Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-24T10:47:28.207Z Has data issue: false hasContentIssue false

Estimation of total antioxidant capacity from diet and supplements in US adults

Published online by Cambridge University Press:  15 February 2011

Meng Yang
Affiliation:
Department of Nutritional Sciences, University of Connecticut, 3624 Horsebarn Road Extension Unit 4017, Storrs, CT06269, USA
Sang-Jin Chung
Affiliation:
Department of Foods and Nutrition, Kookmin University, Seoul136-702, South Korea
Chin Eun Chung
Affiliation:
Department of Food and Nutrition, Ansan College, Ansan426-701, South Korea
Dae-Ok Kim
Affiliation:
Department of Food Science and Technology, Institute of Life Science and Resources, Kyung Hee University, Yongin446-701, South Korea
Won O. Song
Affiliation:
Department of Food Science and Human Nutrition, Michigan State University, East Lansing, MI48824, USA
Sung I. Koo
Affiliation:
Department of Nutritional Sciences, University of Connecticut, 3624 Horsebarn Road Extension Unit 4017, Storrs, CT06269, USA
Ock K. Chun*
Affiliation:
Department of Nutritional Sciences, University of Connecticut, 3624 Horsebarn Road Extension Unit 4017, Storrs, CT06269, USA
*
*Corresponding author: O. K. Chun, fax +1 860 486 3674, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Given the importance of dietary antioxidants in reducing the risks of chronic diseases, the present study aimed to estimate the intake of total antioxidant capacity (TAC) from diet and dietary supplements of US adults. We utilised the US Department of Agriculture flavonoid and proanthocyanidin databases, dietary supplement data and food consumption data of 4391 US adults aged 19+ years in the National Health and Nutrition Examination Survey 2001–2. In order to convert the intake data of individual antioxidant compounds to TAC values, the vitamin C equivalent (VCE) of forty-three antioxidant nutrients measured previously was also applied. Daily TAC averaged 503·3 mg VCE/d (approximately 75 % from diet and 25 % from supplements). The energy-adjusted daily TAC level from diet and supplements was higher in women (except for carotenoids), older adults, Caucasian (except for carotenoids), non-alcohol consumers (for vitamin E and proanthocyanidins), subjects with higher income (except for carotenoids) and higher exercise levels than their counterparts (P < 0·05). TAC was positively associated with daily consumption of fruits and fruit juices, vegetables and vegetable products, beverages, wines and teas (P < 0·001). Teas, dietary supplements, and fruits and fruit juices were the major sources of dietary TAC of the US population (28, 25 and 17 %, respectively), while the contribution of vegetables and vegetable products to TAC was minimal ( < 2 %). The present study indicates that antioxidant intake from various diet and supplements contributes to TAC status. TAC levels are different in sociodemographic subgroups of the US population. The relationship between TAC intake and risks of chronic disease warrants further investigation.

Type
Full Papers
Copyright
Copyright © The Authors 2011

Consumption of fruits and vegetables has been associated with a low incidence and mortality rate of various degenerative diseases including CVD(Reference Hertog, Feskens and Hollman1Reference Hertog, Sweetnam and Fehily3) and cancer(Reference Doll4, Reference Hertog, Sweetnam and Fehily5). It is not known which dietary constituents are responsible for this association, but it is often assumed that antioxidants play a significant role in this respect. Plant foods contain a variety of compounds with antioxidant activity, including ascorbic acid, tocopherols, carotenoids and phytochemicals such as flavonoids and procyanidins. Since any single antioxidant may not reflect the total antioxidant power of food, the concept of total antioxidant capacity (TAC) has been introduced(Reference Serafini and Del Rio6). TAC considers the cumulative/synergistic and protective activities of all the antioxidants present in food or body fluids, thus providing an integrated parameter rather than the simple sum of measurable antioxidants.

Recently, the applicability and scientific appropriateness of the TAC concept have been debated due to the fact that plasma TAC may be affected by plasma protein, uric acid and antioxidant enzymes rather than by antioxidant nutrients and their metabolites directly originating from diets(Reference Ghiselli, Serafini and Natella7). Also, dietary TAC does not reflect bioavailability as determined by absorption and excretion. Furthermore, the successful application of this tool is highly dependent on the completeness and validity of dietary intake data as well as on the accuracy of food composition data. Nevertheless, dietary TAC still has a great potential for clinical and public health applications since it exclusively provides the sum of protective activities of dietary antioxidants.

Our research group has recently estimated antioxidant intakes of the US population from diet and dietary supplements by creatively utilising the US Department of Agriculture (USDA) flavonoid databases, food consumption data and dietary supplement data in the National Health and Nutrition Examination Survey (NHANES) 1999–2002(Reference Chun, Chung and Song8Reference Chun, Floegel and Chung10). To expand our knowledge on the contribution of diets to TAC, a dietary TAC database of the US population has been developed and validated for future application in human antioxidant research(Reference Floegel, Kim and Chung11). However, there is no documentation on the assessment of dietary TAC of a free-living US population due to the limited information of valid antioxidant intake data and measured TAC levels of diverse food items(Reference Floegel, Kim and Chung11). Therefore, the present study aimed to provide the baseline dietary TAC estimation of US adults and sociodemographic subgroups as a premise in order to build the foundation for further investigation of disease prevention and health improvement.

