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Skin carotenoid status and plasma carotenoids: biomarkers of dietary carotenoids, fruits and vegetables for middle-aged and older Singaporean adults

Published online by Cambridge University Press:  14 January 2021

Darel Wee Kiat Toh
Affiliation:
Department of Food Science & Technology, Faculty of Science, National University of Singapore, Science Drive 3, Singapore, Singapore
Wen Wei Loh
Affiliation:
Department of Food Science & Technology, Faculty of Science, National University of Singapore, Science Drive 3, Singapore, Singapore
Clarinda Nataria Sutanto
Affiliation:
Department of Food Science & Technology, Faculty of Science, National University of Singapore, Science Drive 3, Singapore, Singapore
Yuanhang Yao
Affiliation:
Department of Food Science & Technology, Faculty of Science, National University of Singapore, Science Drive 3, Singapore, Singapore
Jung Eun Kim*
Affiliation:
Department of Food Science & Technology, Faculty of Science, National University of Singapore, Science Drive 3, Singapore, Singapore
*
*Corresponding author: Jung Eun Kim, email fstkje@nus.edu.sg
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Abstract

Skin carotenoid status (SCS) measured by resonance Raman spectroscopy (RRS) may serve as an emerging alternative measurement for dietary carotenoid, fruit and vegetable (FV) intake although its application had not been assessed in a middle-aged and older population in Asia. This cross-sectional study aims to concurrently examine the use of SCS and plasma carotenoids to measure FV and carotenoid intake in a middle-aged and older population, taking into consideration potential socio-demographic and nutritional confounders. The study recruited 103 middle-aged and older adults (mean age: 58 years) in Singapore. Dietary carotenoids and FV, plasma carotenoid concentration and SCS were measured using 3-d food records, HPLC and a biophotonic scanner which utilised RRS, respectively. Adjusted for statistically defined socio-demographic covariates sex, age, BMI, prescription medication and cigarette smoking, plasma carotenoids and SCS showed positive associations with dietary total carotenoids (β plasma: 0·020 (95 % CI 0·000, 0·040) µmol/l/mg, P = 0·05; β skin: 265 (95 % CI 23, 506) arbitrary units/mg, P = 0·03) and FV (β plasma: 0·076 (95 % CI 0·021, 0·132) µmol/l per FV serving, P = 0·008; β skin: 1036 (95 % CI 363, 1708) arbitrary units/FV serving, P = 0·003). The associations of SCS with dietary carotenoid and FV intake were null with the inclusion of dietary PUFA, fibre and vitamin C as nutritional covariates (P > 0·05). This suggests a potential influence of these nutritional factors on carotenoid circulation and deposition in the skin. In conclusion, SCS, similar to plasma carotenoids, may serve as a biomarker for both dietary carotenoid and FV intake in a middle-aged and older Singaporean population.

Type
Full Papers
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Nutrition Society

A higher intake of fruits and vegetables (FV) had been consistently evidenced to be associated with a reduced risk and incidence of chronic diseases such as type 2 diabetes(Reference Wang, Fang and Gao1), CVD, total cancer, as well as all-cause mortality(Reference Aune, Giovannucci and Boffetta2). As the likelihood of developing chronic diseases increases with age, lowering this risk is especially important in middle-aged and older adults. Therefore, it is important to assess the intake of FV in this population(Reference Morgan, Graham and Marshall3Reference Shim, Oh and Kim5). Common methods used to determine dietary FV intake include FFQ and dietary recalls. While easy to administer logistically, subjective self-reported methods are prone to recollection and social desirability biases if inadequately performed(Reference Morgan, Graham and Marshall3Reference Shim, Oh and Kim5). Nevertheless, this can be complemented with the use of more objective biomarkers to improve the accuracy of dietary data and to reduce the magnitude of errors.

Carotenoids, in particular, are a group of naturally occurring organic pigments that contribute to the distinctive red, yellow and orange colours of FV. Humans and other animals, while unable to synthesise these pigments, accumulate carotenoids from the diet (e.g. in eggs from poultry and the flesh of fish such as salmon)(Reference Cazzonelli6,Reference Eggersdorfer and Wyss7) . As FV are the main sources of dietary carotenoids, there is potential for carotenoids to serve as an objective and reliable marker to assess dietary FV intake. From an earlier systematic review, circulating carotenoids and vitamin C had been reported to be the most commonly measured biomarkers for dietary FV intake(Reference Baldrick, Woodside and Elborn8).

The use of plasma carotenoids is substantially validated with numerous studies which reported significant, positive correlations between both dietary FV and carotenoids with plasma carotenoid concentrations(Reference Al-Delaimy, Ferrari and Slimani9Reference Couillard, Lemieux and Vohl13). However in recent years, skin carotenoid status (SCS) assessed by resonance Raman spectroscopy (RRS) had become increasingly evaluated as a potential alternative biomarker for dietary carotenoids and FV intake(Reference Morgan, Graham and Marshall3,Reference Mayne, Cartmel and Scarmo14) . Predominantly deposited in the stratum corneum, the transfer of carotenoids to the skin is hypothesised to occur either via diffusion from blood and adipocytes or transportation through sebaceous and eccrine sweat glands(Reference Meléndez-Martínez, Stinco and Mapelli-Brahm15,Reference Darvin, Fluhr and Caspers16) . Following oral consumption, this process was reported to take within 1–3 d(Reference Darvin, Patzelt and Knorr17).

RRS is a spectroscopic technique that detects molecules based on the principle of inelastic light scattering, a frequency shift corresponding to the characteristic vibrational energy of molecules(Reference Hata, Scholz and Ermakov18). Specifically, the carbon backbone of conjugated double bonds in carotenoids yields a unique fingerprint for identification and quantification via RRS(Reference Darvin, Sterry and Lademann19). In contrast to skin biopsies and plasma carotenoids, SCS is rapid, non-invasive and without the discomfort and complications from phlebotomy and biopsy. This makes SCS particularly suited for adolescent and older populations. In addition, SCS assay may be less susceptible to fluctuations in response to recent dietary intake and potential carotenoid degradation by heat, light and oxygen during sample preparation which enhances experiment reproducibility(Reference Kopec, Cooperstone, Cichon, Xu and Howard20Reference Meinke, Friedrich and Tscherch22).

