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Carotenoids as biomarkers of fruit and vegetable intake in men and women

Published online by Cambridge University Press:  30 August 2016

Charles Couillard ,
Simone Lemieux ,
Marie-Claude Vohl ,
Patrick Couture  and
Benoît Lamarche
Charles Couillard*
Affiliation:
School of Nutrition, Université Laval, Québec, Canada, G1V 0A6 Institute of Nutrition and Functional Foods, Université Laval, Québec, Canada, G1V 0A6
Simone Lemieux
Affiliation:
School of Nutrition, Université Laval, Québec, Canada, G1V 0A6 Institute of Nutrition and Functional Foods, Université Laval, Québec, Canada, G1V 0A6
Marie-Claude Vohl
Affiliation:
School of Nutrition, Université Laval, Québec, Canada, G1V 0A6 Institute of Nutrition and Functional Foods, Université Laval, Québec, Canada, G1V 0A6
Patrick Couture
Affiliation:
Institute of Nutrition and Functional Foods, Université Laval, Québec, Canada, G1V 0A6 Lipid Research Center, Centre hospitalier universitaire de Québec (CHUL), Québec, Canada, G1V 4G2
Benoît Lamarche
Affiliation:
School of Nutrition, Université Laval, Québec, Canada, G1V 0A6 Institute of Nutrition and Functional Foods, Université Laval, Québec, Canada, G1V 0A6
*
*Corresponding author: C. Couillard, email charles.couillard@fsaa.ulaval.ca
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Abstract

High fruit and vegetable (FAV) intake is associated with a lower prevalence of chronic diseases. Identifying the ideal number of FAV servings needed to reduce chronic disease risk is, however, difficult because of biases inherent to common self-report dietary assessment tools. The aim of our study was to examine the associations between daily FAV intake and plasma carotenoid concentrations in men and women enrolled in a series of fully controlled dietary interventions. We compiled and analysed data from a group of 155 men and 109 women who participated in six fully controlled dietary interventions and compared post-intervention fasting plasma carotenoid (α-carotene, β-carotene, β-cryptoxanthin, lutein, lycopene, zeaxanthin) concentrations with regard to the daily FAV servings consumed by the participants. We found that plasma β-cryptoxanthin, lutein and zeaxanthin concentrations were positively associated with daily FAV servings (P≤0·005). However, daily FAV intake was negatively associated with plasma α-carotene (P<0·0005) and lycopene (P<0·0001) concentrations, whereas no association was noted with plasma β-carotene. When men and women were analysed separately, we found that for any given number of FAV servings consumed women had higher circulating lutein concentrations compared with men (P<0·01). Significant sex×FAV (P<0·0001) and sex×dietary β-cryptoxanthin (P<0·0005) interactions were also noted favouring higher plasma β-cryptoxanthin concentrations in women than in men for a given FAV consumption. Results from these fully controlled dietary feeding studies indicate that plasma β-cryptoxanthin and lutein concentrations can be used as robust biomarkers of FAV consumption. They also suggest the existence of sex differences influencing circulating β-cryptoxanthin and lutein concentrations following FAV consumption.

Keywords

CarotenoidsFruit and vegetable intakeSex differencesDiet-controlled intervention studiesBiomarkers
Type
Full Papers
Information
British Journal of Nutrition , Volume 116 , Issue 7 , 14 October 2016 , pp. 1206 - 1215
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Copyright
Copyright © The Authors 2016 

Healthy nutritional habits are associated with a reduced risk of chronic diseases, and most nutritional guidelines advocate increasing the consumption of fruits and vegetables (FAV) in order to prevent CVD, type 2 diabetes (T2D) and some types of cancer( Reference Crowe, Roddam and Key 1 4 ). The extent of health benefits resulting from increased FAV consumption, however, depends on the adherence of individuals to prescribed nutritional recommendations. Many methods are commonly used to evaluate food consumption, including food diaries, FFQ and 24-h recalls( Reference Subar 5 ). Automated forms of these tools are particularly affordable, can be easily administered and provide proper estimates of food and nutrient intakes, which explain their use in large-scale clinical trials and epidemiological studies( Reference Subar 5 ). However, these methods also rely on self-report, which has been heavily criticised recently( Reference Archer and Blair 6 ), with potentially important estimation biases regarding certain foods( Reference Miller, Abdel-Maksoud and Crane 7 Reference Livingstone and Black 9 ).