Participants and methods

Study population

Individuals aged 19 years and older among the NHANES 2001–2 participants(12) and having reliable and complete diet recall (DR)(Reference van Herpen-Broekmans, Klopping-Ketelaars and Bots13) data as coded by the National Center for Health Statistics(Reference Botman, Moore and Moriarity14) were included in the present study (n 4391). Participants (n 698) with unreliable and incomplete DR were excluded from the study. There were no significant differences in major outcome variables between included and excluded participants. The NHANES has been conducted by the National Center for Health Statistics to obtain nationally representative information on the health and nutritional status of the US population since the 1970s. All interviewed persons were invited to the mobile examination centre, where the 24 h DR (midnight to midnight) and questionnaires on dietary supplement use were administered. Written informed consent was obtained from all participants or proxies, and the survey protocol was approved by the Research Ethics Review Board of the National Center for Health Statistics.

Description of datasets

Details of the datasets used in the present study have been reported in our recent publication(Reference Chun, Floegel and Chung10). Briefly, we created one flavonoid database from two different datasets released in recent years: the USDA database for the flavonoid content of selected foods (2007 update)(15) and the USDA–Iowa State University database on the isoflavone content of foods (2008 update)(16). The combined flavonoid database consisted of twenty-four flavonoid compounds: flavonols (quercetin, kaempferol, myricetin and isorhamnetin), flavones (luteolin and apigenin), flavanones (eriodictyol, hesperetin and naringenin), flavan-3-ols (catechin, epicatechin, theaflavin and thearubigin), anthocyanidins (cyanidin, delphinidin, malvidin, pelargonidin, peonidin and petunidin) and isoflavones (daidzein, genistein, glycitein, biochanin A and formononetin). In order to improve the coverage of the estimated flavonoid intake, we expanded the flavonoid database according to the pre-established protocol that has been described extensively in a separate publication(Reference Chun, Floegel and Chung10). The USDA proanthocyanidin (PA) database(17) released in 2004 complements the USDA flavonoid and isoflavone databases. It contains analytical data generated by the Arkansas Children's Nutrition Center as well as other published analytical data. The PA database includes the food composition data of 205 selected food items for the following PA: monomers, dimers, trimers, 4–6 mers (tetramers, pentamers and hexamers), 7–10 mers (heptamers, octamers, nonamers and decamers) and polymers (degree of polymerisation >10).

Estimation of antioxidant intakes from diet

The calculation of dietary antioxidant intake has been described in detail in our preliminary study(Reference Chun, Floegel and Chung10). In summary, we matched the NHANES food consumption data with the USDA flavonoid database following the same procedure: (1) conversion of food items in NHANES dietary recalls to USDA standard reference codes using the food recipe book and food description data file for NHANES food codes; (2) weight adjustment using moisture content; (3) code modification using the USDA food unit conversion search program; (4) linking food intake data with the flavonoid database. Daily individual flavonoid intake from selected foods was determined by multiplying the content of individual flavonoids (mg aglycone equivalents/100 g food) by the daily consumption (g/d) of the selected food item. Estimated total intake of individual flavonoids was the sum of individual flavonoid intakes from all food sources reported in the 24 h DR. Total flavonoid intake was determined by the summation of the total intake of individual flavonoids. Data on individual participant's daily dietary intakes of antioxidant vitamins are available in the NHANES 2001–2(12, 18).

Estimation of antioxidant intakes from supplements

A dietary supplement is defined by the Dietary Supplement Health and Education Act of 1994 as ‘a product (other than tobacco) intended to supplement the diet that bears or contains one or more of the following dietary ingredients: a vitamin, a mineral, an herb or other botanical, an amino acid or a dietary substance for use by man to supplement the diet by increasing the dietary intake, or a concentrate, metabolite, constituent, extract, or combination of the above ingredients’. The data on dietary supplement use in the NHANES 2001–2 enable investigators to estimate the individual vitamin and mineral intake from dietary supplement use. They provided information about the participants' dietary supplement usage, including supplement counts, supplement records, supplement information, ingredient information and blend information(12). To calculate the intakes of antioxidant nutrients from the supplement, vitamin C, vitamin E, carotenes, Se and flavonoids were selected from the ingredient information file. Next, the nutrient composition table of supplements containing the antioxidants was made using the supplement information file. The antioxidant intakes from the supplements were calculated using the supplement counts file, supplement records file and the nutrient composition table of supplements. Participants in the NHANES 2001–2 were questioned specifically about their use of vitamin and mineral supplements. Even though the NHANES dietary supplement data provides comprehensive information on nutrient intake status of the US population from various dietary supplements, limited information is available on flavonoid composition in those products. Furthermore, flavonoid intake from supplements was reported to be less than 2 % in US adults(Reference Serafini and Del Rio6). Therefore, flavonoid intake from supplements was not included in the present study. Consequently, the present study includes carotenoids, vitamin C and vitamin E from supplements to estimate the total antioxidant intakes.

Analyses of antioxidant capacity of antioxidants

Antioxidant power of individual antioxidant nutrients expressed as vitamin C equivalents (VCE) measured by the 2,2′-azino-bis-3-ethylbenzthiazoline-6-sulphonic acid (ABTS) assay has been documented in our previous study(Reference Floegel, Kim and Chung11). Concisely, antioxidant capacities of forty-three major antioxidant nutrients were measured by the ABTS assay conducted according to Kim et al. (Reference Kim, Chun and Kim19, Reference Kim, Lee and Lee20). These antioxidants include thirty flavonoids (isorhamnetin, eriodictyol, theaflavin, theaflavin 3-gallate, theaflavin 3′-gallate, theaflavin 3,3′-digallate, petunidin, glycitein, quercetin, kaempferol, myricetin, luteolin, apigenin, hesperetin, naringenin, (+)-catechin, (+)-gallocatechin, ( − )-epicatechin, ( − )-epigallocatechin, ( − )-epicatechin 3-gallate, ( − )-epigallocatechin 3-gallate, cyanidin, delphinidin, malvidin, pelargonidin, peonidin, daidzein, genistein, biochanin A and formononetin), four PA (dimers and trimers), six carotenoids (α-carotene, β-carotene, β-cryptoxanthin, lutein, lycopene and zeaxanthin), vitamin E (α-tocopherol and γ-tocopherol) and vitamin C.

