminded of the importance of performing tests and encouraged to give their all. In the 24 h leading up to the aerobic and anaerobic tests, they were also forbidden from engaging in any strenuous physical activity. Before undertaking exercise tests, all subjects were given a warm-up session for 5 min.

Date seed powder chemical characterisation and antioxidants

A specialised company produced the commercial DSP samples (date seeds, Flavinea Co.). The recommended procedures by the Association of Official Analytical Chemicals were used to determine the chemical analysis(Reference Williams47). The Folin–Ciocalteu colorimetric technique was used to measure the total phenolic content of the samples(Reference Singleton and Rossi48). Likewise, the aluminium chloride colorimetric method was used to assess flavonoid levels(Reference Chang, Yang and Wen49). Table 1 shows the average of the composition and antioxidant properties of the DSP (100 g) that were determined three times.

Table 1. Chemical composition, total phenolic acid and flavonoid content of date seeds and placebo (100 g) and each supplement package

GAE, gallic acid equivalent; QE, quercetin equivalent.

Statistical analysis

The SPSS program version 24 was used to analyse the data. The Shapiro–Wilks test was used to determine the data’s normality. We presented qualitative data as frequency (percent), whereas quantitative data as mean and standard deviation. The independent-samples Student’s t test was used to compare the quantitative variables between groups according to time. Also, ANCOVA was used to compare after intervention between two groups, adjusting for baseline value.

For oxidative stress biomarkers and VAS parameter, which were assessed three times, a repeated-measures ANOVA test was performed and P-value supplement × time in the repeated-measures analysis reflect the effect of the intervention. Statistical significance was defined as a P-value of P < 0·05.

Results

Of thirty-six participants enrolled for trial eligibility, thirty-four subjects completed the study (seventeen in the placebo group and seventeen in the date seed group). One subject was dropped out for poor compliance in the date seed group, and another dropped out for personal reasons in the placebo group. The dropouts did not differ between the two groups, and the participation rate was 94·44 %. No side effects were reported after supplementation with date seeds and placebo. The characteristics of volunteers at baseline were similar in both groups in terms of sex, age, physical activity, HR, BMI and body weight (Table 2), dietary nutritional intake (Table 3), TAC, OSI, SOD, GPx, uric acid, MDA, 8-iso-PGF2α, VAS (Table 4), VO2 max, peak power, average power, and FI (Table 5) (P > 0·05). No significant differences were observed in weight, BMI and the dietary antioxidant intake, as efficient factors on oxidative stress status between groups at the end of the trial (ANCOVA, P > 0·05) (Table 2, Table 3). Based on Table 4, there was a significant supplement × time interaction for TAC, TOS, OSI, GPx, MDA and VAS (for all P < 0·05) and no effect for supplement × time in SOD, uric acid, and 8-iso-PGF2α. Furthermore, we observed a significant main effect for supplementing in TAC, TOS, OSI, GPx, MDA, 8-iso-PGF2α and VAS (for all P < 0·05), whereas there were no changes for SOD and uric acid. TAC, TOS, OSI, SOD, GPx, uric acid, MDA, 8-iso-PGF2α and VAS all showed a significant main effect for time (all P ≤ 0·001).

Table 2. Characteristics of the study participants

PAL, physical activity level, HR, heart rate, THR, target heart rate.

Table 3. Nutritional intakes of subjects at baseline and at the end of the study

(Mean values and standard deviations)

* P < 0·05, ANCOVA for comparison of data after 2 weeks between groups after adjusting for baseline values.

Table 4. Markers of oxidative stress and visual analogue scale status of subjects at baseline, the end of the study and 24 h after intervention

(Mean values and standard deviations)

TAC, total antioxidant capacity; TOS, total oxidant status; OSI, oxidative stress index, SOD, superoxide dismutase; GPx, glutathione peroxidase; MDA, malondialdehyde; VAS, visual analogue scale.

* P < 0·05, repeated-measures ANOVA and P-value supplement × time reflect the effect of the intervention.

P < 0·05, independent-samples Student’s t test for comparison of data between groups at different times of baseline, after 2 weeks and 24 h later.

Table 5. Changes in performance markers of subjects at baseline and the end of the study

(Mean values and standard deviations)

W, watts; W/s, watts/seconds.

* P < 0·05, ANCOVA for comparison of data after 2 weeks between groups and adjusting for baseline values.

P < 0·05, independent-samples Student’s t test for comparison of data between groups at different times of baseline and after 2 weeks.