Measuring markers of food consumption in various biological specimens (urine, blood, tissues, etc.) has therefore been suggested to be a more accurate and consistent indication of dietary intakes and patterns( Reference Baldrick, Woodside and Elborn 10 ). To that effect, recovery biomarkers (e.g. doubly labelled water, urinary measures) are more accurate in estimating dietary intakes compared with concentration biomarkers such as circulating carotenoids, which are, however, less expensive and often easier to collect. Carotenoids are a family of more than 700 fat-soluble pigments that are present in varying quantities in FAV( Reference Maiani, Caston and Catasta 11 ). As they cannot be synthesised by humans( Reference Baldrick, Woodside and Elborn 10 ), carotenoids found in circulation are considered to be reliable biomarkers of dietary carotenoid intake, even though conditions such as obesity have been shown to influence this association( Reference Vioque, Weinbrenner and Asensio 12 ). Accordingly, FAV consumption accounts for up to 90 % of dietary carotenoid intake with the most common blood carotenoids being α-carotene, β-carotene, β-cryptoxanthin, lutein, lycopene and zeaxanthin, which represent >95 % of total circulating carotenoids( Reference Maiani, Caston and Catasta 11 ).

The use of circulating carotenoid concentrations as biomarkers of FAV intake has been mostly validated against self-reported measures of FAV consumption( Reference Jansen, Van Kappel and Ocke 13 Reference Bogers, Van Assema and Kester 18 ). On the other hand, fully controlled dietary interventions – that is, studies in which subjects are provided with all the foods to consume and do so under the supervision of research staff – provide a more robust setting to assess the concordance between blood concentrations of biomarkers and food intake. Over the past few years, we have conducted a series of fully controlled dietary interventions with a wide range of daily FAV servings( Reference Bédard, Riverin and Dodin 19 Reference Lacroix, Charest and Cyr 23 ). The present analysis was therefore conducted with the intent to examine the extent to which circulating carotenoid concentrations are concordant with variations in dietary carotenoid and FAV intakes of healthy men and women enrolled in fully controlled dietary interventions. We hypothesise that dietary carotenoid and FAV intakes are positively associated with plasma carotenoid concentrations in both men and women.

Methods

Study population

A total of 155 men and 109 women have participated in different fully controlled dietary interventions undertaken in our research facility since 2004. Specific selection criteria for participants of each intervention have been previously published( Reference Bédard, Riverin and Dodin 19 Reference Lacroix, Charest and Cyr 23 ). Overall, participants had to be healthy, and were excluded on the basis of current treatment for history of hypertension, CVD, T2D or other endocrine disorders, if they were smokers or had an alcohol consumption >1 drink/d. Dietary supplement use was also considered a reason to exclude participants from all the studies. Each participant signed a written informed consent from to take part in the studies, which were all approved by the Human Research Ethics Committee of Université Laval.

Description of fully controlled dietary interventions

As indicated above, we have taken advantage of data from a series of isoenergetic fully controlled dietary interventions conducted over the last 10 years by our research group( Reference Bédard, Riverin and Dodin 19 Reference Lacroix, Charest and Cyr 23 ) in order to perform the present analysis. Complete detailed descriptions of diet 1 (registered at ClinicalTrials.gov as NCT00988650)( Reference Richard, Couture and Desroches 20 ), diet 2 (NCT00930137)( Reference Lacroix, Charest and Cyr 23 ), diet 3 (NCT01351012)( Reference Jones, Senanayake and Pu 21 ), diet 4 (NCT01163175)( Reference Labonté, Couture and Paquin 22 ), diet 5 (NCT01293344)( Reference Bédard, Riverin and Dodin 19 ) and diet 6 (NCT00988650)( Reference Richard, Couture and Desroches 20 ) have been previously published. In brief, diet 1 (6·8 (sd 1·0) FAV servings/d) was a 5-week control diet of a study assessing the impact of the Mediterranean diet and was designed to reflect average macronutrient intakes of North American men( Reference Gray-Donald, Jacobs-Starkey and Johnson-Down 24 ); diets 2 (7·4 (sd 0·9) FAV servings/d) and 4 (9·8 (sd 1·6) FAV servings/d) were 4-week control diets low in trans-fatty acids (TFA) of ruminant origin (0·3 and 0·8 % of energy, respectively) from studies investigating the metabolic impact of TFA from milk; diet 3 (9·6 (sd 2·4) FAV servings/d) was part of a study looking at the metabolic impacts of different vegetable oils and consisted of a 4-week, weight-maintaining diet of fixed macronutrient composition for protein (15 % of energy), carbohydrates (50 % of energy) and fats (35 % of energy), with a blend of maize and safflower oils (25:75) contributing to dietary fat intake (18 %); diets 5 (19·1 (sd 3·6) FAV servings/d) and 6 (21·0 (sd 3·0) FAV servings/d) corresponded to 5-week Mediterranean diets – that is, they contained key foods of the Mediterranean pyramid (e.g. olive oil, whole-grain products, FAV, legumes, nuts, cheese and yogurt, fish, poultry, red wine)( Reference Willett, Sacks and Trichopoulou 25 ) and provided a MUFA:SFA ratio of 2·7 corresponding to the one found in the traditional Mediterranean diet( Reference Saura-Calixto and Goni 26 ). Table 1 summarises the macronutrient composition of the different dietary interventions, whereas the online Supplementary Tables S1 and S2 list the FAV provided and consumed by the participants in each diet.

