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Dietary patterns in the French adult population: a study from the second French national cross-sectional dietary survey (INCA2) (2006–2007)

Published online by Cambridge University Press:  18 May 2016

R. Gazan
Affiliation:
Risk Assessment Department, French Agency for Food, Environmental and Occupational Health & Safety (ANSES), 94701 Maisons-Alfort, France
C. Béchaux
Affiliation:
Risk Assessment Department, French Agency for Food, Environmental and Occupational Health & Safety (ANSES), 94701 Maisons-Alfort, France
A. Crépet
Affiliation:
Risk Assessment Department, French Agency for Food, Environmental and Occupational Health & Safety (ANSES), 94701 Maisons-Alfort, France
V. Sirot
Affiliation:
Risk Assessment Department, French Agency for Food, Environmental and Occupational Health & Safety (ANSES), 94701 Maisons-Alfort, France
P. Drouillet-Pinard
Affiliation:
Risk Assessment Department, French Agency for Food, Environmental and Occupational Health & Safety (ANSES), 94701 Maisons-Alfort, France
C. Dubuisson
Affiliation:
Risk Assessment Department, French Agency for Food, Environmental and Occupational Health & Safety (ANSES), 94701 Maisons-Alfort, France
S. Havard*
Affiliation:
Risk Assessment Department, French Agency for Food, Environmental and Occupational Health & Safety (ANSES), 94701 Maisons-Alfort, France
*
*Corresponding author: S. Havard, email sabrina.havard@anses.fr
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Abstract

Identification and characterisation of dietary patterns are needed to define public health policies to promote better food behaviours. The aim of this study was to identify the major dietary patterns in the French adult population and to determine their main demographic, socio-economic, nutritional and environmental characteristics. Dietary patterns were defined from food consumption data collected in the second French national cross-sectional dietary survey (2006–2007). Non-negative-matrix factorisation method, followed by a cluster analysis, was implemented to derive the dietary patterns. Logistic regressions were then used to determine their main demographic and socio-economic characteristics. Finally, nutritional profiles and contaminant exposure levels of dietary patterns were compared using ANOVA. Seven dietary patterns, with specific food consumption behaviours, were identified: ‘Small eater’, ‘Health conscious’, ‘Mediterranean’, ‘Sweet and processed’, ‘Traditional’, ‘Snacker’ and ‘Basic consumer’. For instance, the Health-conscious pattern was characterised by a high consumption of low-fat and light products. Individuals belonging to this pattern were likely to be older and to have a better nutritional profile than the overall population, but were more exposed to many contaminants. Conversely, individuals of Snacker pattern were likely to be younger, consumed more highly processed foods, had a nutrient-poor profile but were exposed to a limited number of food contaminants. The study identified main dietary patterns in the French adult population with distinct food behaviours and specific demographic, socio-economic, nutritional and environmental features. Paradoxically, for better dietary patterns, potential health risks cannot be ruled out. Therefore, this study demonstrated the need to conduct a risk–benefit analysis to define efficient public health policies regarding diet.

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Full Papers
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Copyright © The Authors 2016

Relationships between diet and health have already been strongly established in the literature( Reference Willett and Stampfer 1 , Reference Martinez-Gonzalez and Bes-Rastrollo 2 ). Accordingly, the consumption of some foods (e.g. red meat, fruits, fish, alcohol, etc.) or some nutrients (e.g. SFA, Na, K, etc.) is generally associated with an increased or decreased risk of many chronic diseases such as obesity( Reference de la Fuente-Arrillaga, Martinez-Gonzalez and Zazpe 3 5 ), hypertension( Reference Reddy and Katan 6 Reference McCartney, Byrne and Turner 8 ), CVD( Reference Reddy and Katan 6 , Reference de Oliveira Otto, Mozaffarian and Kromhout 9 Reference Mente, de Koning and Shannon 11 ) or certain cancers( Reference Liu and Ma 12 Reference Glade 14 ).