However, as biomarkers of exposure, both SCS and plasma carotenoids are vulnerable to external influences including age, race and other dietary components. At present, although SCS validation studies had been conducted in Western and younger Asian populations(Reference Morgan, Graham and Marshall3,Reference Jahns, Johnson and Conrad23,Reference Rerksuppaphol and Rerksuppaphol24) , there is a need to explore a broader spectrum of individuals including middle-aged and older adults in Asia which may have vastly different dietary preferences. Moreover, while nutrients including fat and fibre had been evidenced to affect carotenoid bioaccessibility and assimilation(Reference Voutilainen, Nurmi and Mursu25,Reference Yonekura and Nagao26) , limited studies evaluated the impact of these constituents on SCS. Therefore, the aim of the present study is to concurrently validate the use of SCS and plasma carotenoids to assess dietary FV and carotenoids in a middle-aged and older Singaporean population, taking into consideration potential socio-demographic and nutritional confounders for a comprehensive assessment. It is hypothesised that SCS and plasma carotenoids will be associated with both dietary FV and carotenoids.

Methods

Study design and participants

The present cross-sectional study recruited middle-aged and older adults between September 2018 and October 2019. The National Healthcare Group’s Domain Specific Review Board approved the study protocol (study reference number 2018/00221) and the study was registered at clinicaltrials.gov as NCT03554954. All participants provided written informed consent and received monetary compensation for participation.

The participant inclusion criteria were as follows: (1) aged between 50 and 75 years, (2) able to give informed consent, (3) no consumption of dietary supplements such as carotenoids, multivitamins and natural extract unless willing to discontinue for a minimum of 1 month, (4) no significant changes in diet during the past year and (5) venous access sufficient for blood sampling. Following consent, participants were asked to complete a questionnaire to obtain information on their socio-demographic characteristics and medical history.

The participant flow diagram is shown in Fig. 1. From the 130 participants screened, a total of 108 participants were recruited for the study. Data from four participants who failed to provide dietary records and one participant whose plasma carotenoids and SCS were identified as an outlier via studentised residuals plots (i.e. > 3 or < –3) were excluded. Collectively, data from 103 participants were used for statistical evaluation.

Fig. 1. Flow diagram for participants of cross-sectional study.

Anthropometric and blood pressure measurements

Height and weight of the participants were measured using a stadiometer (Seca) recorded to the nearest 0·01 m and 0·1 kg, respectively. Waist circumference was measured with a measuring tape according to WHO standards(Reference Al-Khudri, Cowan and Guthold27). Both resting systolic and diastolic blood pressures were measured while seated using an automated blood pressure monitor (Omron, HEM-7121). All measurements and readings were taken at least twice with the average calculated and used as the final readings.

Dietary data

Dietary data were obtained using 3-d food records collected over two weekdays and one weekend which were analysed using the Dietplan 7 software (Forestfield Software Ltd). Recording procedures were carefully instructed by trained research staff with visual aids to ensure accurate entries and portion size estimations. Clear instructions were also provided to remind participants not to deviate from their habitual diet during dietary record. Details recorded include the specific food consumed, mode of food preparation, serving size and meal timings. Nutritional information was obtained primarily from the US Department of Agriculture (USDA) database with reference to the Singapore Health Promotion Board database(28) and nutritional information panels for commercially available food products as secondary data sources. Nutritional data obtained from the secondary sources were verified and cross-referenced with close alternatives from the USDA database to ensure an accurate representation and consistency. Dietary FV intake was described according to serving number which was based on guidelines and schemes set by the WHO and National Health Service. One serving of either fruit or vegetable was defined as 80 g in its fresh or cooked form, 30 g in its dried form or 150 ml of 100 % pure juice(Reference Al-Khudri, Cowan and Guthold27,Reference Lewis, Ahern and Jebb29) . This is with the exclusion of starchy vegetables (e.g. potatoes, cassava, tapioca, etc.) and pulses (e.g. beans, chickpeas, lentils, etc.).

Blood collection and blood lipid-lipoprotein and glucose measurements

Fasting-state blood was collected from the antecubital vein by a trained phlebotomist into EDTA-treated, potassium oxalate/sodium fluoride-treated and plain tubes. EDTA- and potassium oxalate/sodium fluoride-treated tubes were immediately centrifuged at 3000 g, 15 min at 4°C while plain tubes were kept on ice for 15 min before centrifugation at similar settings. Aliquots (500 µl) of the plasma and serum were stored at −80°C until analysis.

Plasma glucose and the serum lipid-lipoprotein profile were measured with Siemens ADVIA Chemistry XPT and ADVIA 1800 systems (Siemens Healthcare Diagnostics) at Quest Laboratories.

Plasma carotenoid analysis by HPLC

The extraction of plasma carotenoids was adapted from Kim et al. (Reference Kim, Gordon and Ferruzzi30) with minor modifications. Plasma aliquots (900 µl) were treated with methanol (1 ml) containing 0·1 % (w/v) butylated hydroxytoluene. The extraction of plasma carotenoids was carried out with acetone–petroleum ether (1:2, v/v) (4 ml) and petroleum ether (2 ml twice). The extracts were evaporated to dryness under N2 gas and reconstituted in methanol–methyl tert-butyl ether (1:1, v/v) with 0·1 % butylated hydroxytoluene.

Six plasma carotenoids, namely α-carotene, β-carotene, β-cryptoxanthin, lycopene, lutein and zeaxanthin, were quantified by HPLC (Waters Alliance e2695 Separation Module; Waters) with photodiode array at 450 nm, with the exception of lycopene (470 nm). Separation of carotenoids was conducted using a C30, 250 × 4·6-mm, bonded silica reversed-phase column (YMC). A pair of mobile phases (methanol–methyl tert-butyl ether–water (81:15:4, by vol.) and methanol–methyl tert-butyl ether–water (6:90:4, by vol.)) were used for gradient elution at 1·0 ml/min, 25°C. The standard curves and retention times of pure carotenoid standards were used for the identification and quantification of plasma carotenoid concentrations. Acetone, methanol and petroleum ether were purchased from VWR International while butylated hydroxytoluene, methyl tert-butyl ether and the carotenoid standards were purchased from Sigma-Aldrich.