Our findings showed statistically significant differences in TAC, TOS, OSI, SOD (24 h), GPx, MDA, 8-iso-PGF2α (after) and VAS (24 h) in the date seed group when compared with the placebo. However, there were no differences in SOD (after), uric acid, 8-iso-PGF2α (24 h) and VAS (after) in the date seed group in comparison with the placebo group (Table 4). Figure 2 also, illustrates oxidative stress marker concentrations and VAS from pre- to post-intervention and 24 h after HIIT.

Fig. 2. Concentrations of oxidative stress and muscle pain markers from pre- to post-intervention and after that. TAC, total antioxidant capacity; TOS, total oxidant status; OSI, oxidative stress index; SOD, superoxide dismutase; GPx, glutathione peroxidase; MDA, malondialdehyde; VAS, visual analogue scale. Data are presented as mean ± sd. Error bars represent the standard deviation of the mean. *P < 0·05, repeated-measures ANOVA.

In aerobic and anaerobic performance, just peak power and FI showed significant differences between the two groups at the end of the study (ANCOVA, P < 0·05) (Table 5).

Discussion

The present study investigated the role of DSP on exercise-induced oxidative stress and parameters of performance following HIIT sessions. To our knowledge, this is the first randomised, double-blind, placebo-controlled clinical trial of its kind. Our findings demonstrated that supplementation with DSP for the duration of 2 weeks attenuated oxidative stress and improved exercise performance in men and women performing HIIT bouts.

It has been postulated that exercise, which enhances oxygen consumption considerably, can increase free radicals and oxidative stress(Reference Clarkson and Thompson50). HIIT provokes oxidative stress and lipid peroxidation by increasing NADPH oxidase, xanthine oxidase, phospholipase A2 activity, cytochrome c from the mitochondria and catecholamine oxidation(Reference Bogdanis, Stavrinou and Fatouros36,Reference Kawamura and Muraoka51) . Many adaptations, such as redox signalling cascades and endogenous antioxidant enzyme up-regulation, muscle hypertrophy, glucose uptake by the skeletal muscle, and mitochondrial biogenesis, contribute to the attenuation of oxidative stress following HIIT(Reference Slattery, Bentley and Coutts52). Nonetheless, to achieve ideal recovery time and to strengthen an impaired antioxidant capacity (that accompanies poor performance), supplementation with an antioxidant-rich source like DSP that protects the body from oxidative damage is necessary. In our study, attenuated oxidative stress response following DSP supplementation was indicated by decreased TOS, OSI, MDA, and increased TAC and GPx in the DSP group that can be due to the antioxidative effects of its polyphenolic compounds like flavonoids and/or its ability to enhance endogenous antioxidants. The decreased OSI in the DSP group is indicative of the beneficial effects of date seed on increasing TAC and decreasing TOS in this group. Serum GPx activity was significantly increased in both groups at the end of the study and 24 h after that; however, the increments were more profound (P < 0·05) in the DSP group than the placebo group. GPx is considered a key barrier against ROS as it converts H2O2 to H2O. It is plausible that elevated levels of H2O2 following HIIT sessions stimulated GPx production, which is, in fact, the body’s response to increased oxidative stress. Moreover, our findings demonstrated a significant reduction in MDA concentration in the DSP group in comparison with the placebo group. In summary, GPx defends cellular membranes against peroxidation by eliminating lipid peroxides; likewise, in our study, reduced MDA levels can be linked to enhanced GPx levels(Reference Ighodaro and Akinloye53). What is more, uric acid, as the component of plasma’s antioxidant capacity and a powerful eliminator of peroxynitrite and peroxyl radicals(Reference Regoli and Winston54) did no change in this study. In line with our findings, several animal studies(Reference Meqbaali and Saif26,Reference Hasan and Mohieldein29,Reference Habib and Ibrahim55,Reference Rahmawati, Hapsari and Hidayat56) , human studies(Reference Platat, Hilary and Tomas-Barberan10,Reference Saryono, Rahmawati and Proverawati25) and a systematic review(Reference Saryono and Proverawati27) have reported the beneficial effects of date seed supplementation on the antioxidant defence system under various health conditions. In a study, supplementation of Wistar rats with date seeds (0·75 g/kg, for 7 d) was shown to significantly increase SOD and GPx levels(Reference Rahmawati, Hapsari and Hidayat56). Moreover, Hasan et al. observed significant changes in MDA and SOD levels following 10 ml of aqueous date seed extract/d supplementation in diabetic Wistar rats at the end of 8 weeks(Reference Hasan and Mohieldein29). Following 13 weeks of treatment with a diet comprising 2, 4 or 8 g/kg date seeds, MDA levels attenuated dose-dependently in male Wistar rats(Reference Meqbaali and Saif26). In a study by Saryono et al., date seed supplementation (2·5 g/d for 2 weeks) in postmenopausal women significantly improved MDA, SOD and GPx enzyme activities(Reference Saryono, Rahmawati and Proverawati25). Platat et al. reported that administration of 0·25 g and 0·5 g date seeds/kg acute dose reduced MDA in healthy participants dose-dependently(Reference Platat, Hilary and Tomas-Barberan10). The differences in genotype, the dosage and kind of supplementation, basal oxidative stress status, supplementation duration, and difference in study design explicate the differences in findings.