The standard approach for exploring these risk–benefit relationships has been to focus on one specific food or one nutrient without considering the diet as a whole( Reference Jacobs and Tapsell 15 ). However, it is necessary to consider the potential interactions or synergistic effects between foods or nutrients in order to depict the overall effect of diet on health( Reference Jacobs and Tapsell 15 Reference Jacobs and Steffen 17 ). Multidimensional approaches, such as the identification of dietary patterns, thus allow the estimation of more reliable associations between diet and health, taking into account the overall diet and its complexity( Reference Hu 18 Reference Moeller, Reedy and Millen 20 ). Moreover, the nutritional and socio-economic characterisation of dietary patterns can be used to define practical public health policies to promote better food behaviours in specific groups of consumers( 21 , Reference Tucker 22 ). From an environmental health perspective, dietary patterns can finally contribute to identify the most exposed consumers to a series of food contaminants( Reference Béchaux, Zetlaoui and Tressou 23 ).

In recent years, there has been increasing interest in studying national diets using a multidimensional approach( Reference Moeller, Reedy and Millen 20 , Reference Kant 24 ). The standard approaches applied were principal factor analyses, such as principal component analysis (PCA), multi-component analysis or cluster analysis (e.g. hierarchical cluster analysis (HCA))( Reference Hu 18 , Reference Schulze and Hoffmann 25 , Reference Wirfält, Drake and Wallström 26 ). In France, only a few studies have investigated dietary patterns at a national level using multifactorial methods( Reference Mahe, Francou and Colin 27 Reference Escalon, Bossard and Beck 30 ), and only one, to our knowledge, from a representative sample of the French population( Reference Bertin, Touvier and Dubuisson 29 ). Although these studies have provided comparable results, the lack of homogeneity of the methods performed and differences in the study population make comparisons difficult. Besides, standard approaches are not really suitable for constructing dietary patterns because of the inherent structure of the data. For instance, food consumption data include a significant number of zeros because of non-consumption of certain categories of foods and only have positive values. Hence, the assumption of a Gaussian distribution may not be valid( Reference Kipnis, Midthune and Buckman 31 ). Moreover, the approaches usually used show poor fit because of non-negative data and the excess of zero values, generally termed ‘sparse data’( Reference Shlens 32 ). Lee & Seung( Reference Lee and Seung 33 ) proposed a new latent-variable-based method, the negative matrix factorisation (NMF) method, specifically adapted to sparse and non-negative data. This method has already been proven to be effective in food risk assessment to identify dietary patterns or chemical mixtures( Reference Béchaux, Zetlaoui and Tressou 23 , Reference Zetlaoui, Feinberg and Verger 34 , Reference Sy, Feinberg and Verger 35 ).

The major aim of this study was thus to identify the main dietary patterns in the French adult population using the NMF approach and the food consumption data of a nationally representative survey (the second French national cross-sectional dietary survey (INCA2)). Next, we determined their main demographic and socio-economic characteristics and assessed their nutritional and environmental profiles in order to highlight their specific features. The dietary patterns revealed in this work will thus give an overview of the different food consumption behaviours in the French adult population, according to distinct dimensions.

Methods

Study population

The French INCA2 survey was carried out between December 2005 and May 2007 by the French Food Safety Agency( 36 ). This cross-sectional survey was initially designed to assess food intake in a nationally representative sample of the French population. Two independent random samples of 3- to 17-year-old children and 18- to 79-year-old adults were drawn using a multistage cluster sampling technique. The complex sampling frame was established from the national census, published by the French National Institute of Statistics and Economic Studies (INSEE), and it has been described elsewhere( Reference Dubuisson, Lioret and Touvier 37 , Reference Lioret, Touvier and Dubuisson 38 ). In brief, 181 geographical units, stratified by region of residence and size of urban area, were first randomly selected with a probability proportional to size. Then, households were randomly drawn within each primary sampling unit, and two independent sampling frames were set up: one restricted to households including at least one child and the other including households with or without children. Last, within each household, either a child or an adult was randomly selected. Participation rates were 63 % for adults and 69 % for children, yielding samples of 2624 adults and 1455 children, respectively. To ensure the national representativeness of each sample, a weighting factor for unequal sampling probabilities for differential non-responses by region, agglomeration size, age, sex, occupation of the household head, size of the household and season has been assigned to each individual. These variables were selected for adjustment because of high discrepancy between their distribution among the INCA2 sample and among the French population, using an external source (Labour force survey 2005-INSEE)( 36 , 39 ) (distribution among the adult sample is presented in the online Supplementary Table S1). The low variability of the weighting factor for adults (mean of 1 and a sd of 0·7) demonstrated the good representativeness of the INCA2 adult sample compared with the French general adult population.