Skin carotenoid analysis by resonance Raman spectroscopy

Utilising RRS, SCS was measured with a Pharmanex S3 biophotonic scanner (NuSkin). Participants were guided to place their palm on the sensor for an analysis which lasted around 30 s. The score obtained had a range from 10 000 to 89 000 arbitrary units (a.u.), where a high score would indicate higher carotenoids concentration in the skin. A minimum of two readings was obtained, and the average SCS was calculated.

Power calculation and statistical analysis

SCS was not a primary outcome of interest for the present cross-sectional study and was not used for the derivation of the original sample size estimates. Retrospectively, post hoc power analysis was conducted with G * Power 3.1 (Heinrich-Heine-Universität)(Reference Faul, Erdfelder and Buchner31) based on the associations between SCS and dietary FV at α = 0·05 (coefficient of determination = 0·0825; two-tailed). Based on the population size of 103, the present study would yield a sufficiently high power of 86 %.

An evaluation of potential confounding factors was performed using multiple linear regressions (MLR) and ANCOVA for continuous and categorical variables, respectively. Dietary total carotenoids were controlled to identify population characteristics which influenced SCS and plasma carotenoids independent of the dietary source. SCS and plasma carotenoids were compared against socio-demographic characteristics (age, sex, race, BMI, waist circumference, cigarette smoking and use of prescription medication (for blood glucose, lipid and blood pressure control)), as well as with a thorough coverage of nutritional data which included energy, macronutrients (carbohydrate, sugar, fibre, protein, total fat, saturated fat, monounsaturated fat, polyunsaturated fat) and micronutrients (Na, K, Ca, vitamin A, vitamin B9, vitamin B12, vitamin C, vitamin D and vitamin E).

The associations between dietary FV and carotenoids with both SCS and plasma carotenoids were first examined with simple linear regression. Pearson’s correlation was further used for pairwise comparisons between skin, plasma and dietary carotenoids. Following which, adjusted for defined socio-demographic covariates, a MLR model was used to assess the associations between dietary FV and carotenoids with both SCS and plasma carotenoids. Nutritional covariates were also incorporated into the statistical models if they were either highly established confounders to carotenoid bioavailability (i.e. fat and fibre)(Reference Voutilainen, Nurmi and Mursu25,Reference Yonekura and Nagao26) or were likewise identified to impact plasma carotenoids or SCS as independent covariates.

Data analyses were conducted using STATA/MP 13 (STATACORP LP). All data are presented as means with their standard errors or as β-coefficients with 95 % CI, with P < 0·05 considered for statistical significance.

Results

Socio-demographic characteristics

The characteristics of 103 middle-aged and older participants (age: 59 (SEM 1) years; BMI: 23·8 (SEM 0·4) kg/m2) are shown in Table 1. Both females (n 58) and males (n 45) were recruited, with racial Chinese making up the majority (n 90). The population was generally healthy based on their BMI, blood pressure, plasma glucose and serum lipid-lipoprotein concentrations as well as their cigarette smoking history and use of prescription medication. The mean plasma carotenoid concentration and SCS were 2·07 (SEM 0·09) µmol/l and 33 277 (SEM 1102) a.u., respectively.

Table 1. Baseline population characteristics

(Mean values with their standard errors; ranges; numbers)

a.u., Arbitrary units.

* To convert glucose in mg/dl to mmol/l, multiply by 0·0555. To convert cholesterol in mg/dl to mmol/l, multiply by 0·0259. To convert TAG in mg/dl to mmol/l, multiply by 0·0113.

Dietary characteristics

The population dietary characteristics are tabulated in Table 1. The intake of dietary FV was 2·3 (SEM 0·2) and 2·4 (SEM 0·2) servings/d, respectively. Dietary total carotenoid intake was 10·52 (SEM 0·80) mg/d with individual carotenoids β-carotene, lutein and zeaxanthin, lycopene, α-carotene and β-cryptoxanthin intake ranked in descending order.

Identification of covariates

Socio-demographic covariates for plasma carotenoids were identified to be: age, BMI and prescription medication, and for SCS: sex, BMI, cigarette smoking and prescription medication (online Supplementary Table S1). Waist circumference, while identified as a covariate, was not adjusted for as it exhibited strong collinearity with BMI. Among the nutritional data, dietary vitamin C was identified as a covariate for both plasma carotenoids and SCS while vitamin A was identified as a covariate for SCS only (online Supplementary Table S2). Coupled with well-established confounders of fat and fibre, nutritional covariates were singularly added to and adjusted for in separate MLR models.

Regression analyses

Simple linear regression, as tabulated in Tables 2 and 3, yielded positive associations between dietary FV with plasma carotenoids and SCS (β plasma (regression coefficient): 0·086 (95 % CI 0·023, 0·149) µmol/l per FV serving, P = 0·008; β skin: 1133 (95 % CI 387, 1878) a.u./FV serving, P = 0·003). For total dietary carotenoids, only SCS showed a significant correlation (β skin: 274 (95 % CI 9, 540) a.u./mg, P = 0·04). According to Fig. 2 however, no linearity was observed between dietary carotenoids and both plasma carotenoids and SCS. With individual dietary carotenoids, positive associations were observed with corresponding plasma carotenoids for α-carotene (β plasma: 0·039 (95 % CI 0·014, 0·063) µmol/l per mg, P = 0·002), β-cryptoxanthin (β plasma: 0·432 (95 % CI 0·195, 0·670) µmol/l per mg, P < 0·001) and lycopene (β plasma: 0·044 (95 % CI 0·027, 0·061) µmol/l per mg, P < 0·001) while SCS depicted positive associations with α-carotene (β skin: 2095 (95 % CI 51, 4139) a.u./mg, P = 0·04) and lutein and zeaxanthin (β skin: 804 (95 % CI 52, 1556) a.u./mg, P = 0·04). Between plasma carotenoids and SCS, a significant positive association was observed (ρ (correlation coefficient) = 0·626; P < 0·001) (Fig. 2).

Table 2. Regression analyses of plasma carotenoids with daily fruit, vegetable and carotenoid intake

(Regression coefficients and 95 % confidence intervals)

* Model 1 was adjusted for age, BMI and prescription medication.