Date seeds are rich sources of polyphenols(Reference Meqbaali and Saif26,Reference Habib and Ibrahim55,Reference Rahmawati, Hapsari and Hidayat56) , and their polyphenols, particularly their flavonoids, can be responsible for attenuation of the exercise-induced oxidative stress observed in the present study. Although the exact mechanisms through which date seed polyphenols modulate oxidative stress were mainly unexplored, some of the proposed mechanisms can be as follows: scavenging free radicals through chelating and/or reducing metal ions by the OH groups attached to the aromatic ring of polyphenol(Reference Leopoldini, Russo and Toscano57), enhancing the expression of nuclear transcription factor-erythroid 2-related factor 2 as a major transcriptional regulator of antioxidant enzymes such as SOD, CAT, and GPx(Reference Ramyaa and Padma58), impeding the NF-κβ cascade pathway at different steps as inducer of the expression of the target genes including IL-6, IL-2, IL-8, cyclo-oxygenase-2, and inducible nitric oxide synthase(Reference Meng, Xiao and Muhammed59), activating sirtuins 1 to suppresses pro-apoptotic factors and proinflammatory factors by downregulating p53 and NF-κB(Reference Urquiaga and Leighton60), and modulating metabolic endotoxemia involved in oxidative stress and MAPK–NF-κβ cascade pathway(Reference Wu, Luo and Nie61). High oxygen uptake during exercise stimulates ROS production(Reference Ji62). While ROS can support the recovery process(Reference Close, Ashton and Cable63,Reference Gomez-Cabrera, Borrás and Pallardó64) , it has been demonstrated that in the state of impaired antioxidant capacity(Reference Halliwell65), excessive ROS can damage muscles, thereby decreasing exercise performance(Reference Howatson and Van Someren66,Reference Ortega, López and Amaya67) . Theoretically, supplementation with antioxidants would reinforce the antioxidant system of the body, would decrease oxidative stress-induced damage, and consequently would improve performance. Consistently, in the current study, we investigated the effect of DSP supplementation on the markers of performance following HIIT bouts. Our findings indicate that DSP supplementation can significantly increase peak power and decrease pain, which implies enhanced performance following DSP supplementation. Decreased pain and improved power and performance following date seed supplementation can be related to its role in speeding up the recovery from ROS generation.

We also found that DSP can lessen fatigue, as indicated by decreased FI. The positive effect of DSP on exercise-induced fatigue can be related to the ability of its antioxidant content (i.e. polyphenols) to neutralise the reactive species produced by HIIT bouts. In a systematic review and meta-analysis by Blake et al., it was reported that foods rich in polyphenols improve endurance exercise performance in subjects(Reference Blake, Buckley and Coates68). Morgan et al. found that daily consumption of 330 ml of cacao juice (containing high flavanols levels) in recreationally active males for 8 d significantly decreased VAS(Reference Morgan, Wollman and Jackman69). Roberts et al. reported that decaffeinated green tea extract supplementation as a flavanols polyphenol source (571 mg/d for 4 weeks) alongside cycle exercise in recreationally active males improved average power(Reference Roberts, Roberts and Tarpey70). Jo´wko et al. showed non-significant changes in peak power, average power and FI in subjects with cycle sprint following green tea extract (245 mg/d for 4 weeks)(Reference Jówko, Długołęcka and Makaruk71). In another study, da Silva et al. reported that green tea supplementation (500 mg/d for 15 d) reduced muscle damage, but not muscle pain (VAS) in non-trained male subjects(Reference da Silva, Machado and Souza72). A double-blind, randomised clinical trial indicated that epicatechin supplementation (200 mg daily for 4 weeks) resulted in significant VO2 max, average power, peak power and FI changes in recreationally active men and women(Reference Schwarz, Blahnik and Prahadeeswaran73). The different findings may be related to various types of polyphenol, the dosage of supplements, metabolic and psychological characteristics of study participants, the use of different exercise protocols, and fitness levels. It is noteworthy that our analysis on the intake of other dietary antioxidants, like vitamins A, C, E and α-tocopherol, lycopene, β-carotene, β-cryptoxanthin, Zn, and Se, did not show any significant difference between the two groups either at the baseline or at the end of the study, which eliminates any probable intervening effects of dietary antioxidants and endorses the pivotal role of date seed on the amelioration of oxidative stress in individuals performing intensive activities.