Table 1 Characteristics of the participants and macronutrient content of the different dietsFootnote * (Mean values and standard deviations)

M/F, male/female.

a,b,c,d,e Mean values with unlike superscript letters were significantly different.

* Macronutrients reported as percentage of daily energy have no standard deviations because all subjects consumed the same diet; hence, there is no between-subject variation in these variables except for the mean of all six diets.

Data were adjusted for sex and age.

In all cases, subjects arrived at our Clinical Investigation Unit (CIU) on weekdays to have their body weight measured and consume their lunch meal (approximately 35 % of daily energy intake) under staff supervision. All meals (including foods and beverages) were prepared and packaged at the CIU, and participants were provided with their evening meals and the next day’s breakfast to take home, giving us the opportunity to control for energy, macronutrient and food intakes. Food was provided under isoenergetic conditions in order to maintain body weight constant, and a 7-d cyclic menu was used in all dietary interventions. Participants were instructed to consume only the foods provided. Compliance of participants with their specific diets was excellent (>95 % in all cases). Dietary interventions were formulated using the Nutrition Data System software (version 4.03_31; Nutrition Coordinating Center). Participants were instructed to maintain their usual physical activity level throughout the experiments except for the 3 d that preceded blood sampling at the end of the feeding period, during which they were asked to refrain from intense physical exercise. Dietary carotenoid intake was calculated using the Canadian Nutrient File (http://webprod3.hc-sc.gc.ca/cnf-fce/index-eng.jsp), which was also used to obtain the energy, macronutrient and micronutrient contents of the different diets.

Anthropometry and plasma lipids

Body weight, height as well as waist and hip circumferences of each participant were measured by standardised procedures( Reference van der Kooy and Seidell 27 ).

Plasma carotenoids

Chemicals

Retinyl acetate, α-carotene, lutein, zeaxanthin, β-cryptoxanthin, β-carotene and lycopene were purchased from Sigma. All solvents were of HPLC grade and purchased from VWR. HPLC water was obtained using a MilliQ water purification system from Millipore.

Standards preparation

Stock solutions for each carotenoid were prepared (1 mg in 100 ml of solvent) in either ethanol (C2H6O, for lutein, zeaxanthin and β-cryptoxanthin) or hexane (C6H14, for β-carotene and lycopene). Solutions were left to shake overnight at 4°C under dim light. The exact concentration of each stock solution was then determined using a UV spectrophotometer, and the specific molecular extinction coefficient (e) of each carotenoid was determined( Reference Gleize, Steib and Andre 28 ). Appropriate volumes of stock solutions were then transferred to amber Eppendorf tubes and evaporated under N. On the day of the analyses, carotenoid standards were solubilised with methanol–dichloromethane (65:35, v/v) to obtain a final concentration of 2 µm. These solutions were then diluted to obtain calibration curves. Retinyl acetate (15 µm) was used as an internal standard.

Samples preparation

Post-intervention plasma samples maintained at −80°C were thawed a day before analyses. Samples were vortexed and then centrifuged at 3500 rpm for 10 min at 4°C. Aliquots of 100 µl of plasma were then transferred to Eppendorf tubes (1·5 ml) along with 20 µl of 2-propanol and 20 µl of carotenoid standard, and the tubes were vortexed. Samples were transferred to a 400-μl fixed well plate (ISOLUTE® SLE+; Biotage), and 900 µl of hexane–isopropanol (90:10, v/v) was added to each well. Each extracted sample was evaporated under N, and once dry the sample was reconstituted with 300 µl of methanol–dichloromethane (65:35, v/v). Plates were shaken for 10 min, and samples were transferred into HPLC glass vials to be analysed.