Model 2 was adjusted for age, BMI, prescription medication and daily total fat intake.

Table 3. Regression analyses of skin carotenoids with daily fruit, vegetable and carotenoid intake

(Regression coefficients and 95 % confidence intervals)

a.u., Arbitrary units.

* Model 1 was adjusted for sex, BMI, prescription medication and cigarette smoking.

Model 2 was adjusted for sex, BMI, prescription medication, cigarette smoking and daily total fat intake.

Model 3 was adjusted for sex, BMI, prescription medication, cigarette smoking and daily saturated fat intake.

§ Model 4 was adjusted for sex, BMI, prescription medication, cigarette smoking and daily monounsaturated fat intake.

Model 5 was adjusted for sex, BMI, prescription medication, cigarette smoking and daily polyunsaturated fat intake.

Fig. 2. Scatterplots depicting correlations between (a) plasma v. dietary carotenoids, (b) skin v. dietary carotenoids and (c) skin v. plasma carotenoids. ρ, Correlation coefficient; a.u., arbitrary units.

Upon the adjustment of socio-demographic covariates (model 1; Tables 2 and 3), dietary FV continued to show positive associations with plasma carotenoids (β plasma: 0·076 (95 % CI 0·021, 0·132) µmol/l per FV serving, P = 0·008) and SCS (β skin: 1036 (95 % CI 363, 1708) a.u./FV serving, P = 0·003). Likewise, significant associations were observed with dietary carotenoids (β plasma: 0·020 (95 % CI 0·000, 0·040) µmol/l per mg, P = 0·05; β skin: 265 (95 % CI 23, 506) a.u./mg, P = 0·03). Similar to the simple linear regression, model 1 continued to depict positive associations between individual carotenoids with the corresponding plasma carotenoids (α-carotene (P = 0·008), β-cryptoxanthin (P < 0·001) and lycopene (P < 0·001)). SCS, on the other hand, depicted associations with both lutein and zeaxanthin (P = 0·04)) and lycopene (P = 0·04).

With the inclusion of total fat intake as a covariate (model 2; Tables 2 and 3), the significant associations between both SCS and plasma carotenoids with dietary FV as well as carotenoids (total and individual) were maintained with reference to model 1 (without dietary covariates). This remained largely true with the inclusion of SFA (model 3), MUFA (model 4) and PUFA (model 5) (Table 3 and online Supplementary Table S3) as covariates, with the exception of the association between SCS and dietary carotenoids after PUFA was adjusted ((β skin: 247 (95 % CI –13, 508) a.u./mg, P = 0·06); model 5). Correspondingly, a similar change was detected for individual dietary carotenoids lutein and zeaxanthin (β skin: 690 (95 % CI –2, 1383) a.u./mg, P = 0·05) and lycopene (β skin: 730 (95 % CI –58, 1518) a.u./mg, P = 0·07) (Table 3).

For plasma carotenoids, the adjustment of fibre contributed to no changes in regression analyses. However, significant associations with both FV and dietary total carotenoids were null (P > 0·05) when controlled for daily vitamin C intake (online Supplementary Table S4). On the other hand for SCS, adjustment of vitamin A contributed to no effects although adjustments of both vitamin C and fibre resulted in no associations with dietary FV and carotenoids (P > 0·05; online Supplementary Table S5).

Discussion

FV are the main sources of dietary carotenoids. Apart from the blood, carotenoids can accumulate in the skin which serves as a site for deposition(Reference Darvin, Sterry and Lademann19). SCS measured by RRS had received emerging interest due to its ease of measurement and accurate representation of FV and carotenoid intake. Previous cross-sectional studies reported positive associations between plasma carotenoids as well as SCS with both dietary FV and carotenoids(Reference Morgan, Graham and Marshall3,Reference Scarmo, Henebery and Peracchio4,Reference Mayne, Cartmel and Scarmo14,Reference Jahns, Johnson and Conrad23,Reference Matsumoto, Suganuma and Shimizu32,Reference Aguilar, Wengreen and Dew33) . In the present study, the authors also observed positive correlations which support the use of both plasma carotenoids and SCS as biomarkers for dietary FV and carotenoid intake in a middle-aged and older Singaporean population.

The mean SCS reported in the present study was similar to participants from the Strong Hearts, Healthy Communities study (mean = 34 100 a.u.) which recruited predominantly Caucasian, obese women (n 157) and used an identical device for SCS analysis(Reference Morgan, Graham and Marshall3). This was coupled with similar dietary total carotenoids (mean = 10·0 mg/d) compared with the present population (mean = 10·5 mg/d). However, there was discrepancy in the intake pattern of dietary carotenoids compared with Western populations whose carotenoid intakes consisted mostly of lycopene(Reference Christensen, Lawler and Mares34). The present results bore closer resemblance to a previous assessment on middle-aged and older Asian adults which likewise consumed predominantly β-carotene, followed by lutein and zeaxanthin(Reference Cao, Zeng and Li35).

In alignment with the hypothesis, both dietary carotenoids and FV showed positive associations with plasma carotenoids and SCS after the socio-demographic covariates were controlled. Plasma carotenoids in particular had been extensively validated as a biomarker for dietary carotenoids and FV intake. This included a systematic review and meta-analysis conducted by Burrows et al. (Reference Burrows, Williams and Rollo36) which observed a positive relationship between dietary and plasma carotenoids. Additionally, the European Prospective Investigation into Cancer and Nutrition (EPIC), a large-scale multicentre prospective cohort study, also demonstrated its usefulness as a biomarker for dietary FV(Reference Al-Delaimy, Ferrari and Slimani9). Examining individual carotenoid species, the results indicated that while a majority of carotenoids depicted a similar trend, there was an absence of associations between dietary and plasma β-carotene, lutein and zeaxanthin.

