Fasted condition in multicomponent training does not affect health parameters in physically active post-menopausal women

RODRIGUES, JHENNYFER A.L.; CUNHA, THAÍS H.A.; FEREZIN, LETÍCIA P.; BUENO-JÚNIOR, CARLOS R.

doi:10.1590/0001-3765202020200988

Abstract

Diet and exercise are the main modifiable factors for cardiovascular disease and may be particularly important in older adults. We investigated the effects of fasting during 12 weeks of multicomponent training in the context of the aging process in physically active post-menopausal women. Method: 25 women (60.6 ± 8.9 years) were randomized into two groups: fed (FED, n=12) or fasted (FASTED, n=13) and submitted to multicomponent training. The participants underwent anthropometric, body composition, blood pressure, biochemical blood and physical fitness assessments. Results: There was a reduction in both groups for waist circumference [FED: 100.4±6.8 and 99.1±7.1 cm before and after the intervention, respectively; F = 4.214, p = 0.048; FASTED: 93.1±10.2 and 92.2±8.4 cm before and after the intervention, respectively; p = 0.039]. No significant changes were observed for the other outcomes. Discussion: The current research results, the first in the context of aging, agree with previous studies that analyzed chronic effects of fasting, showing that fasted exercise training did not improve anthropometric measurements, body composition, or blood markers compared to the fed condition after long-term exercise training. Together, these findings suggest that fasting during multicomponent training does not affect health parameters in physically active post-menopausal women.

Key words
Aging; exercise; metabolism; nutrition

INTRODUCTION

Diet and exercise are the main modifiable factors for cardiovascular disease and may be particularly important in older adults, who are at a higher risk of chronic disease (Atkins et al. 2016ATKINS JL, WHINCUP PH, MORRIS RW, LENNON LT, PAPACOSTA O & WANNAMETHEE SG. 2016. Dietary patterns and the risk of CVD and all-cause mortality in older British men. Br J Nutr 116(7): 1246-1255.). The aging process is associated with increased fat and a reduction in muscle mass, strength, and mobility (Witard et al. 2016WITARD OC, MCGLORY C, HAMILTON DL & PHILLIPS SM. 2016. Growing older with health and vitality: a nexus of physical activity, exercise and nutrition. Biogerontology 17(3): 529-546., Chernoff 2005CHERNOFF R. 2005. Micronutrient requirements in older women. In Am J Clin Nutr 81(5): 1240-1245.). In this sense, current physical activity guidelines for older adults indicate exercise training including aerobic capacity, muscular strength, flexibility, coordination, agility, and balance (AMERICAN COLLEGE OF SPORTS MEDICINE 2009AMERICAN COLLEGE OF SPORTS MEDICINE, CHODZKO-ZAJKO WJ, PROCTOR DN, FIATARONE SINGH MA, MINSON CT, NIGG CR, SALEM GJ & SKINNER JS. 2009. American College of Sports Medicine position stand. Exercise and physical activity for older adults. Med Sci Sports Exerc 41(7): 1510-1530., Bouaziz et al. 2017BOUAZIZ W, VOGEL T, SCHMITT E, KALTENBACH G, GENY B & LANG PO. 2017. Health benefits of aerobic training programs in adults aged 70 and over: a systematic review. Arch Gerontol Geriat 69: 110-127.). In this context, multicomponent training has been demonstrated as more effective for promoting significant improvements in physical fitness than other investigated exercise protocols in women over 50 years of age (Trapé et al. 2017TRAPÉ AA, LIZZI EADS, GONÇALVES TCP, RODRIGUES JAL, TAVARES SS, LACCHINI R & BUENO JÚNIOR CR. 2017. Effect of Multicomponent Training on Blood Pressure, Nitric Oxide, Redox Status, and Physical Fitness in Older Adult Women: Influence of Endothelial Nitric Oxide Synthase (NOS3) Haplotypes. Oxid Med Cell Longev 2017: 2578950: 1-12.).

Changes in dietary pattern have led to higher saturated fat intake, thereby raising cholesterol levels and the chances of developing chronic diseases including obesity, metabolic syndrome, and, consequently, cardiovascular diseases in older people (Nabuco et al. 2018NABUCO HCG, TOMELERI CM, SUGIHARA JUNIOR P, DOS REIS FERNANDES R, CAVALCANTE EF, ANTUNES M & CYRINO ES. 2018. Lower protein and higher carbohydrate intake are related with altering metabolic syndrome components in elderly women: A cross-sectional study. Exper Gerontol 103: 132-137., Trepanowski et al. 2017TREPANOWSKI JF, KROEGER CM, BARNOSKY A, KLEMPEL MC, BHUTANI S, HODDY KK & VARADY KA. 2017. Effect of alternate-day fasting on weight loss, weight maintenance, and cardioprotection among metabolically healthy obese adults: A randomized clinical trial. JAMA Intern Med 177(7): 930-938.). Indeed, Nabuco et al. (2018)NABUCO HCG, TOMELERI CM, SUGIHARA JUNIOR P, DOS REIS FERNANDES R, CAVALCANTE EF, ANTUNES M & CYRINO ES. 2018. Lower protein and higher carbohydrate intake are related with altering metabolic syndrome components in elderly women: A cross-sectional study. Exper Gerontol 103: 132-137. demonstrated an increased risk of developing metabolic syndrome in older women with lower levels of protein intake and/or higher consumption of carbohydrates. Considering the pivotal role of nutrition in training and performance, it is probably important to study training effects in a nutritional context, which is relevant to the aging process.