HPLC

HPLC-UV analysis of the samples was performed using an Agilent 1260 liquid handling system (Agilent) equipped with a binary pump system and a C30 reversed phase column (YMC America Inc.) kept at constant temperature (35°C). Carotenoids of the different samples were separated with a mobile phase consisting of methanol–water (98:2, v/v; Eluent A) and methyl-tert-butyl ether (Eluent B; VWR). Flow rate was set at 1 ml/min, and the gradient elution was as follows: 2 % Eluent B (initial), 2·0–80 % Eluent B (0·0–27·0 min), isocratic 80 % Eluent B (27·0–31·0 min), 80·0–2·0 % Eluent B (31·0–31·1 min) and isocratic 2 % Eluent B (31·1–34·0 min). The UV detector was set at 450 nm, and identification of each compound was confirmed using retention time and UV spectra (190–640 nm) of the pure compounds. Data acquisition was carried out using Chemstation software (Agilent).

Statistical analyses

Data are presented as mean values and standard deviations unless stated otherwise. General linear model (GLM) procedures were used to test differences in the dietary composition as well as plasma carotenoid concentrations of participants enrolled in the different nutritional interventions. Associations of daily servings of FAV and dietary carotenoid intake estimated from the nutrient files with post-intervention plasma carotenoid concentrations were tested for linear trend using the GLM procedure with statistical adjustment for sex and age, when appropriate. The interaction between sex and FAV intake in determining the blood concentrations of the various carotenoids was investigated using proper interaction terms in the GLM. Spearman’s correlation coefficients were computed to study the associations between body weight and total carotenoid dietary intake and plasma concentrations. All analyses were performed using SAS statistical package (version 9.3, SAS Institute Inc.). Throughout the analyses, a P≤0·05 was considered to be statistically significant.

Results

Physical characteristics as well as FAV and dietary carotenoid intakes of participants enrolled in different dietary interventions sorted according to the daily number of FAV servings consumed are presented in Table 1. There were significant differences in physical characteristics between diet groups due to variations in the specific selection criteria of the six diet-controlled interventions that we used in this analysis. The mean age of the 264 participants was 42·6 (sd 14·4) years, 41 % of them were women, and interventions lasted between 4 and 5 weeks. Daily FAV intake of the different diets averaged 12·3 (sd 5·8) servings and ranged from 6·8 (sd 1·0) to 21·0 (sd 3·0) servings/d (P<0·0001 for linear trend; Table 2). Similar trends were observed when FAV servings were expressed per a standard 2500-kcal energy intake or in g/d (P<0·0001). We found that the increment in daily FAV servings across diets was attributable to increases in both fruit (P<0·0001) and vegetable servings (P<0·0001), with the number of daily vegetable servings consumed by the participants remaining slightly above than that of fruits in all diets. Furthermore, we found positive linear trends for dietary α-carotene, β-carotene, β-cryptoxanthin and lutein intakes (P<0·0001 for all; Table 2), whereas there were significant negative linear trends (P<0·0001) for dietary lycopene and retinol intakes when diets were ranked according to daily FAV servings consumed.

Table 2 Characteristics and daily micronutrient intakes of participants (Mean values and standard deviations)

FAV, fruits and vegetables.

a,b,c,d,e,f Mean values with unlike superscript letters were significantly different.

* Data were adjusted for sex and age.

Fig. 1 illustrates the linear trend analysis of the associations of plasma α-carotene, β-carotene, lycopene and retinol concentrations with their corresponding dietary intakes as well as with the daily number of FAV servings consumed by the participants. Circulating concentrations of α-carotene and lycopene were positively associated with their corresponding dietary intakes (P<0·0001 for linear trend for both) but negatively with the number of FAV consumed daily (P<0·0001 for linear trend for both). Plasma β-carotene and retinol concentrations showed no significant association with either their daily dietary intakes or number of FAV servings consumed (Fig. 1).

Fig. 1 Mean plasma α-carotene, β-carotene, lycopene and retinol concentrations of participants according to their respective mean daily dietary intake as well as daily fruit and vegetable (FAV) consumption. Values are means and standard deviations. Data were adjusted for sex and age. , Diet 1; , diet 2; , diet 3; , diet 4; , diet 5; , diet 6.