Estimation of total antioxidant capacity from diet and supplements

Individual antioxidant intake from diet and supplements was determined by multiplying the content of the individual antioxidants (flavonoids, PA, carotenoids, vitamin C and vitamin E) by the daily consumption of each selected food item. The sum of the individual antioxidant intakes was then calculated by summarising individual antioxidant levels from all food sources reported by 24 h DR and dietary supplement use(Reference Chun, Kim and Smith21). Antioxidant capacity of each antioxidant consumed daily was calculated by multiplying the consumption data of each antioxidant by its respective antioxidant capacity. TAC from diet and dietary supplements was assessed by summing individual antioxidant capacity and then adjusted by daily total intake and energy intake, which was adjusted to TAC per 4184 kJ (1000 kcal). The US adults were subgrouped by sociodemographic and lifestyle variables: age (19–30, 31–50, 51–70 and 70+ years); sex; ethnicity (non-Hispanic white, non-Hispanic black, Mexican-American, others); BMI ( ≤ 20, 20–25, 25–30 and >30 kg/m2); poverty income ratios ( < 1·85, ≥ 1·85); alcohol consumption (yes or no to ‘at least twelve drinks/year’); current smoking (yes or no to ‘current smoking’ and ‘smoked cigarettes, cigars or pipes and/or used chewing tobacco or snuff at least once during the past 30 d’); exercise levels (0, T1, T2 and T3). The exercise levels were expressed as the metabolic equivalent score calculated by combining the intensity level of the leisure-time activities reported, mean duration and frequency.

Statistical analyses

All statistical analyses were carried out with SAS software, release 8.1, 2000 (SAS Institute, Cary, NC, USA) and the Survey Data Analysis for multi-stage sample designs professional software package (SUDAAN, release 8.0.2, 2003; Research Triangle Institute, Raleigh, NC, USA). Sample weights were applied to all analyses to account for the unequal probability of selection, non-coverage and non-response bias resulting from oversampling of low-income persons, adolescents, the elderly, African-Americans and Mexican-Americans.

The variables on individual and total antioxidant intakes were not normally distributed and they were not normally distributed even after any transformation. However, non-parametric methods could not be used in the analyses since SUDAAN does not work for those methods. Arithmetic means of dietary TAC intake from the daily diet and supplements of subpopulations grouped by sociodemographic and lifestyle variables were determined. Standard error of the means was calculated by the linearisation (Taylor series) variance estimation method for population parameters by SUDAAN. Student's t test and ANOVA were used to compare means for interval scale variables and to test overall differences of TAC intakes by sociodemographic and lifestyle variables such as sex, income, smoking, etc. The trends of TAC intakes by weight of specific food groups consumed were tested using linear contrasts after adjustment for sex, age, ethnicity and total energy intake. The χ2 test was applied for assessing the distributions of categorical variables. Multivariate linear regression analyses were performed to determine the extent to which energy-adjusted TAC intake was explained by dietary behaviours and other sociodemographic factors. The contribution of each food group to the daily TAC was calculated as the ratio of the antioxidant intake from that food group to the total intake from all foods. Values in the tables are presented as means with their standard errors.

Results

Daily total antioxidant capacity intake from diet and supplements

Individual antioxidant capacities from diet, supplements and TAC are shown in Table 1. Daily TAC level averages 503·3 mg VCE/d, approximately 75 % from diet and 25 % from supplements. Vitamin C and flavonoids are the top two sources contributing to TAC (41 and 39 %, respectively). When total energy was adjusted, daily individual antioxidant capacity levels from diet and supplements increased with age in both men and women (P for trend < 0·05; except for carotenoids in men), with income (P for trend < 0·05; except for carotenoids) and exercise level (P for trend < 0·05). Energy-adjusted individual antioxidant capacity was higher in women (P < 0·05; except for carotenoids) and in Caucasians (P < 0·05; except for carotenoids) than in their counterparts. Alcohol consumers had higher TAC levels from PA than non-consumers (P < 0·05). In addition, energy-adjusted TAC from diet and supplements were higher in women (P < 0·001), older adults (P < 0·001), Caucasians (P < 0·001) and those with higher income level (P < 0·001) and higher exercise level than in their counterparts (P < 0·001). Alcohol consumption and smoking did not seem to be related to TAC levels. BMI had a weaker association with TAC (P = 0·100) compared with the sociodemographic factors.

Table 1 Total antioxidant capacity (TAC) from diet and supplements of US adults aged 19+ years and its subgroups by sociodemographic and lifestyle factors in the National Health and Nutrition Examination Survey 2001–2

(Mean values with their standard errors)

VCE, vitamin C equivalents; Suppl, supplements; PA, proanthocyanidins; PIR, poverty income ratio; MET, metabolic equivalent.