Although previous studies have investigated alternate-day fasting regimens (Trepanowski et al. 2017TREPANOWSKI JF, KROEGER CM, BARNOSKY A, KLEMPEL MC, BHUTANI S, HODDY KK & VARADY KA. 2017. Effect of alternate-day fasting on weight loss, weight maintenance, and cardioprotection among metabolically healthy obese adults: A randomized clinical trial. JAMA Intern Med 177(7): 930-938.), nutritional profiles for overweight people (Magno et al. 2014MAGNO FC, DA SILVA MS, COHEN L, SARMENTO LD, ROSADO EL & CARNEIRO JR. 2014. Nutritional profile of patients in a multidisciplinary treatment program for severe obesity and preoperative bariatric surgery. Arq Bras Cir Dig 27(1): 31-34.), the effects on health markers during Ramadan fasting (Norouzy et al. 2017NOROUZY A, HASANZADE DALOEE M, KHOSHNASAB AH, KHOSHNASAB A, FARROKHI J, NEMATY M, SAFARIAN M, NEZAFATI P & ALINEZHAD-NAMAGHI M. 2017. Trend of blood pressure in hypertensive and normotensive volunteers during Ramadan fasting. Blood Press Monit 22(5): 253-257.), and the effects of aerobic training in a fasted state (De Bock et al. 2005DE BOCK K, RICHTER EA, RUSSELL AP, EIJNDE BO, DERAVE W, RAMAEKERS M & HESPEL P. 2005. Exercise in the fasted state facilitates fibre type-specific intramyocellular lipid breakdown and stimulates glycogen resynthesis in humans. J Physiol 564(2): 649-660., Van Proeyen et al. 2010VAN PROEYEN K, SZLUFCIK K, NIELENS H, PELGRIM K, DELDICQUE L, HESSELINK M, VAN VELDHOVEN PP & HESPEL P. 2010. Training in the fasted state improves glucose tolerance during fat-rich diet. J Physiol 588(21): 4289-4302.), the influence of multicomponent training in a fasted condition in the context of the aging process is unknown. Furthermore, Kersten et al. (2009)KERSTEN S, LICHTENSTEIN L, STEENBERGEN E, MUDDE K, HENDRIKS HF, HESSELINK MK, SCHRAUWEN P & MÜLLER M. 2009. Caloric restriction and exercise increase plasma ANGPTL4 levels in humans via elevated free fatty acids. Arterioscler Thromb Vasc Biol 29(6): 969-974. reported that physiological stressors, such as fasting and exercise, are required to elicit significantly raised plasma angiopoietin-like protein 4 (ANGPTL4) by an average of 80% in humans, mediated by elevated free fatty acids (FFAs) through activation of ANGPTL4 gene transcription via PPARs and ANGPTL4, which may raise plasma FFAs via stimulation of adipose tissue lipolysis (Kersten et al. 2009KERSTEN S, LICHTENSTEIN L, STEENBERGEN E, MUDDE K, HENDRIKS HF, HESSELINK MK, SCHRAUWEN P & MÜLLER M. 2009. Caloric restriction and exercise increase plasma ANGPTL4 levels in humans via elevated free fatty acids. Arterioscler Thromb Vasc Biol 29(6): 969-974.). In addition, Vendelbo et al. (2015)VENDELBO MH, CHRISTENSEN B, GRØNBÆK SB, HØGILD M, MADSEN M, PEDERSEN SB, JØRGENSEN JO, JESSEN N & MØLLER N. 2015. GH signaling in human adipose and muscle tissue during ‘feast and famine’: amplification of exercise stimulation following fasting compared to glucose administration. Eur J Endocrinol 173(3): 283-290. demonstrated that exercise induced stimulation of GH signaling activity in vivo is amplified by fasting and exercise at the level of SOCS and CISH target gene expression in skeletal muscle and adipose tissue in human subjects, thus GH acts as a critical conservator of protein during catabolic stress. However, these manuscripts are based on the acute effects of exercise. As aforementioned, no study has analyzed the chronic effects of fasting in humans in the context of aging, while in professional practice, there is huge speculation about the potential benefits of exercise training in the fasting condition. Moreover, it was demonstrated that a short period of fasting training (30 days) reduced triglycerides in older people (Oliveira 2013OLIVEIRA BJC. 2013. Alterações lipidémicas e da composição corporal induzidas pelo exercício físico em jejum. Estudo com idosos [thesis on the internet]. Universidade do Porto;[106p.]. Disponível em: ps://sigarra.up.pt/faup/en/pub_geral.pub_view?pi_pub_base_id=23252.
ps://sigarra.up.pt/faup/en/pub_geral.pub... ). As a primary outcome, this study aimed to analyze the influence of 12 weeks of multicomponent training in a fasted condition on body composition, weight loss, and markers of metabolic health in physically active women over 50 years of age. In addition, we compared the intake of micro and macronutrients on different days of the week (a training day, a day without training, and a weekend day) before and after the intervention to determine the effects of fasted versus fed training on food intake, energy, and macronutrient and micronutrient intake.

MATERIALS AND METHODS

Participants

In total, 25 physically active post-menopausal women who participated in the Physical Education for the Elderly Program of the Escola de Educação Física e Esporte de Ribeirão Preto - Universidade de São Paulo (USP) (EEFERP-USP), with at least six months in the program (180 min/week) and a minimum attendance of 75%, signed a written informed consent form and were enrolled in the present study. This study was approved by the Ethics Committee of the Faculdade de Filosofia, Ciências e Letras de Ribeirão Preto da Universidade de São Paulo (CAAE 24579513.4.0000.5407), in accordance with the 1964 Helsinki declaration and its later amendments or comparable ethical standards and according to the norms of Resolution 466/2012 of the National Health Council. The participants were randomized into two groups: FED (n=12) or FASTED (n=13) after two days of baseline evaluations, using Random Allocation Software (Saghaei 2004SAGHAEI M. 2004. Random allocation software for parallel group randomized trials. BMC Medical Res Methodol 4: 1-6.). Moreover, the participants in the fasted group were instructed to begin the fasting period 12 hours before each training session. The adherence to the fast condition was adequate for all participants. The inclusion and exclusion criteria have been previously described (Trapé et al. 2017TRAPÉ AA, LIZZI EADS, GONÇALVES TCP, RODRIGUES JAL, TAVARES SS, LACCHINI R & BUENO JÚNIOR CR. 2017. Effect of Multicomponent Training on Blood Pressure, Nitric Oxide, Redox Status, and Physical Fitness in Older Adult Women: Influence of Endothelial Nitric Oxide Synthase (NOS3) Haplotypes. Oxid Med Cell Longev 2017: 2578950: 1-12.). Briefly, the inclusion criteria were being post-menopausal women. Exclusion criteria were the presence of any medical, mental, or musculoskeletal conditions that could prevent performance of the motor tests and physical training program; body mass index > 35 kg/m2, systolic blood pressure >160 mmHg, maximal diastolic blood pressure >100 mmHg; participation in any other physical exercise program in the six months prior to or during the intervention proposed by this study; and presence <75% in the activities proposed by the intervention (Trapé et al. 2017TRAPÉ AA, LIZZI EADS, GONÇALVES TCP, RODRIGUES JAL, TAVARES SS, LACCHINI R & BUENO JÚNIOR CR. 2017. Effect of Multicomponent Training on Blood Pressure, Nitric Oxide, Redox Status, and Physical Fitness in Older Adult Women: Influence of Endothelial Nitric Oxide Synthase (NOS3) Haplotypes. Oxid Med Cell Longev 2017: 2578950: 1-12.).