As illustrated in Fig. 2, we found that plasma β-cryptoxanthin, lutein and zeaxanthin concentrations were all positively associated with their corresponding dietary intakes (P≤0·0005) as well as with the daily number of FAV servings consumed (P≤0·005). Similar patterns of associations were noted when we considered daily fruit or vegetable servings separately (data not shown).

Fig. 2 Mean plasma β-cryptoxanthin, lutein and zeaxanthin concentrations of participants according to their respective mean daily dietary intake as well as fruit and vegetable (FAV) consumption. Values are means and standard deviations. Data were adjusted for sex and age. , Diet 1; , diet 2; , diet 3; , diet 4; , diet 5; , diet 6.

As lutein and β-cryptoxanthin were found to be the best correlates of daily FAV servings consumed, we compared the associations of plasma lutein and β-cryptoxanthin concentrations with their respective daily dietary intakes and FAV servings consumed in men and women separately (Fig. 3). We found significant sex×dietary β-cryptoxanthin (P<0·0005) and sex×FAV servings (P<0·005) interactions with regard to circulating β-cryptoxanthin concentrations, as women showed a steeper increase in plasma β-cryptoxanthin concentrations with increasing dietary β-cryptoxanthin intake and daily number of FAV servings consumed compared with men (Fig. 3). In contrast, significantly higher plasma lutein concentrations were noted in women at any concentration of dietary lutein+zeaxanthin intake or daily number of FAV servings compared with men (sex effect: P<0·0001 for both). However, no significant interaction was noted between dietary lutein+zeaxanthin intake or daily number of FAV servings consumed and circulating lutein concentrations (Fig. 3). Similar results were obtained when plasma zeaxanthin concentrations were analysed alone (data not shown).

Fig. 3 Mean plasma β-cryptoxanthin and lutein concentrations of men ( and ) and women ( and ) according to their respective mean daily dietary intake as well as daily number of fruit and vegetable (FAV) servings. Values are means and standard deviations. Data were adjusted for age. lut+zea, Lutein+zeaxanthin.

Finally, we looked at potential contributors to the variations in circulating carotenoid concentrations (Fig. 4), and found a significant positive association between BMI of participants and total dietary carotenoid intake (r 0·28, P<0·0001). In contrast, BMI was negatively correlated to circulating carotenoid concentrations (r −0·33, P<0·0001).

Fig. 4 Associations between BMI of the 264 participants and their total dietary carotenoid intakes (top panel) and total plasma carotenoid concentrations (bottom panel). , Men; , women.

Discussion

Results of the present analyses of data from highly controlled feeding studies provide further support to the use of plasma β-cryptoxanthin and lutein concentrations as biomarkers of mixed FAV consumption in both men and women. Our observations are in line with previous results, mostly based on self-report data, showing that circulating β-cryptoxanthin concentrations are associated with FAV intake( Reference Jansen, Van Kappel and Ocke 13 , Reference Carlsen, Karlsen and Lillegaard 14 , Reference Daniels, Mulligan and McCance 29 Reference Block, Norkus and Hudes 33 ). Furthermore, there is a large body of evidence showing that plasma lutein concentrations are also associated with FAV intake( Reference Jansen, Van Kappel and Ocke 13 , Reference Daniels, Mulligan and McCance 29 , Reference Campbell, Gross and Martini 32 , Reference Brevik, Andersen and Karlsen 34 , Reference Polsinelli, Rock and Henderson 35 ). We also found that plasma zeaxanthin concentrations were positively associated with FAV intake, but their circulating concentrations remained 2–3 times lower than those of β-cryptoxanthin and lutein. However, contrary to what we observed, plasma β-cryptoxanthin concentrations of men and women were unchanged following increased daily FAV consumption (from 2 to 5 servings/d) for a period of 14 d( Reference Brevik, Andersen and Karlsen 34 ), but the authors were unable to offer a reasonable explanation for the lack of response of plasma β-cryptoxanthin to a higher FAV intake. The lack of association of circulating lutein concentrations with FAV intake in postmenopausal women has also been reported( Reference Macdonald, Hardcastle and Duthie 30 ).