P values are for overall differences by the t test or ANOVA among males and females, age subgroups, ethnicities, income levels, alcohol consumption, smoking and exercise levels after adjusting for total energy intake: *P < 0·05, **P < 0·01, ***P < 0·001.

Antioxidant capacities of nutrients are expressed as mg VCE/d.

Ratio of the median family income: poverty index. A PIR ≤ 1·30 is required to be eligible for food assistance programs.

§ Yes meant to consume twelve alcoholic beverages or more per year.

Yes meant to have smoked cigarettes, cigars, pipes, or used chewing tobacco or snuff at least once during the past 30 d.

Exercise levels, expressed on the MET score, were calculated by combining the intensity level of the leisure-time activities reported, mean duration and frequency.

Estimated total antioxidant capacity by food group consumption

The consumption of specific food or food groups in relation to daily TAC was investigated by testing TAC levels in non-consumers and tertiles of consumers by major food groups (Table 2). After adjusting for sex, age, ethnicity and total energy intake, TAC levels were positively associated with the daily consumption of fruits and fruit juices, vegetables and vegetable products, beverages, wines and teas (P < 0·001), whereas bread and grain foods were not related to TAC levels (P = 0·724).

Table 2 Dietary total antioxidant capacity (TAC) of US adults aged 19+ years by food or food group consumption: National Health and Nutrition Examination Survey 2001–2

(Mean values with their standard errors)

* All subjects who did not consume the food in 24 h dietary recalls were proposed as group ‘non-consumers’ and all consumers were divided into tertiles by the amount of consumption.

T1, T2 and T3 refer to the first, second and third tertiles among the consumers of food or food group.

Adjusted for sex, age, ethnicity and total energy intake.

§ Beverages include other drinks except wines, teas and fruit juices.

Major total antioxidant capacity sources consumed in US adults

Teas, dietary supplements, fruits and fruit juices, and wines were the major food or food groups of TAC based on the 24 h DR (28, 25, 17 and 5 %, respectively), while vegetables and vegetable products only account for less than 2 %. Fig. 1 elucidates the percentage of the major sources contributing to TAC and the corresponding TAC values. The food list of the major TAC sources is presented in Table 3.

Fig. 1 Major sources of dietary total antioxidant capacity (TAC) in the US population aged 19+ years: the National Health and Nutrition Examination Survey 2001–2, including the dietary TAC value of the major food groups and the percentage the food group contributes to the TAC. VCE, vitamin C equivalents.

Table 3 Top major food items contributing to dietary total antioxidant capacity (TAC) in 19+ years US adults

VCE, vitamin C equivalents; Cum%, cumulative percentage; NS, not specified.

* The percentage of the food item contributing to dietary TAC.

Cum% of the food items contributing to dietary TAC.

Includes tea, leaf, unsweetened; tea, leaf, pre-sweetened with sugar; tea, NS as to type, unsweetened; tea, NS as to type, pre-sweetened with sugar; tea, NS as to type, pre-sweetened, NS as to sweetener; tea, leaf, pre-sweetened with low-energy sweetener; tea, NS as to type, pre-sweetened with low-energy sweetener; tea, leaf, decaffeinated, unsweetened; tea, leaf, pre-sweetened, NS as to sweetener.

§ Includes orange juice, canned, bottled or in a carton, unsweetened; orange juice, frozen, unsweetened (reconstituted with water).

Includes regular beer and lite beer.

Includes fruit punch, fruit drink, or fruitade, with vitamin C added; fruit-flavoured drink, made from sweetened powdered mix (fortified with vitamin C); fruit juice drink, not fully specified.

** Includes white potato, French fries, from frozen, deep fried; white potato, chips.

†† Includes orange drink and orangeade with vitamin C added; orange breakfast drink.

Discussion

Antioxidants found in fruits and vegetables have been assumed to be responsible for the inverse association between higher consumption of these foods and lower risks of chronic diseases(Reference Gey22), while singly administered antioxidant interventions failed to support the promising causal relationship(Reference Lonn, Bosch and Yusuf23Reference Markovits, Ben and Levy26). Instead of exploring the ‘quenching’ power of single antioxidants, recently, the concept of TAC has been introduced to express the total synergistic potential of antioxidants for investigating the health effects in food(Reference Serafini and Del Rio6). TAC from diet was found to be inversely and independently related to the plasma concentration of high-sensitive C-reactive protein concentration in Italian adults(Reference Brighenti, Valtuena and Pellegrini27), and positively associated with adiponenctin levels by a Greek team(Reference Detopoulou, Panagiotakos and Chrysohoou28). Also, it was suggested to be potentially an early estimate of the risk of metabolic syndrome features in Spanish people(Reference Puchau, Zulet and de Echavarri29).

A few analytical methods have been developed to measure the synergistic potential of individual food items, differing for scavenging various free radicals and for measuring different endpoints(Reference Pellegrini, Salvatore and Valtuena30). The commonly used methods include Trolox equivalent antioxidant capacity(Reference Miller, Rice-Evans and Davies31), oxygen radical absorbance capacity (ORAC)(Reference Cao, Alessio and Cutler32), total radical-trapping antioxidant parameters(Reference Ghiselli, Serafini and Maiani33), ferric-reducing antioxidant power(Reference Benzie and Strain34), 1,1-diphenyl-2-picrylhydrazyl(Reference Brand-Williams, Cuvelier and Berset35) and ABTS(Reference Fernandez-Panchon, Villano and Troncoso36) assays(Reference Prior, Wu and Schaich37). Among these methods, the ABTS assay developed by Kim et al. (Reference Kim and Lee38) and expressed in VCE antioxidant capacity was used in the present study to estimate TAC. The ABTS (VCE antioxidant capacity) assay utilises quantitative concepts in reference to the familiar vitamin C to measure both hydrophilic and lipophilic antioxidant activities, and its weight-based expression enables researchers to link weight-based food consumption data to estimate TAC(Reference Kim and Lee38).