Only adults were considered in this study. As recommended by the European Food Safety Authority, under-reporting subjects (i.e. those who, voluntarily or not, under-reported amounts consumed; 26·9 % of adult sample) were identified and included in the statistical analyses( 40 ). Besides, twenty-four subjects (0·9 % of the adult sample) with an extremely low total energy intake (TEI) were excluded from the final sample (estimated from the following formula: $${\rm log}\,{\rm (TEI)\,\lt\,mean} {\left( {{\rm log}\,{\rm (TEI}} \right)\,{\minus}\,{\rm 3\, \scale 70%{SD}}\,\left( {{\rm log}\,{\rm (TEI)}} \right)\right)}$$ ( Reference Lioret, Dubuisson and Touvier 41 ).

The INCA2 survey was approved by the French Data Protection Authority (Commission Nationale de l’Informatique et des Libertés) and the French National Council for Statistical Information (Conseil National de l’Information Statistique).

Data

Collection of data on food consumption

Dietary intake was assessed using a 7-d food record. A trained and certified investigator delivered at home the food record with a self-administered questionnaire and explained to the subjects how to complete them. The investigator returned to the home immediately after the week to check the accuracy of the information reported in both documents. Each day of the food record was divided into three main meals (breakfast, lunch and dinner) and three between-meal snacks. The subjects were asked to describe as precisely as possible the nature and the amount of all foods and beverages consumed during the survey week. Consumed quantities were estimated using the SU.VI.MAX (SUpplémentation en VItamines et en MInéraux AntioXydants) photographic booklet( Reference Hercberg, Deheeger and Preziosi 42 ) or expressed directly in weight or in household measures (e.g. spoon).

Foods and beverages declared were subsequently allocated a food code including 1280 food items and were categorised into forty-three food groups and 121 subgroups. McCann et al.( Reference McCann, Marshall and Brasure 43 ) and preliminary analyses (data not shown) showed that the quality of the description of dietary patterns is strongly affected by the level of aggregation of foods. To obtain a satisfactory trade-off between the level of detail to discriminate individuals according to their food consumption and the difficulty in exploring a large data set by factorial analysis, the nomenclature was modified step-by-step for this study and the 1280 food items were finally reclassified into seventy-four new food groups (Table 1). This classification was based on the foods’ nutritional composition and results of previous analyses (data not shown). Eight food groups (i.e. wholegrain pasta/rice/wheat, whole milk, skimmed milk, sweetened milk, low-fat cheese, dried fruit, nectar, soft drinks with fruit) with a consumption rate <10 % were excluded to avoid excessive noise in the data, which could lead to underline too particular and isolated dietary behaviours( Reference Bailey, Gutschall and Mitchell 44 , Reference Grieger, Scott and Cobiac 45 ).

Table 1 Nomenclature (food groups and consumption rate among the 2600 individuals)

Individual characteristics

Individual demographic and socio-economic variables were collected using face-to-face questionnaires and self-reported data. Questionnaires provided information on individual occupational status, education level and household wealth. Household wealth was defined through questions on the household income and other related variables such as ‘having gone away on holiday for more than 4 d within the last 12 months’, ‘the number of cars in the household’, ‘the number of domestic electrical appliances’, ‘how the financial situation is perceived’, ‘financial access to desired food products’, ‘whether the idea of lacking food would be a concern’, ‘giving up health care for financial reasons’ and ‘housing occupancy status’. A wealth index was derived from a correspondence analysis as already done by Fillol et al.( Reference Fillol, Dubuisson and Lafay 46 ) on variables describing household wealth (cited above). From the correspondence analysis, the score of each subject on the first principal component was used as the summary wealth index, which was divided into tertiles. In addition, for this study and according to Darmon et al.( Reference Darmon, Bocquier and Vieux 47 ), an individual was considered as living in a household experiencing food insecurity for financial reasons if she/he declared not having enough to eat (often or sometimes) because of economic reasons. Respondents were also asked to report other information such as age, sex, household composition, region and size of municipality in which the household was located. The variables and associated categories are described in the supporting information (online Supplementary Table S2).