Multicomponent training

The duration of the intervention was 12 weeks. Before starting each session, all the participants were asked if they were in a fasting condition or not. All sessions were conducted in the morning (two times per week from 7:30 to 9:00 am) by a physical education professional (blinded to group allocation) and the intensity of the training was controlled by the Subjective Effort Perception Scale (Borg & Noble 1974BORG G & NOBLE BJ. 1974. Perceived exertion. In J. H. Wilmore (Ed). Exerc Sport Sci Rev 2(1): 131-154.), maintaining an intensity between 13 (moderate) and 15 (intense). The characteristics of the multicomponent training have been demonstrated previously (Trapé et al. 2017TRAPÉ AA, LIZZI EADS, GONÇALVES TCP, RODRIGUES JAL, TAVARES SS, LACCHINI R & BUENO JÚNIOR CR. 2017. Effect of Multicomponent Training on Blood Pressure, Nitric Oxide, Redox Status, and Physical Fitness in Older Adult Women: Influence of Endothelial Nitric Oxide Synthase (NOS3) Haplotypes. Oxid Med Cell Longev 2017: 2578950: 1-12.). Briefly, the sessions (90 minutes each) were divided into four parts: (1) warm-up, including dynamic stretching exercises, coordination, and/or balance (about 20 to 30 minutes), (2) strength exercises performed in the form of a circuit using elastics, free weights, and body weight (about 30 to 40 minutes), (3) aerobic and ludic activities (dances or games) (about 20 to 30 minutes), and (4) “back to calm,” relaxation, massage, and stretching exercises (about 10 minutes). The assessment was completed in two visits: the first visit for anthropometric measurements, questionnaires, physical fitness tests, blood pressure measurements, and the second visit for blood collection. After 12 weeks of training, the participants were invited again for the same procedure. The flow of participants and study design are illustrated in Figure 1.

Figure 1
Flow chart and sample design.

Dietary intake, sleep pattern, quality of life, and physical activity level

The participants were asked to complete a 3-day dietary record before and after the intervention on three different days of the week (a training day, a day without training, and a weekend day). Daily energy and macronutrient intakes were analyzed using Dietpro software version 4.0 (Laval University, Quebec). It is noteworthy that the usual diet did not alter for any groups during the study. However, subjects in the fasted group were asked to ingest only water during the physical training sessions and in the twelve hours preceding them.

In addition, sleep quality was evaluated by the Epworth Daytime Sleepiness Scale (Johns 1991JOHNS MW. 1991. A new method for measuring daytime sleepiness: the Epworth sleepiness scale. Sleep 14(6): 540-545.), level of psychological stress by the Inventory of Stress Symptoms (ISS) (Lipp & Guevara 1994LIPP MEN & GUEVARA AJH. 1994. Validação empírica do Inventário de Sintomas de Stress. Estudos Psicol (Campinas) 11(3): 43-49.), quality of life by the SF-36 questionnaire (Ciconelli et al. 1999CICONELLI RM, FERRAZ MB, SANTOS W, MEINÃO I & QUARESMA MR. 1999. Tradução para a língua portuguesa e validação do questionário genérico de avaliação de qualidade de vida SF-36 (Brasil SF-36). Rev Bras Reumatol 39(3): 143-150), and level of physical activity by the International Physical Activity Questionnaire (IPAQ) (Matsudo et al. 2001MATSUDO S, ARAÚJO T, MATSUDO V, ANDRADE D, ANDRADE E, OLIVEIRA L & RAGGION G. 2001. Questionário Internacional de Atividade Física (IPAQ): estudo de validade e reprodutibilidade no Brasil. Rev Bras Ativ Fís Saúde 6(2): 5-18.).

Blood analysis

All tests were performed in the morning (7:00-8:30 am) after 12 h overnight fasting. Before the tests, all volunteers remained seated for approximately five minutes, after which a venous blood sample was performed to verify fasting lipid profile (triglycerides, total cholesterol, HDL-cholesterol, LDL-cholesterol) and serum glucose level. The analyzes were performed in the clinical laboratory of the Faculty of Pharmaceutical Sciences of Ribeirão Preto of the University of São Paulo, by means of an enzymatic analysis kit (Wiener Lab, Argentina) on an automatic device (Konelab 600i, Wiener Lab, Argentina).

Anthropometric measurements and body composition

Height (cm) was measured using a fixed stadiometer (Welmy W200ALCD) with an accuracy of 1.0 mm. Body mass (kg) was evaluated using a digital scale (Filizola PL 31, Filizzola Ltda., Brazil), with an accuracy of 0.1 kg. The body mass index (BMI) was calculated using the formula weight/height² (kg/cm²). The waist circumference measurement was performed at the midpoint between the last costal arch and the iliac crest. Body composition was measured with a tetrapolar bioimpedance analyzer (model HBF-510W, Brazil) (Hasnan et al. 2014HASNAN M, SHAHAR S, ZAITUN MY & AHMAD Z. 2014. Validation of body composition measured by skinfold thickness technique and bioelectrical impedance analysis versus dualenergy X-ray absorptiometry among elderly with sarcopenia. Asian J Gerontol Geriatrics 9: 85-92.).

Physical fitness

The tests used in the current study are specific for older and elderly adults, validated and with normative reference values (Trapé et al. 2017TRAPÉ AA, LIZZI EADS, GONÇALVES TCP, RODRIGUES JAL, TAVARES SS, LACCHINI R & BUENO JÚNIOR CR. 2017. Effect of Multicomponent Training on Blood Pressure, Nitric Oxide, Redox Status, and Physical Fitness in Older Adult Women: Influence of Endothelial Nitric Oxide Synthase (NOS3) Haplotypes. Oxid Med Cell Longev 2017: 2578950: 1-12.). Aerobic capacity was evaluated by the six-minute walk test, the strength of upper limbs was evaluated by the elbow extension-flexion and handgrip test, and the strength of lower limbs was evaluated by the sit and stand up from a chair test.

Statistical analysis

Normally distributed variables were tested and confirmed by the Kolmogorov-Smirnov test, enabling the description of data as mean ± standard deviation. Non-normally distributed variables are presented as median (interquartile range). In order to assess differences before and after the intervention, as well as between groups (FED and FASTED), a repeated measure analysis of variance (ANOVA) with fixed factors (i.e., ‘condition’ and ‘time of response’) or the Kruskal-Wallis test was performed. Bonferroni’s post hoc test was applied to determine the differences between conditions and time points. The statistical analysis was performed using Sigma Stat software version 3.1 and the level of significance was set at p-value <0.05.

RESULTS

The mean (SD) age of the participants was 60.6±8.9 years. Table I presents the anthropometric characteristics, body composition, and blood analysis between the groups before and after the multicomponent training. Both groups presented a reduction in waist circumference [F = 4.214, p = 0.048 (FED) and p = 0.039 (FASTED)].

Thumbnail

Table I
Anthropometric, body composition, and blood analysis characteristics between the fed and fasted conditions before and after the multicomponent training intervention.