Among the carotenoids, β-carotene in particular displays the highest substrate affinity to β-carotene dioxygenase-1, making it most susceptible to vitamin A conversion(Reference Yeum and Russell37). Compared with other provitamin A carotenoids, β-carotene can be enzymatically cleaved to yield 2 molecules of retinal via a single-step process in enterocytes. This may have increased plasma β-carotene depletion and hence, the absence of significant associations with dietary β-carotene. For the most abundantly consumed xanthophylls lutein and zeaxanthin, this lack of association may be attributed to its markedly lower half-life and more rapid clearance from the circulation(Reference Oshima, Sakamoto and Ishiguro38). Conjugation with oxygen increases hydrophilicity which influences the orientation of xanthophylls in circulating lipoproteins(Reference McNulty, Jacob and Mason39). In contrast to the hydrophobic carotenes packaged in the lipoprotein core, xanthophylls were postulated to be metabolised and deposited more efficiently(Reference Milde, Elstner and Graßmann40).

Carotenoids in the skin were reported to reflect dietary intake and its bioavailability from food sources(Reference Canene-Adams, Erdman, Britton, Pfander and Liaaen-Jensen41). This is supported by the present positive associations between SCS with dietary carotenoids and FV. The uptake and depletion kinetics was described by Jahns et al. (Reference Jahns, Johnson and Mayne42) who reported that SCS mirrored the changes in plasma carotenoids. In comparison however, the skin, which serves as a site for deposition, was regarded to be less responsive than fluctuations in blood, which functioned as a transport medium(Reference Mayne, Cartmel and Scarmo14,Reference Meinke, Darvin and Vollert43) . This makes SCS a promising indicator of long-term carotenoid intake.

Moreover, in contrast to plasma carotenoids, SCS reflects total carotenoids. This includes, for instance, fucoxanthin and capsanthin which may be present in lower quantities in FV, with reference to the six main plasma carotenoids detected. Therefore, caution ought to be exercised when interpreting associations with single dietary carotenoids and SCS since carotenoids more abundantly present may reflect stronger associations. This was evidenced by the marked correlations with lycopene, lutein and zeaxanthin which are the most consumed carotenoids in this population after β-carotene.

In addition to established socio-demographic confounders such as sex, BMI and smoking history which aligned with the covariates identified from previous clinical studies(Reference Meinke, Friedrich and Tscherch22,Reference Meinke, Lauer and Taskoparan44) , dietary factors including fibre and fat intake also play an important role in the bioaccessibility and bioavailability of carotenoids. However, limited studies considered the influence of dietary confounders on plasma carotenoids and SCS(Reference Voutilainen, Nurmi and Mursu25,Reference Nagao, Kotake-Nara and Hase45) . With the adjustment of total fat as well as SFA, MUFA and PUFA individually, the present study largely showed no marked change in association, in contrast to MLR model 1 (controlled for socio-demographic covariates only). While the role of dietary fat in increasing carotenoid absorption had been well studied in postprandial experiments, patterning of food intake needs to be taken into consideration(Reference Kim, Gordon and Ferruzzi30,Reference Unlu, Bohn and Clinton46,Reference Brown, Ferruzzi and Nguyen47) . Specifically, carotenoid absorption may only be enhanced when carotenoid-rich foods are co-consumed with dietary fat(Reference Unlu, Bohn and Clinton46). However, as this is a cross-sectional study, it is not optimised to take into consideration the variable of time. This could possibly explain the absence of significant associations.

Nevertheless, it is noteworthy to highlight that the association between dietary carotenoids and SCS was null when adjusted for PUFA. This suggests that among the dietary fats, PUFA intake in particular may confound the observed associations between dietary carotenoids and SCS. Previous studies on genetically obese rats have shown that PUFA administration raised the mRNA and levels of hepatic scavenger receptor class B1 type 1 (SR-B1) compared with controls fed with SFA-rich groundnut oil(Reference Sheril, Jeyakumar and Jayashree48) while fish oil intake was also observed to increase CD36 expression in abdominal adipocytes of spontaneously hypertensive rats(Reference Alexander Aguilera, Hernández Díaz and Lara Barcelata49). Similarly expressed in epidermal keratinocytes, lipid membrane transporters SR-B1 and CD36 had been thought to facilitate carotenoids absorption into the skin(Reference Alessio, Gruarin and Castagnoli50Reference Reboul52). Therefore, its raised expression may explain the influence of PUFA on SCS although this hypothesis will need to be validated. Thus, future studies could investigate the effects of co-consuming dietary fat at different levels of saturation on the eventual deposition of carotenoids in the skin.

Corresponding to the adjustments with dietary fat, controlling for vitamin A did not exert any considerable influence on the associations between SCS with dietary FV and carotenoids. However, correlations for both SCS and plasma carotenoids were mostly non-significant following the inclusion of fibre and vitamin C into the MLR models. This indicates a possible influence of vitamin C and fibre on the status of plasma and skin carotenoids. Notably, dietary fibre had been established to lower carotenoid bioavailability as a result of matrix entrapment during digestion(Reference Palafox-Carlos, Ayala-Zavala and Gonzalez-Aguilar53,Reference Riedl and Linseisen54) while vitamin C, which may exhibit antioxidant synergy with carotenoids, could aid in the extension of its half-life(Reference Palozza55,Reference Böhm, Edge and Truscott56) . Nonetheless, in contrast to dietary fat, vitamin C and fibre are synonymous with and strongly correlated with FV intake (data not shown). This results in multicollinearity which can weaken the regression model’s precision and statistical power.

The strengths of the present study include the use of a rapid, non-invasive method to analyse carotenoids in the skin, where skin biopsies would otherwise be challenging in this population due to the discomfort from excision(Reference Meléndez-Martínez, Stinco and Mapelli-Brahm15). Another strength lies in the rigorous collection of dietary information. This was challenging to achieve, particularly in the present, predominantly Asian population whose cuisines are often composite, with a variety of ingredients. To maintain dietary data precision, each food item was deconstructed according to its ingredients with careful consideration of the cooking method, portion size and product details. This yields a thorough depiction of the nutritional data which subsequently allow for a more meticulous identification of potential dietary confounders to be applied in the present study. Furthermore, quantification of FV as servings in accordance to WHO and National Health Service guidelines also provides a more characteristic description, in contrast to earlier studies which measured FV intake by weight(Reference Al-Khudri, Cowan and Guthold27,Reference Lewis, Ahern and Jebb29) . This quantification method standardises the dietary data of FV intake according to typical consumption quantities v. the absolute weights which improve research translatability and representation from a nutritional perspective. For instance, a serving of dried fruit (30 g) deviates substantially in absolute weight in contrast to fresh alternatives (80 g) although the weight of the fruit pre-processing may be similar.