Nutritional composition data

Nutritional intake was estimated by matching the French Food Composition database for the year 2008( Reference Feinberg, Favier and Laussucq 48 , 49 ) to the individual food consumption data. The individual average daily intake of macronutrients (i.e. total energy content, total carbohydrates, simple carbohydrates, total fats, SFA, proteins, alcohol, fibres and salt), minerals (i.e. Ca, Fe, Na, Mg, K) and vitamins (i.e. vitamins A, C, E, B1, B6, B9) was thus determined.

Food contamination data

Food contamination data were provided by the Second French Total Diet Study (TDS2). The TDS2 was conducted between 2006 and 2010 to evaluate the exposure of the French population to various substances that are likely to be found in foods ‘as consumed’. This study collected 20 000 food products, representing 212 types of food, for which 445 substances of interest were investigated. Food sampling was based on the data from the INCA2 survey, covering about 90 % of dietary consumption in the adult and child populations( Reference Sirot, Volatier and Calamassi-Tran 50 ). The 212 foods selected were linked to the INCA2 nomenclature. Of the 445 substances analysed, ten chemical substances, for which toxicological risk could not be excluded, were considered in this study( Reference Sirot, Volatier and Calamassi-Tran 50 ): trace elements (i.e. Pb, Al, Cd, inorganic As, organic Hg), acrylamide, one mycotoxin (i.e. deoxynivalenol (DON) and its acetylated derivatives), polychlorinated biphenyls (PCB)/dioxins (i.e. non-dioxin-like polychlorinated biphenyls (NDL-PCB), polychlorinated dibenzo-p-dioxins and dibenzofurans and dioxin-like polychlorinated biphenyl) and one additive (sulphites). The individual average daily exposure levels to the ten substances were estimated by combining individual food consumption data and contamination data from the food sample analysis, considering the same hypotheses as those described in the TDS2 report( 51 , 52 ).

Statistical analyses

Identification of dietary patterns

The NMF method was applied to the data set composed of the 2600 individual daily intake (g/d) of the sixty-six food groups. The analysis was performed on the overall adult population because similar dietary patterns were identified separately in men and women (data not shown). To account for individual weight in pattern identification, the iterative least squares (LS)-NMF algorithm developed by Wang et al.( Reference Wang, Kossenkov and Ochs 53 ) and based on that described by Lee & Seung( Reference Lee and Seung 33 ) was used. The goal of this factorial analysis is to summarise the information available in food consumption data into an optimal number k of consumption systems (CS)( Reference Béchaux, Zetlaoui and Tressou 23 , Reference Zetlaoui, Feinberg and Verger 34 , Reference Sy, Feinberg and Verger 35 ). In contrast to the PCA technique, each CS k in the NMF is defined as a positive linear combination of foods, which are generally associated in the same diet. Thus, all CS k describe the different associations of foods within the population. For each CS k , each food group had a coefficient that can be interpreted as the contribution of this food group to the construction of the system CS k . The weight of each CS k in each individual’s total diet was also determined. The diet of an individual is thus represented by a combination of different CS k .

To implement the NMF method, an optimal number of CS must be chosen. In this study, it was selected according to the quality of the interpretation of the CS (relevancy and ease of interpretation) and a graphical approach as done in Béchaux et al.( Reference Béchaux, Zetlaoui and Tressou 23 ) and Sy et al.( Reference Sy, Feinberg and Verger 35 ). Finally, a HCA was conducted to identify individuals with similar combinations of CS, defining a dietary pattern. The scores of each individual on the CS selected were used as input to the HCA. This classical clustering method consists of a step-by-step aggregation of individuals or groups of individuals who combined the CS in a similar way( Reference Kaufman 54 ), leading to one single class that includes the entire population. The number of clusters to retain was based on the inter-cluster inertia:total inertia ratio and the interpretability of the different clusters.

For each dietary pattern, the relative contribution (%) of each CS k was calculated (i.e. among individuals within the same dietary pattern, the contribution of the CS k is the ratio between the sum of weights of the CS k and the sum of the weights of all the CS). The CS that best describes each pattern was identified according to the V test indicator, which compares the average weight of the CS k in one dietary pattern with the average weight of the CS k in the whole population( Reference Lê, Josse and Husson 55 , Reference Lebart, Morineau and Piron 56 ). The CS k with significant and positive V tests were used to describe dietary patterns.