HIIT sessions may decline aerobic and anaerobic performance via several mechanisms like changing in stretch fibres, collapsing membrane surrounding the sarcoplasmic reticulum and muscle fibres, damaging excitation–contraction coupling, stimulation of proteolytic enzymes, activating inflammatory response, which can result in muscle edema and pain, and exacerbated muscle function(Reference Peake, Nosaka and Suzuki74,Reference Proske and Allen75) . However, improved oxidative stress and inflammation have been mentioned to decrease the amount of pain and improve exercise performance following HIIT sessions. Other non-oxidative mechanisms can be involved in the performance improvement following date seed supplementation in the present study. For instance, in vitro studies show that polyphenols can act as an adenosine A1-receptor antagonist and present analgesic effects that result in the reduction of effort perception or muscle aches and pains during exercise(Reference Alexander76). Furthermore, it was previously found that polyphenols can reduce the conversion of nitric oxide to peroxynitrite, which probably contributed to increased vasodilation response, improved muscle perfusion and increased oxygenation by increasing nitric oxide bioavailability(Reference Ruiz-Iglesias, Gorgori-González and Massot-Cladera77). While these can explain the favourable effects of date seeds on aerobic and anaerobic performance, further research is required to investigate mechanisms that link polyphenol date seeds with increased exercise performance.

Strengths and limitations

This study’s strengths include its double-blind, placebo-controlled, randomised clinical design, as well as stratification by sex and VO2 max variables, which eliminate inter-individual variance and the participation of volunteers. Another strength of the present study was its novelty, as it is the first clinical experiment that exploited date seed (which could be a waste product) to determine the effects of its supplementation on recreational runners. Application of date seeds as alternative sources for functional foods can minimise the cost of waste management as well as the waste of these valuable by-products. The study’s limitations include using a fixed supplement dose, a short duration and the lack of assessment of the level of polyphenols or flavonoid content, glycemic indices, other hormones, and inflammatory biomarkers. This is knowing that longer-term studies testing DSP, its polyphenols extract, or by-products such as bread or chocolate should be conducted to confirm our findings. In addition, the sample size was calculated based on the decrease in MDA, with 90 % power and 95 % CI. The power achieved for this particular variable was sufficient to provide significant results. However, it appears that a larger sample size and higher power are required to achieve statistical significance for some other variables.

Conclusion

The present double-blind, placebo-controlled clinical trial revealed that date seed supplementation can improve exercise-induced oxidative stress and performance parameters in healthy active subjects. Its findings provided new insights into date seed consumption. Further studies that investigate the effects of DSP in different doses, with longer intervention periods, and with other exercises are needed.

Acknowledgements

The authors would like to thank all the participants who took part in this study. The study was written based on data obtained from the MSc thesis of Moslemi, E.

This work is part of a government-funded project supported by the Tabriz University of Medical Science (grant number: 66809).

Research Project: P. D. M. K. and E. M.; Statistical Analysis: P. S. and E. M.; Manuscript Preparation: P. D. and E. M.; Review and Critique: P. D., M. K., B. S. and E. M.