Nevertheless, a weakness which needs to be highlighted is the discrepancy in optical properties of carotenoids despite the similar conjugated carbon molecular structure. In particular, this may be a limitation for specific colourless carotenoids including phytoene and phytofluene which can be further investigated in future studies. The representativeness of SCS for FV intake may also be challenged since some FV contains little to no carotenoids while other foods which are not FV (e.g. eggs) may contain carotenoids. Nevertheless, carotenoid status can serve as a reflective marker of nutritional factors which are abundant in FV beyond carotenoids alone. As deduced in the present study, antioxidants such as vitamin C were also strongly correlated with SCS. While these do not serve as a direct carotenoid source, synergism between antioxidants, as described earlier, may extend carotenoid half-life. This indirectly raises plasma and skin concentrations and hence, supports its use as FV biomarkers. However, it should be noted that the large lipid to protein ratio of the skin may inherently favour the deposition of the more hydrophobic carotenes, as deduced by an earlier trial which examined the correlations using skin biopsy samples(Reference Scarmo, Cartmel and Lin57). Lastly, it is worth noting that while the use of 3-d food records at present yields greater accuracy, specifically in the context of dietary carotenoids data, it may lack representability for long-term dietary patterns.

In conclusion, skin carotenoids, similar to plasma carotenoids, may serve as a biomarker for both dietary FV and carotenoid intake in the middle-aged and older Singaporean population. The application of carotenoid biomarkers, however, may be susceptible to confounding from socio-demographic and other nutritional influences which ought to be considered for a more comprehensive assessment.

Acknowledgements

We would like to extend our appreciation to fellow researchers Delia Pei Shan Lee, Denise Tan, Jasmine Hui Min Low, Xuejuan Xia and Wan Peng Lew for their assistance during the clinical study. We are also grateful to Huey Lee Lew for her technical assistance.

The research was funded by the National University of Singapore, Singapore, the Ministry of Education Academic Research Fund Tier 1, Singapore and the Agency of Science, Technology and Research Industry Alignment Fund, Singapore.

D. W. K. T., C. N. S. and J. E. K. conceptualised the research. J. E. K. acquired the research funding. D. W. K. T., W. W. L., C. N. S. and Y. Y. were involved in methodology development and validation. D. W. K. T., W. W. L. and C. N. S. investigated and curated the data. D. W. K. T. and W. W. L. conducted the formal analysis, wrote the manuscript under the supervision of J. E. K. and D. W. K. T. and J. E. K. had primary responsibility for the final content. All authors read and approved the final manuscript.

The authors report no conflicts of interest.

Supplementary material

For supplementary material referred to in this article, please visit https://doi.org/10.1017/S0007114521000143