Table II shows the physical tests, level of physical activity, level of sleepiness during the day, level of stress, and quality of life. There was no effect of time, group, or interaction between the groups before and after the training period for these variables.

Thumbnail

Table II
Characteristics of physical abilities and participant questionnaires between the fed and fasted conditions before and after the multicomponent training intervention.

The changes in energy intake are shown in Figure 2a. Increased energy intake was observed on the weekend day only in the fasted group (F = 4.536, p = 0.026). Macronutrient intake, comparing the fed and fasted conditions, before and after the multicomponent training, on different days of the week, is also shown in Figure 2. Increased intake of carbohydrates was observed after the training period on the weekend day only in the fasted group (F = 4.340, p = 0.027) (Figure 2b). In addition, there was increased intake of protein in the fasted group on the training day (F = 11.397, p = 0.011). In the baseline condition, the intake of protein was higher in the fed group compared to the fasted group on the weekend day (F = 3.480, p = 0.049) (Figure 2c). Finally, there was increased intake of lipids in the fed group on the training day (F = 5.869, p = 0.011) (Figure 2d).

Figure 2
TD: training day; DWT: day without training; WDWT: weekend day without training. Two-way ANOVA for repeated measurements. Data presented as mean ± standard deviation. p <0.05. *against pre in the same group. #against fed at the same time.

Table III presents the intake of micronutrients between the fed and fasted conditions before and after the multicomponent training intervention on different days of the week. Increased intake of zinc was observed in both groups on the training day [F = 28.616, p = 0.014 (FED) and p < 0.001 (FASTED)]. Iron intake reduced only in the fed group on the weekend day (F = 5.081, p = 0.006). In counterpart, an increase in folic acid intake was observed only in the fasted group on the weekend day (F = 9.327, p = 0.010). The intake of sodium was different between the groups after the multicomponent training, being higher in the fed group compared to the fasted group during the day without training (F = 4.681, p = 0.042). Intake of vitamin D increased in the fed group on the training day (F = 10.503, p = 0.013), while the intake of vitamin A reduced in the fed group on the day without training (F = 9.882, p = 0.024).

Thumbnail

Table III
Micronutrient intake of participants between the fed and fasted conditions before and after the multicomponent training intervention on different days of the week.

DISCUSSION

The results of this study demonstrate that the body composition, weight loss, and health markers of physically active post-menopausal women were similar regardless of whether an individual was fasted or fed during 12 weeks of a multicomponent training intervention. Despite the growing popularity of exercise in the fasted state, to our knowledge, no randomized clinical trials have evaluated its efficacy or compared this regimen before and after 12 weeks of multicomponent exercise in the context of aging. In addition, one innovation of the present study was to analyze the consumption of micro and macronutrients on different days of the week (a training day, a day without training, and a weekend day) before and after the intervention.

In the current research, we observed that fasted exercise training did not improve anthropometric measurements, body composition, or blood markers compared to the fed condition after 12 weeks of multicomponent training (Table I). In addition, our results did not demonstrate any significant differences in physical abilities, physical activity level, stress, quality of life, or mental score between the groups. Only the waist circumference reduced in both groups after the training period (Table II). It is known that the aging process is characterized by several changes in the different components of body composition, especially a decline in muscle mass and subcutaneous fat, with a concomitant increase in visceral fat and intramuscular fat (Cruz-Jentoft et al. 2010CRUZ-JENTOFT AJ, BAEYENS JP, BAUER JM, BOIRIE Y, CEDERHOLM T & LANDI F. 2010. European Working Group on Sarcopenia in Older People. Sarcopenia: European consensus on definition and diagnosis: Report of the European Working Group on Sarcopenia in Older People. Age and Ageing 39(4): 412-423.). Therefore, improving health outcomes or even avoiding deterioration due to the aging process through exercise becomes an important strategy. In addition, it is essential to highlight that the participants in the current study were physically active, which could explain the absence of differences in the health parameters analysed - the trainability principle states that the more fully a person is trained with respect to a given fitness component, the less there remains of that component to be trained in the future (Foster 1998FOSTER C. 1998. Monitoring training in athletes with reference to overtraining syndrome. Med Sci Sports Exerc 30(7): 1164-1168.).

Fasting is characterized by the absence of food and/or energy beverage intake for a period, which may last from several hours to a few weeks (Moro et al. 2016MORO T, TINSLEY G, BIANCO A, MARCOLIN G, PACELLI QF, BATTAGLIA G & PAOLI A. 2016. Effects of eight weeks of time-restricted feeding (16/8) on basal metabolism, maximal strength, body composition, inflammation, and cardiovascular risk factors in resistance-trained males. J Transl Med 14: 290.). Some weight loss studies have used fasting on alternate days as a strategy to change body composition (Trepanowski et al. 2017TREPANOWSKI JF, KROEGER CM, BARNOSKY A, KLEMPEL MC, BHUTANI S, HODDY KK & VARADY KA. 2017. Effect of alternate-day fasting on weight loss, weight maintenance, and cardioprotection among metabolically healthy obese adults: A randomized clinical trial. JAMA Intern Med 177(7): 930-938.). In theory, strategies involving training after an overnight fast might accelerate the loss of body fat, as fasting greatly enhances the aerobic metabolism, promoting fat oxidation during activity (Kang et al. 2013KANG J, RAINES E, ROSENBERG J, RATAMESS N, NACLERIO F & FAIGENBAUM A. 2013. Metabolic responses during postprandial exercise. Res Sports Med 21(3): 240-252.), although some studies have shown an absence of differences. Recently, Schoenfeld et al. (2014)SCHOENFELD BJ, ARAGON AA, WILBORN CD, KRIEGER JW & SONMEZ GT. 2014. Body composition changes associated with fasted versus non-fasted aerobic exercise. J Int Soc Sports Nutr 11(1): 54., for example, did not find differences in body composition changes in young women after four weeks of aerobic exercise performed in the fasted versus fed state, while subjects maintained a caloric deficit. The authors observed no differences between conditions in any outcome measured, regardless of pre-exercise feeding status (Schoenfeld et al. 2014SCHOENFELD BJ, ARAGON AA, WILBORN CD, KRIEGER JW & SONMEZ GT. 2014. Body composition changes associated with fasted versus non-fasted aerobic exercise. J Int Soc Sports Nutr 11(1): 54.).