None of the authors reported a conflict of interest related to the study

References

Zaid, A & de Wet, F (2002) Date Palm Cultivation. https://www.fao.org/3/y4360e/y4360e06.htm Google Scholar
Bouaziz, MA, Abbes, F, Mokni, A, et al. (2017) The addition effect of Tunisian date seed fibers on the quality of chocolate spreads. J Texture Stud 48, 143150.CrossRefGoogle ScholarPubMed
Alem, C, Ennassir, J, Benlyas, M, et al. (2017) Phytochemical compositions and antioxidant capacity of three date (Phoenix dactylifera L.) seeds varieties grown in the South East Morocco. J Saudi Soc Agric Sci 16, 350357.Google Scholar
Hilary, S, Tomás-Barberán, FA, Martinez-Blazquez, JA, et al. (2020) Polyphenol characterisation of Phoenix dactylifera L.(date) seeds using HPLC-mass spectrometry and its bioaccessibility using simulated in-vitro digestion/Caco-2 culture model. Food Chem 311, 125969.CrossRefGoogle Scholar
Djaoudene, O, López, V, Cásedas, G, et al. (2019) Phoenix dactylifera L. seeds: a by-product as a source of bioactive compounds with antioxidant and enzyme inhibitory properties. Food Funct 10, 49534965.CrossRefGoogle Scholar
Isworo, A (2020) Anti-inflammatory activity of date palm seed by down regulating interleukin-1β, TGF-β, cyclooxygenase-1 and-2: a study among middle age women. Saudi Pharm J 28, 10141018.Google Scholar
Ahmed, F, Ahmed, AM & Darwish, HH (2010) Hypoglycemic effect of an extract from date seeds on diabetic rats. Saudi Med J 31, 747751.Google Scholar
Jubayer, F, Kayshar, S & Rahaman, M (2020) Effects of ajwa date seed powder on serum lipids in humans: a randomized, double-blind, placebo-controlled clinical trial. J Herb Med 24, 100409.CrossRefGoogle Scholar
Dehghanian, F, Kalantaripour, TP, Esmaeilpour, K, et al. (2017) Date seed extract ameliorates β-amyloid-induced impairments in hippocampus of male rats. Biom Pharmacother 89, 221226.CrossRefGoogle ScholarPubMed
Platat, C, Hilary, S, Tomas-Barberan, FA, et al. (2019) Urine metabolites and antioxidant effect after oral intake of date (phoenix dactylifera L.) seeds-based products (powder, bread and extract) by human. Nutrients 11, 2489.CrossRefGoogle ScholarPubMed
Kessler, HS, Sisson, SB & Short, KR (2012) The potential for high-intensity interval training to reduce cardiometabolic disease risk. Sports med 42, 489509.CrossRefGoogle ScholarPubMed
Mallol, M, Norton, L, Bentley, DJ, et al. (2020) Physiological response differences between run and cycle high intensity interval training program in recreational middle age female runners. J Sports Sci Med 19, 508.Google ScholarPubMed
Maillard, F, Pereira, B & Boisseau, N (2018) Effect of high-intensity interval training on total, abdominal and visceral fat mass: a meta-analysis. Sports Med 48, 269288.CrossRefGoogle ScholarPubMed
Khalafi, M, Ravasi, AA, Malandish, A, et al. (2022) The impact of high-intensity interval training on postprandial glucose and insulin: a systematic review and meta-analysis. Diabetes Res Clin Pract, 109815.CrossRefGoogle ScholarPubMed
Powers, SK, Nelson, WB & Hudson, MB (2011) Exercise-induced oxidative stress in humans: cause and consequences. Free Radic Biol Med 51, 942950.CrossRefGoogle ScholarPubMed
Sies, H, Berndt, C & Jones, DP (2017) Oxidative stress. Annu Rev Biochem 86, 715748.CrossRefGoogle ScholarPubMed
Farhangi, MA, Dehghan, P & Namazi, N (2020) Prebiotic supplementation modulates advanced glycation end-products (AGEs), soluble receptor for AGEs (sRAGE), and cardiometabolic risk factors through improving metabolic endotoxemia: a randomized-controlled clinical trial. Eur J Nutr 59, 30093021.CrossRefGoogle ScholarPubMed
Vollaard, NB, Shearman, JP & Cooper, CE (2005) Exercise-induced oxidative stress. Sports Med 35, 10451062.CrossRefGoogle ScholarPubMed
Gomez-Cabrera, MC, Salvador-Pascual, A, Cabo, H, et al. (2015) Redox modulation of mitochondriogenesis in exercise. Does antioxidant supplementation blunt the benefits of exercise training? Free radic biol med 86, 3746.CrossRefGoogle ScholarPubMed
Vidal, K, Robinson, N & Ives, SJ (2017) Exercise performance and physiological responses: the potential role of redox imbalance. Physiol rep 5, e13225.CrossRefGoogle ScholarPubMed