References

Wang, P-Y, Fang, J-C, Gao, Z-H, et al. (2016) Higher intake of fruits, vegetables or their fiber reduces the risk of type 2 diabetes: a meta-analysis. J Diabetes Investig 7, 5669.CrossRefGoogle ScholarPubMed
Aune, D, Giovannucci, E, Boffetta, P, et al. (2017) Fruit and vegetable intake and the risk of cardiovascular disease, total cancer and all-cause mortality: a systematic review and dose-response meta-analysis of prospective studies. Int J Epidemiol 46, 10291056.10.1093/ije/dyw319CrossRefGoogle ScholarPubMed
Morgan, EH, Graham, ML, Marshall, GA, et al. (2019) Serum carotenoids are strongly associated with dermal carotenoids but not self-reported fruit and vegetable intake among overweight and obese women. Int J Behav Nutr Phys Act 16, 104115.CrossRefGoogle Scholar
Scarmo, S, Henebery, K, Peracchio, H, et al. (2012) Skin carotenoid status measured by resonance Raman spectroscopy as a biomarker of fruit and vegetable intake in preschool children. Eur J Clin Nutr 66, 555560.CrossRefGoogle ScholarPubMed
Shim, J-S, Oh, K & Kim, HC (2014) Dietary assessment methods in epidemiologic studies. Epidemiol Health 22, e2014009.10.4178/epih/e2014009CrossRefGoogle Scholar
Cazzonelli, CI (2011) Carotenoids in nature: insights from plants and beyond. Funct Plant Biol 38, 833.CrossRefGoogle ScholarPubMed
Eggersdorfer, M & Wyss, A (2018) Carotenoids in human nutrition and health. Arch Biochem Biophys 652, 1826.10.1016/j.abb.2018.06.001CrossRefGoogle ScholarPubMed
Baldrick, FR, Woodside, JV, Elborn, JS, et al. (2011) Biomarkers of fruit and vegetable intake in human intervention studies: a systematic review. Crit Rev Food Sci Nutr 51, 795815.10.1080/10408398.2010.482217CrossRefGoogle ScholarPubMed
Al-Delaimy, WK, Ferrari, P, Slimani, N, et al. (2005) Plasma carotenoids as biomarkers of intake of fruits and vegetables: individual-level correlations in the European Prospective Investigation into Cancer and Nutrition (EPIC). Eur J Clin Nutr 59, 13871396.10.1038/sj.ejcn.1602252CrossRefGoogle Scholar
Pezdirc, K, Hutchesson, MJ, Williams, RL, et al. (2016) Consuming high-carotenoid fruit and vegetables influences skin yellowness and plasma carotenoids in young women: a single-blind randomized crossover trial. J Acad Nutr Diet 116, 12571265.CrossRefGoogle ScholarPubMed
van Kappel, AL, Martínez-García, C, Elmståhl, S, et al. (2001) Plasma carotenoids in relation to food consumption in Granada (southern Spain) and Malmö (southern Sweden). Int J Vitam Nutr Res 71, 97102.CrossRefGoogle Scholar
Campbell, DR, Gross, MD, Martini, MC, et al. (1994) Plasma carotenoids as biomarkers of vegetable and fruit intake. Cancer Epidemiol Biomarkers Prev 3, 493500.Google ScholarPubMed
Couillard, C, Lemieux, S, Vohl, M-C, et al. (2016) Carotenoids as biomarkers of fruit and vegetable intake in men and women. Br J Nutr 116, 12061215.10.1017/S0007114516003056CrossRefGoogle ScholarPubMed
Mayne, ST, Cartmel, B, Scarmo, S, et al. (2010) Noninvasive assessment of dermal carotenoids as a biomarker of fruit and vegetable intake. Am J Clin Nutr 92, 794800.CrossRefGoogle ScholarPubMed
Meléndez-Martínez, AJ, Stinco, CM & Mapelli-Brahm, P (2019) Skin carotenoids in public health and nutricosmetics: the emerging roles and applications of the UV radiation-absorbing colourless carotenoids phytoene and phytofluene. Nutrients 11, 1093.10.3390/nu11051093CrossRefGoogle Scholar
Darvin, ME, Fluhr, JW, Caspers, P, et al. (2009) In vivo distribution of carotenoids in different anatomical locations of human skin: comparative assessment with two different Raman spectroscopy methods. Exp Dermatol 18, 10601063.CrossRefGoogle ScholarPubMed
Darvin, ME, Patzelt, A, Knorr, F, et al. (2008) One-year study on the variation of carotenoid antioxidant substances in living human skin: influence of dietary supplementation and stress factors. J Biomed Opt 13, 044028.10.1117/1.2952076CrossRefGoogle Scholar
Hata, TR, Scholz, TA, Ermakov, IV, et al. (2000) Non-invasive Raman spectroscopic detection of carotenoids in human skin. J Invest Dermatol 115, 441448.CrossRefGoogle ScholarPubMed
Darvin, ME, Sterry, W, Lademann, J, et al. (2011) The role of carotenoids in human skin. Molecules 16, 1049110506.10.3390/molecules161210491CrossRefGoogle Scholar
Kopec, RE, Cooperstone, JL, Cichon, MJ, et al. (2012) Analysis methods of carotenoids. In Analysis of Antioxidant-Rich Phytochemicals, pp. 105148 [Xu, Z and Howard, LR, editors]. Oxford: Wiley-Blackwell.CrossRefGoogle Scholar
Ermakov, IV & Gellermann, W (2010) Validation model for Raman based skin carotenoid detection. Arch Biochem Biophys 504, 4049.10.1016/j.abb.2010.07.023CrossRefGoogle ScholarPubMed
Meinke, MC, Friedrich, A, Tscherch, K, et al. (2013) Influence of dietary carotenoids on radical scavenging capacity of the skin and skin lipids. Eur J Pharm Biopharm 84, 365373.10.1016/j.ejpb.2012.11.012CrossRefGoogle ScholarPubMed
Jahns, L, Johnson, LAK, Conrad, Z, et al. (2019) Concurrent validity of skin carotenoid status as a concentration biomarker of vegetable and fruit intake compared to multiple 24-h recalls and plasma carotenoid concentrations across one year: a cohort study. Nutr J 18, 7885.CrossRefGoogle ScholarPubMed
Rerksuppaphol, S & Rerksuppaphol, L (2012) Carotenoid intake and asthma prevalence in Thai children. Pediatr Rep 4, 25.CrossRefGoogle ScholarPubMed
Voutilainen, S, Nurmi, T, Mursu, J, et al. (2006) Carotenoids and cardiovascular health. Am J Clin Nutr 83, 12651271.10.1093/ajcn/83.6.1265CrossRefGoogle ScholarPubMed
Yonekura, L & Nagao, A (2007) Intestinal absorption of dietary carotenoids. Mol Nutr Food Res 51, 107115.10.1002/mnfr.200600145CrossRefGoogle ScholarPubMed
Al-Khudri, L, Cowan, M, Guthold, R, et al. (2005) The STEPS Instrument. WHO STEPS Surveillance Manual: The WHO STEPwise Approach to Chronic Disease Risk Factor Surveillance. Geneva: World Health Organization.Google Scholar
Health Promotion Board Singapore (2011) Energy & nutrient composition of food. Health Promotion Board Singapore. https://focos.hpb.gov.sg/eservices/ENCF/ (accessed November 2020).Google Scholar
Lewis, HB, Ahern, AL & Jebb, SA (2012) How much should I eat? A comparison of suggested portion sizes in the UK. Public Health Nutr 15, 21102117.10.1017/S1368980012001097CrossRefGoogle ScholarPubMed
Kim, JE, Gordon, SL, Ferruzzi, MG, et al. (2015) Effects of egg consumption on carotenoid absorption from co-consumed, raw vegetables. Am J Clin Nutr 102, 7583.CrossRefGoogle ScholarPubMed