DR(Reference Valtuena, Pellegrini and Franzini39) and FFQ(Reference Pellegrini, Salvatore and Valtuena30, Reference Rautiainen, Serafini and Morgenstern40) have been commonly used to assess dietary TAC by summation of known TAC values of different food items measured by total radical-trapping antioxidant parameters or ORAC, which, to large extent, depends on the ORAC or total radical-trapping antioxidant parameter food datasets limited to the species and amounts of fruits and vegetables. Although, in 2007, the USDA released an ORAC dataset of 277 selected food items based on a meta-analysis(41), it is unlikely to be used in different countries because of various food availability and nutrient fortification laws. Since it is impractical to measure the TAC of every food that each individual person consumes, we creatively estimated the dietary TAC theoretically by summation of antioxidant capacities of individual antioxidants consumed/d. This theoretical TAC of foods has been proven to be positively correlated with the different TAC values determined analytically by ABTS and 1,1-diphenyl-2-picrylhydrazyl assays and with TAC values from matched forty-four food items from the USDA ORAC database(Reference Floegel, Kim and Chung11). To our best knowledge, this is the first time such a method has been used to estimate dietary TAC of US adults. This approach to calculate dietary TAC would not be limited by specific food items, whose antioxidant capacity has to be measured in advance.

Daily TAC of 503·3 mg VCE in the present study is lower than what we reported previously in 2005 based on experimental data from fruits and vegetables purchased locally in the New York area (591 mg VCE)(Reference Chun, Kim and Smith21). In the present study, antioxidants from both diet and supplements played pivotal roles in the daily TAC of US adults. Individual antioxidant contributions to TAC were in the following order: vitamin C>flavonoids>proanthocyanins>vitamin E>carotenoids. TAC from supplements took account for almost one-fourth of TAC, and particularly more than half of vitamin C contribution to TAC was from supplements, indicating that supplementation is a major source for vitamin C intake in US adults. These results were in accordance with the previous report that about 48 % of US adults take at least one supplement/d and that vitamin C intake from supplements are higher than that from diet(Reference Chun, Floegel and Chung10). Dietary phenolic phytochemicals, such as flavonoids and PA, provided relatively high TAC (39 and 17 %, respectively), while those kinds of supplements which were expressed as the total amount of flavonoid and PA intakes regardless of the subcategories consumed accounted for so little ( < 2 %) and they were not included in the present study. The major sources of the phenolics in US diets were from fruits than from vegetables(Reference Chun, Kim and Smith21), black and green teas, red wines and cocoa(Reference Lee, Kim and Lee42, Reference Cao, Sofic and Prior43). The significant contribution of flavonoids to TAC was similar to the previous findings that flavonoid consumption from diet was two times more than vitamin C intake(Reference Chun, Floegel and Chung10). On the TAC database, flavonoids also have higher antioxidant capacities than other antioxidant vitamins(Reference Floegel, Kim and Chung11). Vitamin E and carotenoids took a very small part in TAC, which was attributed to their lower existence and their relatively lower antioxidant capacities(Reference Floegel, Kim and Chung11).

TAC and individual antioxidant TAC from diet or supplements differed among sociodemographic subgroups. Energy-adjusted TAC of individual antioxidants increased with age, income and exercise levels except for carotenoids. This result was slightly different from the antioxidant intake estimation study(Reference Chun, Floegel and Chung10), in which flavonoids present no trend. The discrepancy was probably attributed to the fact that the low antioxidant capacity of carotenoids weakened their contribution to the whole diet, particularly in men, while the high antioxidant capacity of flavonoids strengthened their role in scavenging free radicals. One of the serious public concerns related to smoking is the lower consumption of vitamin C, vitamin E and carotenes by smokers(Reference Chun, Floegel and Chung10). The present study, however, did not find any differences of TAC intake between smokers and non-smokers, which may stem from the lower antioxidant capacities possessed by these three nutrients. Although many studies have proved that smoking causes smokers to be subject to higher oxidative stress than their counterpart, based on our studies, smoking people did not intend to consume more antioxidants to counteract the adverse damage from smoking, which, indeed, needs public and self concern to increase the corresponding consumption of the antioxidant-rich foods or supplements. Energy-adjusted TAC indicated the similar trend to the TAC of the individual antioxidants, that is, higher in men, older adults, Caucasians and those with higher income level and exercise level.

Consumption of fruits and fruit juices, vegetables and vegetable products, beverages, wines and teas was positively associated with dietary TAC (Table 2). Although the previous studies have reported that fruits and fruit juices, and vegetables have been identified as major sources of antioxidant vitamins(Reference Hampl, Taylor and Johnston44), vitamins did not contribute the most to the TAC from food. Vitamin C, the most abundant vitamin, was found to only account for less than 15 % of antioxidant capacities in most fruits except for kiwi fruit and honeydew melon(Reference Chun, Kim and Smith21), whereas flavonoids were the predominant sources. Particularly, anthocyanins, with a high antioxidant potential among flavonoids, are abundant in many deep-coloured fruits and vegetables(Reference Yang, Koo and Song45, Reference Proteggente, Pannala and Paganga46) and in red wine(Reference Chun, Floegel and Chung10, Reference Proteggente, Pannala and Paganga46). Tea was demonstrated to be the major source of flavan-3-ols and flavonols, both of which accounted for over 90 % of total flavonoids(Reference Song and Chun47). These findings suggested that the food items possessing high proportional flavonoids would contribute most to the dietary TAC.