Gholami, F, Antonio, J, Evans, C, et al. (2021) Tomato powder is more effective than lycopene to alleviate exercise-induced lipid peroxidation in well-trained male athletes: randomized, double-blinded cross-over study. J Int Soc Sports Nutr 18, 17.CrossRefGoogle ScholarPubMed
Koivisto, AE, Olsen, T, Paur, I, et al. (2019) Effects of antioxidant-rich foods on altitude-induced oxidative stress and inflammation in elite endurance athletes: a randomized controlled trial. PLoS One 14, e0217895.CrossRefGoogle ScholarPubMed
McLeay, Y, Barnes, MJ, Mundel, T, et al. (2012) Effect of New Zealand blueberry consumption on recovery from eccentric exercise-induced muscle damage. J Int Soc Sports Nutr 9, 112.CrossRefGoogle ScholarPubMed
Martin-Rincon, M, Gelabert-Rebato, M, Galvan-Alvarez, V, et al. (2020) Supplementation with a mango leaf extract (Zynamite®) in combination with quercetin attenuates muscle damage and pain and accelerates recovery after strenuous damaging exercise. Nutrients 12, 614.CrossRefGoogle ScholarPubMed
Saryono, S, Rahmawati, E, Proverawati, A, et al. (2017) Effect of antioxidant status and oxidative stress products in pre-menopausal women after treatment with date seed powder (Phoenix dactylifera L.): a study on women in Indonesia. Pak J Nutr 16, 477481.Google Scholar
Meqbaali, AA & Saif, FT (2016) The Potential Antioxidant and Anti-Inflammatory Effects of Date Seed Powder in Rats. https://scholarworks.uaeu.ac.ae/all_theses/473/ (accessed November 2016).Google Scholar
Saryono, S & Proverawati, A (2019) Hepatoprotective effect of date seeds works through the antioxidant mechanism: a systematic review. Ann Trop Med Public Health 22, 301309.CrossRefGoogle Scholar
Saryono, S, Sumeru, A, Proverawati, A, et al. (2018) Decreasing carbon tetrachloride toxicity using date-seed (Phoenix dactylifera L.) steeping in rats. Toxicol Environ Health Sci 10, 139145.CrossRefGoogle Scholar
Hasan, M & Mohieldein, A (2016) In vivo evaluation of anti diabetic, hypolipidemic, antioxidative activities of Saudi date seed extract on streptozotocin induced diabetic rats. J Clinical Diagn: JCDR 10, FF06.Google ScholarPubMed
Saafi, EB, Louedi, M, Elfeki, A, et al. (2011) Protective effect of date palm fruit extract (Phoenix dactylifera L.) on dimethoate induced-oxidative stress in rat liver. Exp Toxicol Pathol 63, 433441.CrossRefGoogle Scholar
Abdelaziz, DH & Ali, SA (2014) The protective effect of Phoenix dactylifera L. seeds against CCl4-induced hepatotoxicity in rats. J Ethnopharmacol 155, 736743.CrossRefGoogle ScholarPubMed
Shephard, RJ (1988) PAR-Q, Canadian Home Fitness Test and exercise screening alternatives. Sports med 5, 185195.CrossRefGoogle ScholarPubMed
Schulz, KF, Altman, DG & Moher, D (2010) CONSORT 2010 statement: updated guidelines for reporting parallel group randomised trials. Trials 11, 18.CrossRefGoogle ScholarPubMed
Roy, BA (2013) High-intensity interval training: efficient, effective, and a fun way to exercise: brought to you by the American college of sports medicine www. acsm. org. ACSM’s Health Fit J 17, 3.Google Scholar
Moslemi, E, Dehghan, P & Khani, M (2022) The effect of date seed (Phoenix dactylifera) supplementation on inflammation, oxidative stress biomarkers, and performance in active people: a blinded randomized controlled trial protocol. Contemp Clin Trials Commun 28, 100951.CrossRefGoogle ScholarPubMed
Bogdanis, G, Stavrinou, P, Fatouros, I, et al. (2013) Short-term high-intensity interval exercise training attenuates oxidative stress responses and improves antioxidant status in healthy humans. Food Chem Toxicol 61, 171177.CrossRefGoogle ScholarPubMed
Goldberg, L, Elliot, DL & Kuehl, KS (1988) Assessment of exercise intensity formulas by use of ventilatory threshold. Chest 94, 9598.CrossRefGoogle ScholarPubMed
Yang, YJ, Kim, MK, Hwang, SH, et al. (2010) Relative validities of 3-day food records and the food frequency questionnaire. Nutr Res Pract 4, 142148.CrossRefGoogle ScholarPubMed
Organization WH (2006) The World Health Report 2006: Working Together for Health. Geneva: World Health Organization.Google Scholar
Ács, P, Veress, R, Rocha, P, et al. (2021) Criterion validity and reliability of the International Physical Activity Questionnaire–Hungarian short form against the RM42 accelerometer. BMC Public Health 21, 110.CrossRefGoogle ScholarPubMed