Faul, F, Erdfelder, E, Buchner, A, et al. (2009) Statistical power analyses using G*Power 3.1: tests for correlation and regression analyses. Behav Res Methods 41, 11491160.CrossRefGoogle ScholarPubMed
Matsumoto, M, Suganuma, H, Shimizu, S, et al. (2020) Skin carotenoid level as an alternative marker of serum total carotenoid concentration and vegetable intake correlates with biomarkers of circulatory diseases and metabolic syndrome. Nutrients 12, 1825.10.3390/nu12061825CrossRefGoogle ScholarPubMed
Aguilar, SS, Wengreen, HJ & Dew, J (2015) Skin carotenoid response to a high-carotenoid juice in children: a randomized clinical trial. J Acad Nutr Diet 115, 17711778.10.1016/j.jand.2015.06.011CrossRefGoogle ScholarPubMed
Christensen, K, Lawler, T & Mares, J (2019) Dietary carotenoids and non-alcoholic fatty liver disease among US adults, NHANES 2003–2014. Nutrients 11, 1101.CrossRefGoogle Scholar
Cao, W, Zeng, F, Li, B, et al. (2018) Higher dietary carotenoid intake associated with lower risk of hip fracture in middle-aged and elderly Chinese: a matched case–control study. Bone 111, 116122.CrossRefGoogle ScholarPubMed
Burrows, TL, Williams, R, Rollo, M, et al. (2015) Plasma carotenoid levels as biomarkers of dietary carotenoid consumption: a systematic review of the validation studies. J Nutr Intermed Metab 2, 1564.10.1016/j.jnim.2015.05.001CrossRefGoogle Scholar
Yeum, K-J & Russell, RM (2002) Carotenoid bioavailability and bioconversion. Annu Rev Nutr 22, 483504.10.1146/annurev.nutr.22.010402.102834CrossRefGoogle ScholarPubMed
Oshima, S, Sakamoto, H, Ishiguro, Y, et al. (1997) Accumulation and clearance of capsanthin in blood plasma after the ingestion of paprika juice in men. J Nutr 127, 14751479.CrossRefGoogle ScholarPubMed
McNulty, H, Jacob, RF & Mason, RP (2008) Biologic activity of carotenoids related to distinct membrane physicochemical interactions. Am J Cardiol 101, S20S29.CrossRefGoogle ScholarPubMed
Milde, J, Elstner, EF & Graßmann, J (2007) Synergistic effects of phenolics and carotenoids on human low-density lipoprotein oxidation. Mol Nutr Food Res 51, 956961.CrossRefGoogle ScholarPubMed
Canene-Adams, K & Erdman, JW (2009) Absorption, transport, distribution in tissues and bioavailability. In Carotenoids, pp. 115148 [Britton, G, Pfander, H and Liaaen-Jensen, S, editors]. Basel: Birkhäuser Basel.CrossRefGoogle Scholar
Jahns, L, Johnson, LK, Mayne, ST, et al. (2014) Skin and plasma carotenoid response to a provided intervention diet high in vegetables and fruit: uptake and depletion kinetics. Am J Clin Nutr 100, 930937.CrossRefGoogle ScholarPubMed
Meinke, MC, Darvin, ME, Vollert, H, et al. (2010) Bioavailability of natural carotenoids in human skin compared to blood. Eur J Pharm Biopharm 76, 269274.10.1016/j.ejpb.2010.06.004CrossRefGoogle ScholarPubMed
Meinke, MC, Lauer, A, Taskoparan, B, et al. (2011) Influence on the carotenoid levels of skin arising from age, gender, body mass index in smoking/non-smoking individuals. Free Radicals Antioxid 1, 1520.10.5530/ax.2011.2.4CrossRefGoogle Scholar
Nagao, A, Kotake-Nara, E & Hase, M (2013) Effects of fats and oils on the bioaccessibility of carotenoids and vitamin E in vegetables. Biosci Biotechnol Biochem 77, 10551060.CrossRefGoogle ScholarPubMed
Unlu, NZ, Bohn, T, Clinton, SK, et al. (2005) Carotenoid absorption from salad and salsa by humans is enhanced by the addition of avocado or avocado oil. J Nutr 135, 431436.CrossRefGoogle ScholarPubMed
Brown, MJ, Ferruzzi, MG, Nguyen, ML, et al. (2004) Carotenoid bioavailability is higher from salads ingested with full-fat than with fat-reduced salad dressings as measured with electrochemical detection. Am J Clin Nutr 80, 396403.CrossRefGoogle ScholarPubMed
Sheril, A, Jeyakumar, SM, Jayashree, T, et al. (2009) Impact of feeding polyunsaturated fatty acids on cholesterol metabolism of dyslipidemic obese rats of WNIN/GR-Ob strain. Atherosclerosis 204, 136140.CrossRefGoogle ScholarPubMed
Alexander Aguilera, A, Hernández Díaz, G, Lara Barcelata, M, et al. (2006) Induction of CD36 expression elicited by fish oil PUFA in spontaneously hypertensive rats. J Nutr Biochem 17, 760765.10.1016/j.jnutbio.2005.12.007CrossRefGoogle ScholarPubMed
Alessio, M, Gruarin, P, Castagnoli, C, et al. (1998) Primary ex-vivo culture of keratinocytes isolated from hypertrophic scars as a means of biochemical characterization of CD36. Int J Clin Lab Res 28, 4754.10.1007/s005990050017CrossRefGoogle ScholarPubMed
Tsuruoka, H, Khovidhunkit, W, Brown, BE, et al. (2002) Scavenger receptor class B type I is expressed in cultured keratinocytes and epidermis. J Biol Chem 277, 29162922.CrossRefGoogle Scholar
Reboul, E (2019) Mechanisms of carotenoid intestinal absorption: where do we stand? Nutrients 11, 838.10.3390/nu11040838CrossRefGoogle ScholarPubMed
Palafox-Carlos, H, Ayala-Zavala, JF & Gonzalez-Aguilar, GA (2011) The role of dietary fiber in the bioaccessibility and bioavailability of fruit and vegetable antioxidants. J Food Sci 76, R6R15.10.1111/j.1750-3841.2010.01957.xCrossRefGoogle ScholarPubMed
Riedl, J & Linseisen, J (1999) Some dietary fibers reduce the absorption of carotenoids in women. J Nutr 129, 21702176.10.1093/jn/129.12.2170CrossRefGoogle ScholarPubMed
Palozza, P (2009) Pro-oxidant actions of carotenoids in biologic systems. Nutr Rev 56, 257265.10.1111/j.1753-4887.1998.tb01762.xCrossRefGoogle Scholar
Böhm, F, Edge, R & Truscott, TG (2012) Interactions of dietary carotenoids with singlet oxygen (1O2) and free radicals: Potential effects for human health. Acta Biochim Pol 59, 2730.CrossRefGoogle ScholarPubMed
Scarmo, S, Cartmel, B, Lin, H, et al. (2010) Significant correlations of dermal total carotenoids and dermal lycopene with their respective plasma levels in healthy adults. Arch Biochem Biophys 504, 3439.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Flow diagram for participants of cross-sectional study.

Figure 1

Table 1. Baseline population characteristics(Mean values with their standard errors; ranges; numbers)

Figure 2

Table 2. Regression analyses of plasma carotenoids with daily fruit, vegetable and carotenoid intake(Regression coefficients and 95 % confidence intervals)

Figure 3

Table 3. Regression analyses of skin carotenoids with daily fruit, vegetable and carotenoid intake(Regression coefficients and 95 % confidence intervals)

Figure 4

Fig. 2. Scatterplots depicting correlations between (a) plasma v. dietary carotenoids, (b) skin v. dietary carotenoids and (c) skin v. plasma carotenoids. ρ, Correlation coefficient; a.u., arbitrary units.

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