We identified the major food sources of dietary TAC as tea, supplements, fruits and fruit juices and wines, while vegetables and vegetable products account for little antioxidant potential in the US diet. One previous study has implicated that only 21 % of US adults drink tea daily, while fruits and fruit juices, were consumed by almost 80 % of US adults(Reference Song and Chun47); the various abundances of flavonoids and vitamins prompt tea to have a stronger free-radical scavenging power. The prevalent consumption of supplements in US adults drives them to be a major contributor of TAC. Vegetables and vegetable products account for a tiny part of the TAC in the US diet, and potatoes, onions and broccoli were the top three dietary TAC contributors among different vegetables (Table 3). The findings about vegetable contribution were different from two previous TAC estimations based on FFQ, which found vegetables to be the main contributors to TAC intake in the Italian and Swedish population(Reference Rautiainen, Serafini and Morgenstern48, Reference Pellegrini, Salvatore and Valtuena49). The comparison probably raised the public concern that food selection based on TAC may modify the lifestyles or health conditions in US populations.

To our best knowledge, the present study is the first to document the baseline dietary TAC levels in the free-living US populations on a large scale. It provides a general insight of the real ‘quenching’ power of antioxidants and broadens our horizon to assess the antioxidant functions. However, there are some limitations. First, the lack of some antioxidant intake data or antioxidant capacity values limits our investigation, such as Se, whose antioxidant capacity was difficult to measure. Second, the NHANES food consumption data were based on a 24 h DR that might not be accurately presenting the usual US diet. Third, our study focuses on the dietary data without considering the bioavailability or metabolism of the antioxidants. Dietary TAC is not an ‘intrinsic’ parameter for the human body; however, several studies have found that it was potentially related to some biomarkers of chronic diseases(Reference Brighenti, Valtuena and Pellegrini27, Reference Puchau, Zulet and de Echavarri29).

The present study as a prerequisite for the future investigation of the association between the antioxidant status in humans and the risks of chronic diseases may advance the understanding of establishing the recommended dietary antioxidant intake in US populations for promoting the public health. Additionally, consumption of vegetables and fruits has been proved to decrease the risks of chronic diseases, though, whether antioxidants play the pivotal role warrants more investigation. Furthermore, the modulation of dietary TAC on plasma TAC or the role of antioxidant-rich diets on plasma antioxidant status is still debatable, which may be attributed to the homeostatic mechanisms of regulation, the various bioavailability of different antioxidants and the methods used for measuring biological antioxidant status or TAC. Importantly, on the journey of researching the dietary or physiological antioxidant status or their potential power for fighting against oxidative stress and therefore chronic diseases, considering antioxidants as a whole group, that is, as TAC, instead of individual nutrients, is a better direction.

Acknowledgements

The present study was fully funded by the Beginning Grant-in-Aid no. 0865092E from the American Heart Association. The authors bear no conflict of interest regarding the manuscript submitted to the British Journal of Nutrition. The article was partially presented at the 2010 Experimental Biology Meeting, Anaheim, CA, in April 2010. O. K. C. and W. O. S. designed the study. D. O.-K. prepared the preliminary studies. S.-J. C. and C. E. C. performed the statistical analyses. M. Y. analysed and interpreted the TAC data. S. I. K. and W. O. S. provided technical support and advice as members of the project steering group. All authors were involved in the data interpretation and manuscript preparation.