De Bock et al. (2005)DE BOCK K, RICHTER EA, RUSSELL AP, EIJNDE BO, DERAVE W, RAMAEKERS M & HESPEL P. 2005. Exercise in the fasted state facilitates fibre type-specific intramyocellular lipid breakdown and stimulates glycogen resynthesis in humans. J Physiol 564(2): 649-660. hypothesized that six weeks of endurance training while fasting would increase the relative contribution of fat oxidation to total energy production, for a given absolute workload and exercise duration, even in the presence of carbohydrate intake during exercise. However, the authors showed that neither intramyocellular triglyceride content breakdown nor rate of total fat oxidation was affected by the differential dietary context of the training sessions. Using Diet Pro software, the 3-day diet record was uploaded and provided information on an extensive battery of macro and micronutrient intake data from which 10 were selected (calcium, zinc, iron, acid folic, sodium, vitamin D, vitamin B6, vitamin A, vitamin B12, vitamin C), which may be associated with deficiencies in elderly women. According to the Dietary Guidelines for Americans (Trumbo et al. 2002TRUMBO P, SCHLICKER S, YATES AA & POOS M. 2002. Food and Nutrition Board of the Institute of Medicine, The National Academies. Dietary reference intakes for energy, carbohydrate, fiber, fat, fatty acids, cholesterol, protein and amino acids. J Am Diet Assoc 102(11): 1621-1630.), a healthier eating pattern includes habits based on fruit and vegetable intake and reduction in energy-dense foods. The mean intake of all micronutrients was similar between groups (p>0.05), except for sodium after the training period (Table III).

Van Proeyen et al. (2010)VAN PROEYEN K, SZLUFCIK K, NIELENS H, PELGRIM K, DELDICQUE L, HESSELINK M, VAN VELDHOVEN PP & HESPEL P. 2010. Training in the fasted state improves glucose tolerance during fat-rich diet. J Physiol 588(21): 4289-4302. investigated whether exercise training in the fasted state is more potent than exercise in the fed state to rescue whole-body glucose tolerance and insulin sensitivity during a period of hyper-caloric fat-rich diet. The authors showed that a given amount of endurance training in a fasted state is more potent than training in a fed state to improve glucose tolerance during an episode of dietary lipid challenge (six weeks of high fat diet) (Van Proeyen et al. 2010VAN PROEYEN K, SZLUFCIK K, NIELENS H, PELGRIM K, DELDICQUE L, HESSELINK M, VAN VELDHOVEN PP & HESPEL P. 2010. Training in the fasted state improves glucose tolerance during fat-rich diet. J Physiol 588(21): 4289-4302.). Our results did not demonstrate differences between the groups for glucose levels (Table I). In addition, we showed that the intake of protein was lower in the fasted condition before the intervention compared to the fed group at the same moment on the weekend day and the intake of carbohydrate increased in the fasted group after the intervention on the weekend day. Finally, the fasted group presented increased protein intake on the training day while the fed group increased lipid intake on the training day after the intervention (Figure 2c, d). It is important to highlight that although we did not impose a diet for the participants during the intervention, for all participants the intake of micro and macronutrients was balanced as recommended by the Dietary Reference Intake (Trumbo et al. 2002TRUMBO P, SCHLICKER S, YATES AA & POOS M. 2002. Food and Nutrition Board of the Institute of Medicine, The National Academies. Dietary reference intakes for energy, carbohydrate, fiber, fat, fatty acids, cholesterol, protein and amino acids. J Am Diet Assoc 102(11): 1621-1630.). Regarding the measurement instruments, it is difficult to compare research findings due to the different methodologies used to evaluate nutritional status.

Finally, it is important to state that no individual experienced any discomfort throughout the intervention period. Furthermore, the small sample size is a significant limitation. Besides that, the participants’ blood was collected at least 48h after the last training session on random days. However, this fact does not entirely put away the effect on the blood outcomes of higher energy and carbohydrates intakes during the weekends in the fasted group.

CONCLUSION

In conclusion, the current study, for the first time, shows that multicomponent training in a fasted or fed condition does not affect health parameters in physically active post-menopausal women, except for waist circumference, which reduced in both groups. These results add important information regarding the chronic effects of exercise during fasting for physically active post-menopausal women.