On the other hand, although FAV are the primary source of dietary carotenoids, our analyses indicate that plasma α-carotene concentrations are negatively associated with the daily number of FAV servings consumed by the participants enrolled in these diet-controlled feeding studies, whereas plasma β-carotene concentrations were not associated with FAV intake. This is somewhat contradictory to previous self-report data studies that have shown positive associations between circulating α-carotene and β-carotene concentrations with vegetable( Reference Carlsen, Karlsen and Lillegaard 14 , Reference Campbell, Gross and Martini 32 , Reference Al-Delaimy, Ferrari and Slimani 36 , Reference van Kappel, Steghens and Zeleniuch-Jacquotte 37 ) and fruit( Reference Jansen, Van Kappel and Ocke 13 , Reference Carlsen, Karlsen and Lillegaard 14 , Reference Brevik, Andersen and Karlsen 34 ) consumption. A likely explanation for the inverse relationship between plasma α-carotene concentration and FAV intake could be that, although FAV intake of diet 4 was in the lower range of intakes in studies we analysed, it was also the one showing the highest proportion of carrots (approximately 12 % of total FAV intake or 1·25 servings/d), the most potent dietary source of α-carotene( Reference Maiani, Caston and Catasta 11 ). This may have increased circulating α-carotene concentrations of participants enrolled in diet 4 in the context of a lower FAV intake. Likewise, a high proportion of β-carotene-rich foods( Reference Maiani, Caston and Catasta 11 ) in diets with a lower FAV intake, such as green leafy vegetables in diet 3 (>18 % of total FAV intake or 1·76 servings/d) and butter (75 g/10 460 kJ (2500 kcal)) in diet 4, may have prevented us from noticing the previously reported association between plasma β-carotene concentrations and FAV intake. Our results are, however, in line with those suggesting that plasma β-carotene concentration may not be a suitable marker of FAV intake as it may be affected by specific dietary patterns( Reference Garcia, Mohan and Koebnick 38 ).

Lycopene, a carotenoid highly abundant in tomatoes( Reference Maiani, Caston and Catasta 11 ), has attracted much attention in recent years because of its potential benefits against chronic diseases( Reference Wang 39 ). There is a positive relationship between circulating lycopene concentrations and FAV consumption( Reference Crane, Kubota and West 31 ), although this association was not reported by all( Reference Carlsen, Karlsen and Lillegaard 14 , Reference Daniels, Mulligan and McCance 29 ). Lycopene is, however, recognised as a better biomarker of tomato (whole and processed) consumption than of mixed FAV intake( Reference Baldrick, Woodside and Elborn 10 ). In the present study, plasma lycopene concentrations were positively associated with dietary lycopene intake but also negatively correlated to the daily number of FAV servings consumed by the participants. This could be due to the fact that the diets with the highest lycopene contents (diets 1 and 4) were not the ones with the highest number of daily FAV servings consumed. When we further investigated foods that contributed to dietary lycopene intake within the context of our diet-controlled interventions, we found that starchy vegetables (potatoes and maize) best predicted dietary lycopene intake (data not shown). Starchy vegetables are not a source of lycopene, but they were used in the preparation of meals (e.g. mixed with ground beef) consumed in the context of diets 1 and 4 and diets that were accompanied by ketchup and chili sauce, which are potent sources of lycopene( Reference Maiani, Caston and Catasta 11 , Reference Clinton 40 ). Thus, our results suggest that circulating lycopene concentrations may not be the best-suited biomarker of mixed FAV intake in diets where processed tomato products are also consumed.

We further investigated potential sex differences in circulating carotenoid concentrations, and found that plasma lutein concentrations were significantly higher in women compared with men regardless of the number of daily FAV servings consumed. We also noted that associations between plasma β-cryptoxanthin and FAV intake were different between men and women, as reflected by a significant sex×daily FAV servings interaction determining circulating β-cryptoxanthin concentrations. Specifically, women showed a proportionally larger increase in plasma β-cryptoxanthin concentrations with increasing FAV intake compared with men. Such sex differences in circulating lutein and β-cryptoxanthin concentrations have already been reported( Reference Jansen, Van Kappel and Ocke 13 , Reference Olmedilla, Granado and Blanco 41 ), although the explanation for such a phenomenon remains to be elucidated. Previous observations have, however, suggested that body size may interfere with the relationship between dietary carotenoid intake and plasma concentration, with overweight individuals showing lower circulating carotenoid concentrations compared with non-obese subjects( Reference Vioque, Weinbrenner and Asensio 12 ) probably because of the accumulation of carotenoids within adipose tissue( Reference El-Sohemy, Baylin and Kabagambe 42 ). In the present study, we found a negative association between BMI and total plasma carotenoid concentrations, which may partly explain the observed sex difference in total plasma carotenoid concentrations, as women who showed lower mean BMI compared with men were also those showing higher total plasma carotenoid concentrations. This reinforces the notion that besides potential differences in absorption and/or metabolism of dietary carotenoids obesity status must also be considered when comparing and interpreting the physiological and nutritional relevance of circulating carotenoid concentrations.