References

1 Hertog, MG, Feskens, EJ, Hollman, PC, et al. (1993) Dietary antioxidant flavonoids and risk of coronary heart disease: the Zutphen Elderly Study. Lancet 342, 10071011.CrossRefGoogle ScholarPubMed
2 Hertog, MG, Kromhout, D, Aravanis, C, et al. (1995) Flavonoid intake and long-term risk of coronary heart disease and cancer in the seven countries study. Arch Intern Med 155, 381386.CrossRefGoogle ScholarPubMed
3 Hertog, MG, Sweetnam, PM, Fehily, AM, et al. (1997) Antioxidant flavonols and ischemic heart disease in a Welsh population of men: the Caerphilly Study. Am J Clin Nutr 65, 14891494.CrossRefGoogle Scholar
4 Doll, R (1990) An overview of the epidemiological evidence linking diet and cancer. Proc Nutr Soc 49, 119131.CrossRefGoogle ScholarPubMed
5 Hertog, ML, Sweetnam, P, Fehily, A, et al. (1997) Potentially Anticarcinogenic Secondary Metabolites from Fruit and Vegetables. Oxford: Clarendon Press.CrossRefGoogle Scholar
6 Serafini, M & Del Rio, D (2004) Understanding the association between dietary antioxidants, redox status and disease: is the total antioxidant capacity the right tool? Redox Rep 9, 145152.Google Scholar
7 Ghiselli, A, Serafini, M, Natella, F, et al. (2000) Total antioxidant capacity as a tool to assess redox status: critical view and experimental data. Free Radic Biol Med 29, 11061114.CrossRefGoogle ScholarPubMed
8 Chun, OK, Chung, S-J & Song, WO (2007) Estimated dietary flavonoid intakes and major food sources of U.S. adults. J Nutr 137, 12441252.CrossRefGoogle ScholarPubMed
9 Chun, O, Chung, S-J & Song, WO (2009) Estimated intakes of proanthocyanidin in the US population. Experimental Biology Meeting 2009, April 20, 2009, New Orleans, LA: FASEB.Google Scholar
10 Chun, OK, Floegel, A, Chung, S-J, et al. (2010) Estimation of antioxidant intakes from diet and supplements in U.S. adults. J Nutr 140, 317324.CrossRefGoogle ScholarPubMed
11 Floegel, A, Kim, D-O, Chung, S-J, et al. (2010) Development and validation of an algorithm to establish a total antioxidant capacity database of the US diet. Int J Food Sci Nutr 61, 600623.CrossRefGoogle ScholarPubMed
12 National Center for Health Statistics (2004) National Health and Nutrition Examination Survey, 2001–2002 Data Files. Hyattsville, MD: Center for Disease Control. http://www.cdc.gov/nchs/data/nhanes/nhanes_01_02/l36_b_doc.pdf (accessed May 2004).Google Scholar
13 van Herpen-Broekmans, WMR, Klopping-Ketelaars, IAA, Bots, ML, et al. (2004) Serum carotenoids and vitamins in relation to markers of endothelial function and inflammation. Eur J Epidemiol 19, 915921.CrossRefGoogle ScholarPubMed
14 Botman, S, Moore, T, Moriarity, C, et al. (2000) Design and estimation for the national health interview survey, 1995-2004. Vital Health Stat 2 130, 131.Google Scholar
15 Agricultural Research Service & US Department of Agriculture (2003) Database for the Flavonoid Content of Selected Foods. Beltsville, MD: Agricultural Research Service. http://www.nal.usda.gov/fnic/foodcomp/Data/Flav/flav.pdf (accessed March 2003).Google Scholar
16 Agricultural Research Service & US Department of Agriculture (2002) USDA-Iowa State University Database on the Isoflavone Content of Foods, Release 1.3. Beltsville, MD: Agricultural Research Service. http://www.nal.usda.gov/fnic/foodcomp/Data/isoflav/isoflav.html (accessed 2002).Google Scholar
17 Agricultural Research Service & US Department of Agriculture (2004) Database for the Proanthocyanidin Content of Selected Foods. Beltsville, MD: Agricultural Research Service. http://www.nal.usda.gov/fnic/foodcomp/Data/PA/PA.html (accessed 2004).Google Scholar
18 National Center for Health Statistics (2002) National Health and Nutrition Examination Survey, 1999–2000 Data Files. Hyattsville, MD: Centers for Disease Control. http://www.cdc.gov/nchs/nhanes/nhanes1999-2000/nhanes99_00.htm (accessed 2002).Google Scholar
19 Kim, D-O, Chun, OK, Kim, YJ, et al. (2003) Quantification of polyphenolics and their antioxidant capacity in fresh plums. J Agric Food Chem 51, 65096515.CrossRefGoogle ScholarPubMed
20 Kim, D-O, Lee, KW, Lee, HJ, et al. (2002) Vitamin C equivalent antioxidant capacity (VCEAC) of phenolic phytochemicals. J Agric Food Chem 50, 37133717.CrossRefGoogle ScholarPubMed
21 Chun, OK, Kim, D-O, Smith, N, et al. (2005) Daily consumption of phenolics and total antioxidnat capacity from fruits and vegetables in the American diet. J Sci Food Agric 85, 17151724.CrossRefGoogle Scholar
22 Gey, KF (1990) The antioxidant hypothesis of cardiovascular disease: epidemiology and mechanisms. Biochem Soc Trans 18, 10411045.CrossRefGoogle ScholarPubMed
23 Lonn, E, Bosch, J, Yusuf, S, et al. (2005) Effects of long-term vitamin E supplementation on cardiovascular events and cancer: a randomized controlled trial. JAMA 293, 13381347.Google ScholarPubMed
24 Dalgård, C, Nielsen, F, Morrow, J, et al. (2009) Supplementation with orange and blackcurrant juice, but not vitamin E, improves inflammatory markers in patients with peripheral arterial disease. Br J Nutr 101, 263269.CrossRefGoogle Scholar
25 Eidelman, RS, Hollar, D, Hebert, PR, et al. (2004) Randomized trials of vitamin E in the treatment and prevention of cardiovascular disease. Arch Intern Med 164, 15521556.Google Scholar
26 Markovits, N, Ben, AA & Levy, Y (2009) The effect of tomato-derived lycopene on low carotenoids and enhanced systemic inflammation and oxidation in severe obesity. Isr Med Assoc J 11, 598602.Google ScholarPubMed