REFERENCES

AMERICAN COLLEGE OF SPORTS MEDICINE, CHODZKO-ZAJKO WJ, PROCTOR DN, FIATARONE SINGH MA, MINSON CT, NIGG CR, SALEM GJ & SKINNER JS. 2009. American College of Sports Medicine position stand. Exercise and physical activity for older adults. Med Sci Sports Exerc 41(7): 1510-1530.
ATKINS JL, WHINCUP PH, MORRIS RW, LENNON LT, PAPACOSTA O & WANNAMETHEE SG. 2016. Dietary patterns and the risk of CVD and all-cause mortality in older British men. Br J Nutr 116(7): 1246-1255.
BORG G & NOBLE BJ. 1974. Perceived exertion. In J. H. Wilmore (Ed). Exerc Sport Sci Rev 2(1): 131-154.
BOUAZIZ W, VOGEL T, SCHMITT E, KALTENBACH G, GENY B & LANG PO. 2017. Health benefits of aerobic training programs in adults aged 70 and over: a systematic review. Arch Gerontol Geriat 69: 110-127.
CHERNOFF R. 2005. Micronutrient requirements in older women. In Am J Clin Nutr 81(5): 1240-1245.
CICONELLI RM, FERRAZ MB, SANTOS W, MEINÃO I & QUARESMA MR. 1999. Tradução para a língua portuguesa e validação do questionário genérico de avaliação de qualidade de vida SF-36 (Brasil SF-36). Rev Bras Reumatol 39(3): 143-150
CRUZ-JENTOFT AJ, BAEYENS JP, BAUER JM, BOIRIE Y, CEDERHOLM T & LANDI F. 2010. European Working Group on Sarcopenia in Older People. Sarcopenia: European consensus on definition and diagnosis: Report of the European Working Group on Sarcopenia in Older People. Age and Ageing 39(4): 412-423.
DE BOCK K, RICHTER EA, RUSSELL AP, EIJNDE BO, DERAVE W, RAMAEKERS M & HESPEL P. 2005. Exercise in the fasted state facilitates fibre type-specific intramyocellular lipid breakdown and stimulates glycogen resynthesis in humans. J Physiol 564(2): 649-660.
FOSTER C. 1998. Monitoring training in athletes with reference to overtraining syndrome. Med Sci Sports Exerc 30(7): 1164-1168.
HASNAN M, SHAHAR S, ZAITUN MY & AHMAD Z. 2014. Validation of body composition measured by skinfold thickness technique and bioelectrical impedance analysis versus dualenergy X-ray absorptiometry among elderly with sarcopenia. Asian J Gerontol Geriatrics 9: 85-92.
JOHNS MW. 1991. A new method for measuring daytime sleepiness: the Epworth sleepiness scale. Sleep 14(6): 540-545.
KANG J, RAINES E, ROSENBERG J, RATAMESS N, NACLERIO F & FAIGENBAUM A. 2013. Metabolic responses during postprandial exercise. Res Sports Med 21(3): 240-252.
KERSTEN S, LICHTENSTEIN L, STEENBERGEN E, MUDDE K, HENDRIKS HF, HESSELINK MK, SCHRAUWEN P & MÜLLER M. 2009. Caloric restriction and exercise increase plasma ANGPTL4 levels in humans via elevated free fatty acids. Arterioscler Thromb Vasc Biol 29(6): 969-974.
LIPP MEN & GUEVARA AJH. 1994. Validação empírica do Inventário de Sintomas de Stress. Estudos Psicol (Campinas) 11(3): 43-49.
MAGNO FC, DA SILVA MS, COHEN L, SARMENTO LD, ROSADO EL & CARNEIRO JR. 2014. Nutritional profile of patients in a multidisciplinary treatment program for severe obesity and preoperative bariatric surgery. Arq Bras Cir Dig 27(1): 31-34.
MATSUDO S, ARAÚJO T, MATSUDO V, ANDRADE D, ANDRADE E, OLIVEIRA L & RAGGION G. 2001. Questionário Internacional de Atividade Física (IPAQ): estudo de validade e reprodutibilidade no Brasil. Rev Bras Ativ Fís Saúde 6(2): 5-18.
MORO T, TINSLEY G, BIANCO A, MARCOLIN G, PACELLI QF, BATTAGLIA G & PAOLI A. 2016. Effects of eight weeks of time-restricted feeding (16/8) on basal metabolism, maximal strength, body composition, inflammation, and cardiovascular risk factors in resistance-trained males. J Transl Med 14: 290.
NABUCO HCG, TOMELERI CM, SUGIHARA JUNIOR P, DOS REIS FERNANDES R, CAVALCANTE EF, ANTUNES M & CYRINO ES. 2018. Lower protein and higher carbohydrate intake are related with altering metabolic syndrome components in elderly women: A cross-sectional study. Exper Gerontol 103: 132-137.
NOROUZY A, HASANZADE DALOEE M, KHOSHNASAB AH, KHOSHNASAB A, FARROKHI J, NEMATY M, SAFARIAN M, NEZAFATI P & ALINEZHAD-NAMAGHI M. 2017. Trend of blood pressure in hypertensive and normotensive volunteers during Ramadan fasting. Blood Press Monit 22(5): 253-257.
OLIVEIRA BJC. 2013. Alterações lipidémicas e da composição corporal induzidas pelo exercício físico em jejum. Estudo com idosos [thesis on the internet]. Universidade do Porto;[106p.]. Disponível em: ps://sigarra.up.pt/faup/en/pub_geral.pub_view?pi_pub_base_id=23252
» ps://sigarra.up.pt/faup/en/pub_geral.pub_view?pi_pub_base_id=23252
SAGHAEI M. 2004. Random allocation software for parallel group randomized trials. BMC Medical Res Methodol 4: 1-6.
SCHOENFELD BJ, ARAGON AA, WILBORN CD, KRIEGER JW & SONMEZ GT. 2014. Body composition changes associated with fasted versus non-fasted aerobic exercise. J Int Soc Sports Nutr 11(1): 54.
TRAPÉ AA, LIZZI EADS, GONÇALVES TCP, RODRIGUES JAL, TAVARES SS, LACCHINI R & BUENO JÚNIOR CR. 2017. Effect of Multicomponent Training on Blood Pressure, Nitric Oxide, Redox Status, and Physical Fitness in Older Adult Women: Influence of Endothelial Nitric Oxide Synthase (NOS3) Haplotypes. Oxid Med Cell Longev 2017: 2578950: 1-12.
TREPANOWSKI JF, KROEGER CM, BARNOSKY A, KLEMPEL MC, BHUTANI S, HODDY KK & VARADY KA. 2017. Effect of alternate-day fasting on weight loss, weight maintenance, and cardioprotection among metabolically healthy obese adults: A randomized clinical trial. JAMA Intern Med 177(7): 930-938.
TRUMBO P, SCHLICKER S, YATES AA & POOS M. 2002. Food and Nutrition Board of the Institute of Medicine, The National Academies. Dietary reference intakes for energy, carbohydrate, fiber, fat, fatty acids, cholesterol, protein and amino acids. J Am Diet Assoc 102(11): 1621-1630.
VAN PROEYEN K, SZLUFCIK K, NIELENS H, PELGRIM K, DELDICQUE L, HESSELINK M, VAN VELDHOVEN PP & HESPEL P. 2010. Training in the fasted state improves glucose tolerance during fat-rich diet. J Physiol 588(21): 4289-4302.
VENDELBO MH, CHRISTENSEN B, GRØNBÆK SB, HØGILD M, MADSEN M, PEDERSEN SB, JØRGENSEN JO, JESSEN N & MØLLER N. 2015. GH signaling in human adipose and muscle tissue during ‘feast and famine’: amplification of exercise stimulation following fasting compared to glucose administration. Eur J Endocrinol 173(3): 283-290.
WITARD OC, MCGLORY C, HAMILTON DL & PHILLIPS SM. 2016. Growing older with health and vitality: a nexus of physical activity, exercise and nutrition. Biogerontology 17(3): 529-546.

Publication Dates

Publication in this collection
14 Dec 2020
Date of issue
2020

History

Received
30 June 2020
Accepted
26 Oct 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AMERICAN COLLEGE OF SPORTS MEDICINE, CHODZKO-ZAJKO WJ, PROCTOR DN, FIATARONE SINGH MA, MINSON CT, NIGG CR, SALEM GJ & SKINNER JS. 2009. American College of Sports Medicine position stand. Exercise and physical activity for older adults. Med Sci Sports Exerc 41(7): 1510-1530.

[2] ATKINS JL, WHINCUP PH, MORRIS RW, LENNON LT, PAPACOSTA O & WANNAMETHEE SG. 2016. Dietary patterns and the risk of CVD and all-cause mortality in older British men. Br J Nutr 116(7): 1246-1255.

[3] BORG G & NOBLE BJ. 1974. Perceived exertion. In J. H. Wilmore (Ed). Exerc Sport Sci Rev 2(1): 131-154.

[4] BOUAZIZ W, VOGEL T, SCHMITT E, KALTENBACH G, GENY B & LANG PO. 2017. Health benefits of aerobic training programs in adults aged 70 and over: a systematic review. Arch Gerontol Geriat 69: 110-127.

[5] CHERNOFF R. 2005. Micronutrient requirements in older women. In Am J Clin Nutr 81(5): 1240-1245.