Strengths of our study include the use of data from a fairly large sample of men and women enrolled in fully controlled feeding studies, allowing us to examine the relationship of circulating biomarkers of consumption with the actual number of daily FAV servings consumed by participants, whereas most studies looking at carotenoids as biomarkers of FAV consumption have relied on data collected through self-reported dietary assessment tools( Reference Jansen, Van Kappel and Ocke 13 , Reference Carlsen, Karlsen and Lillegaard 14 , Reference Campbell, Gross and Martini 32 , Reference Brevik, Andersen and Karlsen 34 , Reference Al-Delaimy, Ferrari and Slimani 36 , Reference van Kappel, Steghens and Zeleniuch-Jacquotte 37 ). During the preparation of the present article, a meta-analysis was published( Reference Souverein, de Vries and Freese 43 ) using data from twelve diet-controlled intervention studies including 526 European men and women in whom circulating carotenoid measures were available (largest sample size for β-carotene (n 316) and smallest sample size for lutein+zeaxanthin (n 35)). Studies considered for this meta-analysis were interventions in which all foods and drinks or all FAV consumed were provided to the participants for periods varying from 7 to 90 d. Souverein et al. ( Reference Souverein, de Vries and Freese 43 ) reported that circulating β-cryptoxanthin and lutein concentrations were significantly associated with FAV intake, which is in line with the results we have reported in this study. However, contrary to what we found, plasma/serum α-carotene, β-carotene and lycopene concentrations were also positively associated with FAV intake( Reference Souverein, de Vries and Freese 43 ). When taken together, our results and those of Souverein et al. ( Reference Souverein, de Vries and Freese 43 ) suggest that circulating β-cryptoxanthin and lutein concentrations may be more robust biomarkers of mixed FAV intake than α-carotene, β-carotene and lycopene, which in turn could be more sensible to the presence of specific FAV categories (or by-products) in the diet.

The present study also has limitations that must be acknowledged. First, dietary interventions that were compiled in the present analyses were not primarily designed to identify biomarkers of FAV consumption. For instance, in our analyses, the lowest FAV intake of the participants was about 7 servings/d – a value that actually falls within the range of the recommended FAV intake, that is, 7–10 FAV servings/d( 44 ). However, it must be kept in mind that a large number of individuals do not meet nutritional recommendations and especially those for FAV. Indeed, >60 % of Canadians aged 12 years or older consume <5 FAV servings/d( 45 ). In the USA, 13·1 % of adults reportedly meet fruit intake recommendations and 8·9 % meet those for vegetables( Reference Moore and Thompson 46 ), whereas in Europe a majority of people do not reach the WHO daily recommendation for FAV consumption of ≥400 g/d( 47 ). In the studies we used for the present analysis, FAV consumption was well above the WHO threshold for all participants. Therefore, it would have been interesting to have been able to include studies with a lower range of FAV intakes not only in an attempt to identify threshold values for circulating biomarkers such as plasma carotenoid concentrations associated with the ideal number of FAV servings needed to reduce chronic disease risk, but also to verify to what extent plasma carotenoids also correlate with lower daily FAV intake. Second, there are variations in the FAV contents of the six dietary interventions used in our analyses, which could impact the validity of our observations as the proportion of carotenoids that are consumed likely differ between diets. On the other hand, this variety in FAV provided and consumed could also been seen as a strength as it may better reflect the mixed FAV intakes generally observed in the population. Third, it has been suggested that plasma carotenoids may be more powerful markers of the changes in the consumption of FAV. For our analyses, we compared post-intervention plasma carotenoid concentrations and FAV intakes rather than their respective changes over the course of the interventions, which may have yielded stronger relationships. Finally, our study does not take into account potential metabolic or genetic characteristics of subjects or even seasonal variations in the carotenoid content of foods, which most likely affect carotenoid metabolism and circulating concentrations.