Moghaddam, MB, Aghdam, FB, Jafarabadi, MA, et al. (2012) The Iranian Version of International Physical Activity Questionnaire (IPAQ) in Iran: content and construct validity, factor structure, internal consistency and stability. World Appl Sci J 18, 10731080.Google Scholar
Ueda, T, Nabetani, T & Teramoto, K (2006) Differential perceived exertion measured using a new visual analogue scale during pedaling and running. J Physiol Anthropol 25, 171177.CrossRefGoogle ScholarPubMed
Yirün, MC, Kübranur, Ü, Şen, NA, et al. (2016) Evaluation of oxidative stress in bipolar disorder in terms of total oxidant status, total antioxidant status, and oxidative stress index. Neuropsychiatry 53, 194.Google Scholar
Jentzsch, AM, Bachmann, H, Fürst, P, et al. (1996) Improved analysis of malondialdehyde in human body fluids. Free Radic Biol Med 20, 251256.CrossRefGoogle ScholarPubMed
Bandyopadhyay, A (2014) Validity of Cooper’s 12-min run test for estimation of maximum oxygen uptake in female university students. Indian J Physiol Pharmacol 58, 184186.Google ScholarPubMed
Adamczyk, J (2011) The estimation of the RAST test usefulness in monitoring the anaerobic capacity of sprinters in athletics. Pol J Sport Tourism 18, 214218.CrossRefGoogle Scholar
Williams, S (1984) Official Methods of Analysis. Arlington, VA: Association of Official Analytical Chemists, Inc.Google Scholar
Singleton, VL & Rossi, JA (1965) Colorimetry of total phenolics with phosphomolybdic-phosphotungstic acid reagents. Am J Enol Vitic 16, 144158.Google Scholar
Chang, C-C, Yang, M-H, Wen, H-M, et al. (2002) Estimation of total flavonoid content in propolis by two complementary colorimetric methods. J Food Drug Anal 10, 3.Google Scholar
Clarkson, PM & Thompson, HS (2000) Antioxidants: what role do they play in physical activity and health? Am J Clin Nutr 72, 637S646S.CrossRefGoogle ScholarPubMed
Kawamura, T & Muraoka, I (2018) Exercise-induced oxidative stress and the effects of antioxidant intake from a physiological viewpoint. Antioxidants 7, 119.CrossRefGoogle ScholarPubMed
Slattery, K, Bentley, D & Coutts, AJ (2015) The role of oxidative, inflammatory and neuroendocrinological systems during exercise stress in athletes: implications of antioxidant supplementation on physiological adaptation during intensified physical training. Sports Med 45, 453471.CrossRefGoogle ScholarPubMed
Ighodaro, O & Akinloye, O (2018) First line defence antioxidants-superoxide dismutase (SOD), catalase (CAT) and glutathione peroxidase (GPX): their fundamental role in the entire antioxidant defence grid. Alexandria J Med 54, 287293.CrossRefGoogle Scholar
Regoli, F & Winston, GW (1999) Quantification of total oxidant scavenging capacity of antioxidants for peroxynitrite, peroxyl radicals, and hydroxyl radicals. Toxicol Appl Pharmacol 156, 96105.CrossRefGoogle ScholarPubMed
Habib, HM & Ibrahim, WH (2011) Effect of date seeds on oxidative damage and antioxidant status in vivo . J Sci Food Agric 91, 16741679.CrossRefGoogle ScholarPubMed
Rahmawati, E, Hapsari, E & Hidayat, A (2016) Antioxidant enzyme status on rat after date seeds (Phoenix dactylifera) steeping treatment. Int J Res Med Sci 4, 18931896.Google Scholar
Leopoldini, M, Russo, N & Toscano, M (2011) The molecular basis of working mechanism of natural polyphenolic antioxidants. Food Chem 125, 288306.CrossRefGoogle Scholar
Ramyaa, P & Padma, VV (2014) Quercetin modulates OTA-induced oxidative stress and redox signalling in HepG2 cells—up regulation of Nrf2 expression and down regulation of NF-κB and COX-2. Biochim Biophys Acta Gen Subj 1840, 681692.CrossRefGoogle ScholarPubMed
Meng, T, Xiao, D, Muhammed, A, et al. (2021) Anti-inflammatory action and mechanisms of resveratrol. Molecules 26, 229.CrossRefGoogle ScholarPubMed
Urquiaga, I & Leighton, F (2000) Plant polyphenol antioxidants and oxidative stress. Biol Res 33, 5564.CrossRefGoogle ScholarPubMed
Wu, M, Luo, Q, Nie, R, et al. (2021) Potential implications of polyphenols on aging considering oxidative stress, inflammation, autophagy, and gut microbiota. Crit Rev Food Sci Nutr 61, 21752193.CrossRefGoogle ScholarPubMed
Ji, LL (1993) Antioxidant enzyme response to exercise and aging. Med Sci Sports Exerc 25, 225231.CrossRefGoogle ScholarPubMed