[6] CICONELLI RM, FERRAZ MB, SANTOS W, MEINÃO I & QUARESMA MR. 1999. Tradução para a língua portuguesa e validação do questionário genérico de avaliação de qualidade de vida SF-36 (Brasil SF-36). Rev Bras Reumatol 39(3): 143-150

[7] CRUZ-JENTOFT AJ, BAEYENS JP, BAUER JM, BOIRIE Y, CEDERHOLM T & LANDI F. 2010. European Working Group on Sarcopenia in Older People. Sarcopenia: European consensus on definition and diagnosis: Report of the European Working Group on Sarcopenia in Older People. Age and Ageing 39(4): 412-423.

[8] DE BOCK K, RICHTER EA, RUSSELL AP, EIJNDE BO, DERAVE W, RAMAEKERS M & HESPEL P. 2005. Exercise in the fasted state facilitates fibre type-specific intramyocellular lipid breakdown and stimulates glycogen resynthesis in humans. J Physiol 564(2): 649-660.

[9] FOSTER C. 1998. Monitoring training in athletes with reference to overtraining syndrome. Med Sci Sports Exerc 30(7): 1164-1168.

[10] HASNAN M, SHAHAR S, ZAITUN MY & AHMAD Z. 2014. Validation of body composition measured by skinfold thickness technique and bioelectrical impedance analysis versus dualenergy X-ray absorptiometry among elderly with sarcopenia. Asian J Gerontol Geriatrics 9: 85-92.

[11] JOHNS MW. 1991. A new method for measuring daytime sleepiness: the Epworth sleepiness scale. Sleep 14(6): 540-545.

[12] KANG J, RAINES E, ROSENBERG J, RATAMESS N, NACLERIO F & FAIGENBAUM A. 2013. Metabolic responses during postprandial exercise. Res Sports Med 21(3): 240-252.

[13] KERSTEN S, LICHTENSTEIN L, STEENBERGEN E, MUDDE K, HENDRIKS HF, HESSELINK MK, SCHRAUWEN P & MÜLLER M. 2009. Caloric restriction and exercise increase plasma ANGPTL4 levels in humans via elevated free fatty acids. Arterioscler Thromb Vasc Biol 29(6): 969-974.

[14] LIPP MEN & GUEVARA AJH. 1994. Validação empírica do Inventário de Sintomas de Stress. Estudos Psicol (Campinas) 11(3): 43-49.

[15] MAGNO FC, DA SILVA MS, COHEN L, SARMENTO LD, ROSADO EL & CARNEIRO JR. 2014. Nutritional profile of patients in a multidisciplinary treatment program for severe obesity and preoperative bariatric surgery. Arq Bras Cir Dig 27(1): 31-34.

[16] MATSUDO S, ARAÚJO T, MATSUDO V, ANDRADE D, ANDRADE E, OLIVEIRA L & RAGGION G. 2001. Questionário Internacional de Atividade Física (IPAQ): estudo de validade e reprodutibilidade no Brasil. Rev Bras Ativ Fís Saúde 6(2): 5-18.

[17] MORO T, TINSLEY G, BIANCO A, MARCOLIN G, PACELLI QF, BATTAGLIA G & PAOLI A. 2016. Effects of eight weeks of time-restricted feeding (16/8) on basal metabolism, maximal strength, body composition, inflammation, and cardiovascular risk factors in resistance-trained males. J Transl Med 14: 290.

[18] NABUCO HCG, TOMELERI CM, SUGIHARA JUNIOR P, DOS REIS FERNANDES R, CAVALCANTE EF, ANTUNES M & CYRINO ES. 2018. Lower protein and higher carbohydrate intake are related with altering metabolic syndrome components in elderly women: A cross-sectional study. Exper Gerontol 103: 132-137.

[19] NOROUZY A, HASANZADE DALOEE M, KHOSHNASAB AH, KHOSHNASAB A, FARROKHI J, NEMATY M, SAFARIAN M, NEZAFATI P & ALINEZHAD-NAMAGHI M. 2017. Trend of blood pressure in hypertensive and normotensive volunteers during Ramadan fasting. Blood Press Monit 22(5): 253-257.

[20] OLIVEIRA BJC. 2013. Alterações lipidémicas e da composição corporal induzidas pelo exercício físico em jejum. Estudo com idosos [thesis on the internet]. Universidade do Porto;[106p.]. Disponível em: ps://sigarra.up.pt/faup/en/pub_geral.pub_view?pi_pub_base_id=23252
» ps://sigarra.up.pt/faup/en/pub_geral.pub_view?pi_pub_base_id=23252

[21] SAGHAEI M. 2004. Random allocation software for parallel group randomized trials. BMC Medical Res Methodol 4: 1-6.

[22] SCHOENFELD BJ, ARAGON AA, WILBORN CD, KRIEGER JW & SONMEZ GT. 2014. Body composition changes associated with fasted versus non-fasted aerobic exercise. J Int Soc Sports Nutr 11(1): 54.

[23] TRAPÉ AA, LIZZI EADS, GONÇALVES TCP, RODRIGUES JAL, TAVARES SS, LACCHINI R & BUENO JÚNIOR CR. 2017. Effect of Multicomponent Training on Blood Pressure, Nitric Oxide, Redox Status, and Physical Fitness in Older Adult Women: Influence of Endothelial Nitric Oxide Synthase (NOS3) Haplotypes. Oxid Med Cell Longev 2017: 2578950: 1-12.

[24] TREPANOWSKI JF, KROEGER CM, BARNOSKY A, KLEMPEL MC, BHUTANI S, HODDY KK & VARADY KA. 2017. Effect of alternate-day fasting on weight loss, weight maintenance, and cardioprotection among metabolically healthy obese adults: A randomized clinical trial. JAMA Intern Med 177(7): 930-938.

[25] TRUMBO P, SCHLICKER S, YATES AA & POOS M. 2002. Food and Nutrition Board of the Institute of Medicine, The National Academies. Dietary reference intakes for energy, carbohydrate, fiber, fat, fatty acids, cholesterol, protein and amino acids. J Am Diet Assoc 102(11): 1621-1630.

[26] VAN PROEYEN K, SZLUFCIK K, NIELENS H, PELGRIM K, DELDICQUE L, HESSELINK M, VAN VELDHOVEN PP & HESPEL P. 2010. Training in the fasted state improves glucose tolerance during fat-rich diet. J Physiol 588(21): 4289-4302.

[27] VENDELBO MH, CHRISTENSEN B, GRØNBÆK SB, HØGILD M, MADSEN M, PEDERSEN SB, JØRGENSEN JO, JESSEN N & MØLLER N. 2015. GH signaling in human adipose and muscle tissue during ‘feast and famine’: amplification of exercise stimulation following fasting compared to glucose administration. Eur J Endocrinol 173(3): 283-290.