In summary, the present study shows that plasma β-cryptoxanthin and lutein concentrations are reliable biomarkers of mixed FAV consumption. Our results also provide us with an insight on the importance of sex as a determinant of circulating plasma carotenoid concentrations, especially β-cryptoxanthin and lutein. The reliability of using circulating β-cryptoxanthin, lutein or other carotenoid concentrations as biomarkers of mixed FAV consumption and their relevance in the validation of self-reporting dietary assessment methods in different populations (adults, adolescents, elderly, pregnant women, etc.) will need to be examined in future studies. In addition, the determinants of sex difference in the response of plasma β-cryptoxanthin and lutein concentrations to increased FAV consumption will need to be further investigated as well as how this affects the health benefits of FAV in chronic disease conditions.

Acknowledgements

The authors acknowledge the contribution of Pascal Dubé of the Institute of Nutrition and Functional Foods for the measurements of plasma carotenoid concentrations. The authors also acknowledge the contributions of nurses and other research professionals as well as subjects who participated in the dietary interventions, without whom no clinical research would be possible.

Studies were made possible by grants from the Canadian Institutes of Health Research (MOP-68866, MOP-84568 and FHG-129921), the Natural Sciences and Engineering Research Council of Canada, the Dairy Farmers of Canada, the Canadian Dairy Commission, Novalait Inc., Dairy Australia, Agriculture and Agri-Food Canada, the Canola Council of Canada, the Flax Council of Canada, Dow Agrosciences, the Western Grains Research Foundation of Canada, the National Center for Research Resources (UL1 RR033184) and the National Center for Advancing Translational Sciences (UL1 TR000127). Funders of the studies had no role in the design, conduct, management, data collection, analysis or writing or review of the present article.

The authors’ responsibilities were as follows: C. C., S. L., M.-C. V., P. C. and B. L.: research design; P. C.: medical supervision of study participants; C. C., S. L., M.-C. V., P. C. and B. L.: data acquisition; P. C.: medical supervision of study participants; C. C.: analysis and interpretation of the data and drafting of the manuscript; M.-C. V., P. C., S. L. and B. L.: critical revision of the manuscript for important intellectual content. All the authors read and approved the final manuscript.

C. C. has received research funding from the Canadian Cranberry Growers Coalition and McCormick Science Institute and received honoraria or travel expense reimbursements from the Berry Health Benefits Symposium, Ocean Spray Cranberries Inc. and Mott’s Canada. C. C. and B. L. have received research funding from Atrium Innovations. B. L. has received research funding from the Danone Institute and honoraria from Unilever, Danone and the Dairy Farmers of Canada. B. L. is Chair in Nutrition and Cardiovascular Health, supported in part by Provigo/Loblaws. B. L. and P. C. have received research grants from the Dairy Farmers of Canada and Dairy Australia.

Supplementary Material

For supplementary material/s referred to in this article, please visit http://dx.doi.org/10.1017/S0007114516003056

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Figure 0

Table 1 Characteristics of the participants and macronutrient content of the different diets* (Mean values and standard deviations)

Figure 1

Table 2 Characteristics and daily micronutrient intakes of participants (Mean values and standard deviations)

Figure 2

Fig. 1 Mean plasma α-carotene, β-carotene, lycopene and retinol concentrations of participants according to their respective mean daily dietary intake as well as daily fruit and vegetable (FAV) consumption. Values are means and standard deviations. Data were adjusted for sex and age. , Diet 1; , diet 2; , diet 3; , diet 4; , diet 5; , diet 6.

Figure 3

Fig. 2 Mean plasma β-cryptoxanthin, lutein and zeaxanthin concentrations of participants according to their respective mean daily dietary intake as well as fruit and vegetable (FAV) consumption. Values are means and standard deviations. Data were adjusted for sex and age. , Diet 1; , diet 2; , diet 3; , diet 4; , diet 5; , diet 6.

Figure 4

Fig. 3 Mean plasma β-cryptoxanthin and lutein concentrations of men ( and ) and women ( and ) according to their respective mean daily dietary intake as well as daily number of fruit and vegetable (FAV) servings. Values are means and standard deviations. Data were adjusted for age. lut+zea, Lutein+zeaxanthin.

Figure 5

Fig. 4 Associations between BMI of the 264 participants and their total dietary carotenoid intakes (top panel) and total plasma carotenoid concentrations (bottom panel). , Men; , women.

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