Close, GL, Ashton, T, Cable, T, et al. (2006) Ascorbic acid supplementation does not attenuate post-exercise muscle soreness following muscle-damaging exercise but may delay the recovery process. Br J Nutr 95, 976981.CrossRefGoogle Scholar
Gomez-Cabrera, MC, Borrás, C, Pallardó, FV, et al. (2005) Decreasing xanthine oxidase-mediated oxidative stress prevents useful cellular adaptations to exercise in rats. J Physiol 567, 113120.CrossRefGoogle ScholarPubMed
Halliwell, B (2006) Reactive species and antioxidants. Redox biology is a fundamental theme of aerobic life. Plant Physiol 141, 312322.CrossRefGoogle ScholarPubMed
Howatson, G & Van Someren, KA (2008) The prevention and treatment of exercise-induced muscle damage. Sports Med 38, 483503.CrossRefGoogle ScholarPubMed
Ortega, DR, López, AM, Amaya, HM, et al. (2021) Tart cherry and pomegranate supplementations enhance recovery from exercise-induced muscle damage: a systematic review. Biol Sport 38, 97.CrossRefGoogle ScholarPubMed
Blake, H, Buckley, J, Coates, A, et al. (2021) Polyphenol consumption and endurance exercise performance: a systematic review and meta-analysis of randomised controlled trials. J Sci Med Sport 24, S42S43.CrossRefGoogle Scholar
Morgan, PT, Wollman, PM, Jackman, SR, et al. (2018) Flavanol-rich cacao mucilage juice enhances recovery of power but not strength from intensive exercise in healthy, young men. Sports 6, 159.CrossRefGoogle Scholar
Roberts, JD, Roberts, MG, Tarpey, MD, et al. (2015) The effect of a decaffeinated green tea extract formula on fat oxidation, body composition and exercise performance. J Int Soc Sports Nutr 12, 19.CrossRefGoogle ScholarPubMed
Jówko, E, Długołęcka, B, Makaruk, B, et al. (2015) The effect of green tea extract supplementation on exercise-induced oxidative stress parameters in male sprinters. Eur J Nutr 54, 783791.CrossRefGoogle ScholarPubMed
da Silva, W, Machado, ÁS, Souza, MA, et al. (2018) Effect of green tea extract supplementation on exercise-induced delayed onset muscle soreness and muscular damage. Physiol behav 194, 7782.CrossRefGoogle ScholarPubMed
Schwarz, NA, Blahnik, ZJ, Prahadeeswaran, S, et al. (2018) (–)-Epicatechin supplementation inhibits aerobic adaptations to cycling exercise in humans. Front nutr 5, 132.CrossRefGoogle ScholarPubMed
Peake, J, Nosaka, KK & Suzuki, K (2005) Characterization of Inflammatory Responses to Eccentric Exercise in Humans. https://ro.ecu.edu.au/ecuworks/2980/ (accessed November 2005).Google Scholar
Proske, U & Allen, TJ (2005) Damage to skeletal muscle from eccentric exercise. Exerc Sport Sci Rev 33, 98104.CrossRefGoogle ScholarPubMed
Alexander, SP (2006) Flavonoids as antagonists at A1 adenosine receptors. Phytother Res: Int J Devoted Pharmacol Toxicol Eval Nat Product Derivative 20, 10091012.CrossRefGoogle ScholarPubMed
Ruiz-Iglesias, P, Gorgori-González, A, Massot-Cladera, M, et al. (2021) Does flavonoid consumption improve exercise performance? Is it related to changes in the immune system and inflammatory biomarkers? A systematic review of clinical studies since 2005. Nutrients 13, 1132.CrossRefGoogle ScholarPubMed
Figure 0

Image 1. Experimental design.

Figure 1

Fig. 1. Flowchart of study.

Figure 2

Table 1. Chemical composition, total phenolic acid and flavonoid content of date seeds and placebo (100 g) and each supplement package

Figure 3

Table 2. Characteristics of the study participants

Figure 4

Table 3. Nutritional intakes of subjects at baseline and at the end of the study(Mean values and standard deviations)

Figure 5

Table 4. Markers of oxidative stress and visual analogue scale status of subjects at baseline, the end of the study and 24 h after intervention(Mean values and standard deviations)

Figure 6

Table 5. Changes in performance markers of subjects at baseline and the end of the study(Mean values and standard deviations)

Figure 7

Fig. 2. Concentrations of oxidative stress and muscle pain markers from pre- to post-intervention and after that. TAC, total antioxidant capacity; TOS, total oxidant status; OSI, oxidative stress index; SOD, superoxide dismutase; GPx, glutathione peroxidase; MDA, malondialdehyde; VAS, visual analogue scale. Data are presented as mean ± sd. Error bars represent the standard deviation of the mean. *P < 0·05, repeated-measures ANOVA.