27 Brighenti, F, Valtuena, S, Pellegrini, N, et al. (2005) Total antioxidant capacity of the diet is inversely and independently related to plasma concentration of high-sensitivity C-reactive protein in adult Italian subjects. Br J Nutr 93, 619625.CrossRefGoogle ScholarPubMed
28 Detopoulou, P, Panagiotakos, DB, Chrysohoou, C, et al. (2010) Dietary antioxidant capacity and concentration of adiponectin in apparently healthy adults: the ATTICA Study. Eur J Clin Nutr 64, 161168.Google Scholar
29 Puchau, B, Zulet, MA, de Echavarri, AG, et al. (2009) Dietary total antioxidant capacity is negatively associated with some metabolic syndrome features in healthy young adults. Nutrition 26, 534541.CrossRefGoogle ScholarPubMed
30 Pellegrini, N, Salvatore, S, Valtuena, S, et al. (2007) Development and validation of a food frequency questionnaire for the assessment of dietary total antioxidant capacity. J Nutr 137, 9398.Google Scholar
31 Miller, N, Rice-Evans, C, Davies, M, et al. (1993) A novel method for measuring antioxidant capacity and its application to monitoring the antioxidant status in premature neonates. Clin Sci (London) 84, 407412.CrossRefGoogle ScholarPubMed
32 Cao, G, Alessio, HM & Cutler, RG (1993) Oxygen-radical absorbance capacity assay for antioxidants. Free Radic Biol Med 14, 303311.CrossRefGoogle ScholarPubMed
33 Ghiselli, A, Serafini, M, Maiani, G, et al. (1995) A fluorescence-based method for measuring total plasma antioxidant capability. Free Radic Biol Med 18, 2936.CrossRefGoogle ScholarPubMed
34 Benzie, IF & Strain, JJ (1996) The ferric reducing ability of plasma (FRAP) as a measure of “antioxidant power”: the FRAP assay. Anal Biochem 239, 7076.Google Scholar
35 Brand-Williams, W, Cuvelier, ME & Berset, C (1995) Use of a free radical method to evaluate antioxidant activity. Lebensm Wiss Technol 28, 2530.CrossRefGoogle Scholar
36 Fernandez-Panchon, MS, Villano, D, Troncoso, AM, et al. (2008) Antioxidant activity of phenolic compounds: from in vitro results to in vivo evidence. Crit Rev Food Sci Nutr 48, 649671.CrossRefGoogle ScholarPubMed
37 Prior, RL, Wu, X & Schaich, K (2005) Standardized methods for the determination of antioxidant capacity and phenolics in foods and dietary supplements. J Agric Food Chem 53, 42904302.CrossRefGoogle ScholarPubMed
38 Kim, D-O & Lee, CY (2004) Comprehensive study on vitamin C equivalent antioxidant capacity (VCEAC) of various polyphenolics in scavenging a free radical and its structural relationship. Crit Rev Food Sci Nutr 44, 253273.Google Scholar
39 Valtuena, S, Pellegrini, N, Franzini, L, et al. (2008) Food selection based on total antioxidant capacity can modify antioxidant intake, systemic inflammation, and liver function without altering markers of oxidative stress. Am J Clin Nutr 87, 12901297.CrossRefGoogle ScholarPubMed
40 Rautiainen, S, Serafini, M, Morgenstern, R, et al. (2008) The validity and reproducibility of food-frequency questionnaire-based total antioxidant capacity estimates in Swedish women. Am J Clin Nutr 87, 12471253.CrossRefGoogle ScholarPubMed
41 USDA (2007) Database for the Oxygen Radical Absorbance Capacity (ORAC) of Selected Foods. Beltsville, MD: Nutrient Data Laboratory, Beltsville Human Nutrition Research Center.Google Scholar
42 Lee, KW, Kim, YJ, Lee, HJ, et al. (2003) Cocoa has more phenolic phytochemicals and a higher antioxidant capacity than teas and red wine. J Agric Food Chem 51, 72927295.CrossRefGoogle Scholar
43 Cao, G, Sofic, E & Prior, RL (1996) Antioxidant capacity of tea and common vegetables. J Agric Food Chem 44, 34263431.CrossRefGoogle Scholar
44 Hampl, JS, Taylor, CA & Johnston, CS (1999) Intakes of vitamin C, vegetables and fruits: which schoolchildren are at risk? J Am Coll Nutr 18, 582590.CrossRefGoogle ScholarPubMed
45 Yang, M, Koo, SI, Song, WO, et al. (2011) Food matrix affecting anthocyanin bioavailability: review. Curr Med Chem 18, 291300.Google Scholar
46 Proteggente, AR, Pannala, AS, Paganga, G, et al. (2002) The antioxidant activity of regularly consumed fruit and vegetables reflects their phenolic and vitamin C composition. Free Radic Res 36, 217233.Google Scholar
47 Song, WO & Chun, OK (2008) Tea is the major source of flavan-3-ol and flavonol in the U.S. diet. J Nutr 138, 1543S1547S.CrossRefGoogle ScholarPubMed
48 Rautiainen, S, Serafini, M, Morgenstern, R, et al. (2008) The validity and reproducibility of food-frequency questionnaire-based total antioxidant capacity estimates in Swedish women. Am J Clin Nutr 87, 12471253.Google Scholar
49 Pellegrini, N, Salvatore, S, Valtuena, S, et al. (2007) Development and validation of a food frequency questionnaire for the assessment of dietary total antioxidant capacity. J Nutr 137, 9398.Google Scholar
Figure 0

Table 1 Total antioxidant capacity (TAC) from diet and supplements of US adults aged 19+ years and its subgroups by sociodemographic and lifestyle factors in the National Health and Nutrition Examination Survey 2001–2(Mean values with their standard errors)

Figure 1

Table 2 Dietary total antioxidant capacity (TAC) of US adults aged 19+ years by food or food group consumption: National Health and Nutrition Examination Survey 2001–2(Mean values with their standard errors)

Figure 2

Fig. 1 Major sources of dietary total antioxidant capacity (TAC) in the US population aged 19+ years: the National Health and Nutrition Examination Survey 2001–2, including the dietary TAC value of the major food groups and the percentage the food group contributes to the TAC. VCE, vitamin C equivalents.

Figure 3

Table 3 Top major food items contributing to dietary total antioxidant capacity (TAC) in 19+ years US adults