[28] WITARD OC, MCGLORY C, HAMILTON DL & PHILLIPS SM. 2016. Growing older with health and vitality: a nexus of physical activity, exercise and nutrition. Biogerontology 17(3): 529-546.

	Fed		Fasted
	Pre	Post	Pre	Post
Body mass (kg)	80.6±15.0	80.1±15.6	70.9±11.0	70.7±10.8
Height (m)	1.63±0.1		1.59±0.1
BMI (kg/m²)	29.6±2.2	30.1±2.1	28.3±4.3	27.9±4.1
WC (cm)	100.4±6.8	99.1±7.1*	93.1±10.2	92.2±8.4*
FAT (%)	38.1±7.3	37.9±4.0	37.2±8.2	37.4±7.6
BMR (kcal)	1327.6±244.8	1324.9±212.6	1233.3±109.4	1226.8±96.4
Blood glucose (mg/dL)	109.8±35.2	107.2±44.9	106.5±42.4	92.5±12.8
HDL-c (mg/dL)	49.7±13.4	49.8±12.2	52.2±14.4	50.3±13.8
LDL-c (mg/dL)	114.8±20.0	115.1±22.3	116.9±30.0	109.8±33.9
Triglycerides (mg/dL)	143.6±76.8	142.0±70.5	135.2±87.5	144.9±90.2
Cholesterol total (mg/dL)	196.6±20.4	193.5±20.9	196.5±37.1	188.9±30.9

	Fed		Fasted
	Pre	Post	Pre	Post
6 minute walk (m)	544.6±58.4	564.2±69.8	574.9±59.4	578.6±55.7
Sit and stand up (reps)	18.0±5.4	18.5±5.3	16.2±7.0	18.4±5.8
RHGS (KGS)	30.2±5.7	29.8±5.7	28.5±6.7	29.2±6.5
LHGS (KGS)	28.8±9.1	29.3±7.7	26.2±8.2	26.8±7.0
EFE (reps)	22.1±5.1	22.8±4.1	20.7±3.8	21.5±3.3
IPAQ Walk (minute/week)	190.1 (20-790)	170.3 (30-940)	180.3 (30-780)	270.1 (40-970)
Moderate (minute/week)	215.1 (40-840)	305.1 (60-1202)	182.4 (90-1300)	240.1 (30-1420)
Vigorous (minute/week)	40.3 (10-220)	30.2 (10-260)	45.3 (30-185)	33.1 (30-170)
ESS (points)	8.3±3.9	7.7±3.9	6.4±4.8	7.2±4.2
ISS Alert phase (points)	1.6 ±2.5	1.5±1.7	1.2±1.2	1.2±1.5
Phase of resistance and near-exhaustion (points)	1.4±2.2	1.6±2.3	1.2±1.7	0.8±1.3
Exhaustion phase (points)	1.8±2.4	1.8±2.8	1.3±2.1	0.8±1.3
SF36 Physical score (points)	65.7±8.2	66.1±9.5	68.3±3.6	63.9±9.1
Mental score (points)	59.8±11.0	63.0±13.2	60.8±4.3	56.2±7.1

	Fed		Fasted
	Pre	Post	Pre	Post
Calcium TD (mg)	635.7±345.3	467.0±248.6	549.7±367.0	424.6±210.3
Calcium DWT (mg)	738.0±382.6	614.1±251.5	526.5±367.9	537.6±293.3
Calcium WDWT (mg)	573.1±302.4	522.0±166.8	337.8±198.3	496.7±277.9
Zinc TD (mg)	7.6±4.0	11.6±5.8*	5.7±1.9	12.8±5.3*
Zinc DWT (mg)	8.6±2.7	9.0±6.1	7.9±3.6	9.1±5.2
Zinc WDWT (mg)	10.3±4.6	9.0±5.1	8.8±4.8	7.4±4.2
Iron TD (mg)	11.1±4.8	11.9±3.3	10.1±4.6	11.4±3.4
Iron DWT (mg)	10.2±6.1	8.5±2.3	9.3±4.2	8.9±3.2
Iron WDWT (mg)	11.0±3.9	7.5±1.6*	8.7±4.0	8.5±2.9
Folic acid TD (µg)	103.2±73.5	139.9±75.9	106.8±80.1	131.6±64.7
Folic acid DWT (µg)	93.7±47.7	102.7±64.9	121.7±49.8	133.3±77.8
Folic acid WDWT (µg)	88.1±55.5	116.1±32.9	76.7±34.9	124.8±41.3*
Sodium TD (g)	2477.8±1103.2	2707.8±650.1	2475.3±821.8	2446.6±676.0
Sodium DWT (g)	2628.0±447.0	2715.1±820.8	2454.4±626.0	2143.7±644.9#
Sodium WDWT (g)	2411.6±2381.3	2520.8±1005.4	3248.0±3006.2	4569.9±5510.4
Vitamin D TD (µg)	1.5±1.3	5.0±4.6*	2.0±1.9	4.3±4.5
Vitamin D DWT (µg)	2.4±1.5	2.2±2.7	2.5±1.5	3.4±3.2
Vitamin D WDWT (µg)	1.6±1.4	2.0±1.3	7.0±22.7	2.1±1.4
Vitamin B6 TD (mg)	1.4±0.6	1.4±0.6	1.3±0.6	1.6±0.4
Vitamin B6 DWT (mg)	1.3±0.4	1.1±0.6	1.4±0.4	1.3±0.6
Vitamin B6 WDWT (mg)	1.2±0.6	1.2±0.4	1.3±0.6	1.4±0.4
Vitamin A TD (µg)	1055.5±2190.1	442.5±401.3	412.2±212.1	2975.6±9731.1
Vitamin A DWT (µg)	587.7±370.7	310.3±215.1*	500.4±310.3	277.6±128.8
Vitamin A WDWT (µg)	292.8±361.1	386.2±388.4	205.6±94.5	299.3±235.9
Vitamin B12 TD (µg)	13.7±40.5	3.0±2.0	1.5±0.8	3.2±2.5
Vitamin B12 DWT (µg)	2.8±2.3	2.7±2.4	2.0±1.2	2.5±2.2
Vitamin B12 WDWT (µg)	3.0±2.6	2.3±1.5	3.1±2.3	3.2±1.6
Vitamin C TD (mg)	106.8±111.9	105.6±91.6	90.5±82.1	111.2±105.9
Vitamin C DWT (mg)	83.0±67.5	114.7±72.9	89.5±99.7	102.9±63.9
Vitamin C WDWT (mg)	73.8±63.8	77.2±24.8	100.4±70.5	87.3±48.3