Characterisation of the dietary patterns

Demographic and socio-economic characteristics of each dietary pattern were investigated using binomial logistic regression. Each tested model identified the main demographic and socio-economic determinants of each dietary pattern independently of the others, by comparing with the overall population. Variables considered were age, level of education, wealth index, household size, household composition, occupational status, region, food insecurity and municipality size. These factors were selected because of their significant associations with the dietary patterns in univariate analysis (data not shown), as well as the consistent associations between dietary intake and these demographic and socio-economic determinants( Reference Novaković, Cavelaars and Geelen 57 Reference Cappuccio, Ji and Donfrancesco 61 ). All analyses were performed among men and women separately in order to take into account the significant interaction observed between sex and other factors (data not shown).

The mean nutrient intake was calculated for each dietary pattern. The association between nutritional intake and dietary patterns was assessed using ANOVA, and specific nutrient intake was identified by comparing the mean of each dietary pattern with the overall mean. All models were controlled for age, sex, season, TEI, level of education, wealth index, occupational status, household size, food insecurity, household composition, municipality size and region. As previously mentioned, these covariates were selected on preliminary analyses and previous studies( Reference Novaković, Cavelaars and Geelen 57 Reference Cappuccio, Ji and Donfrancesco 61 ).

Diet quality indices can evaluate the overall diet of an individual based on the following: (i) nutrient indicators, which reflect the adequacy to nutritional requirements; and (ii) foods to assess the variety of food intake( Reference Wirt and Collins 62 , Reference Alkerwi 63 ). Three scores were selected to illustrate the overall quality of the diet: the energy density (ED) of the diet( Reference Kant and Graubard 64 ), the mean adequacy ratio (MAR)( Reference Vieux, Soler and Touazi 65 ) and the dietary diversity score (DDS)( Reference Kant 66 ). The ED was used as an indicator of bad nutritional quality. Low ED has been shown to have a good nutritional quality( Reference Ledikwe, Blanck and Khan 67 ), and a decrease of ED of the diet is recommended by several public health authorities to prevent obesity( 68 , Reference Swinburn, Caterson and Seidell 69 ). For this study, ED was calculated for each individual with respect to the energy content (kJ/g (kcal/g)) of all foods consumed (except beverages such as water, soft drinks, alcohol, milk, coffee, tea). The mean ED was assessed for each dietary pattern. MAR was used as an indicator of good nutritional quality. The MAR represents the nutritional adequacy of the diet. Multiple versions of this index have been related to health indicators( Reference Keller, Ostbye and Bright-See 70 ), as well to other diet quality indexes( Reference Krebs-Smith, Smiciklas-Wright and Guthrie 71 Reference Torheim, Ouattara and Diarra 73 ). It was calculated as the mean percentage of the French daily recommended intake for twenty keys nutrients (namely proteins, fibres, vitamins A, C, E, D, B1, B2, B3, B6, B9, B12, Ca, K, Fe, Mg, Zn, Cu, I and Se). Each ratio was truncated at 100, so that a high intake of one nutrient could not compensate for the low intake of another: $MAR_{i} {\equals}{1 \over {20}}{\times}\mathop \sum\nolimits_{n\,\,1}^{n\,\,20} {{intake_{{i,\,n}} } \over {RDA_{n} }}{\times}100$ where $intake_{{i,n}} $ is the individual nutrient intake of the nutrient n and $RDA_{n} $ is the French RDA for the nutrient, taking into account the age and the sex of the individual( Reference Vieux, Soler and Touazi 65 ). Besides, the diet diversity is also a key element of the high quality of diets. A diverse diet increased the probability of nutrient adequacy( Reference Ruel 74 ), and it has been associated with positive health outcomes( Reference Lucenteforte, Garavello and Bosetti 75 , Reference Garavello, Giordano and Bosetti 76 ). DDS is defined as the number of specific food groups consumed over a specific period( Reference Kant 66 , Reference Drewnowski, Henderson and Shore 77 ). In this study, 3 d were randomly chosen for each subject: 2 weekdays and 1 weekend day. Five food groups were considered: dairy products (milk, yogurt, cheese), meat (red meat, poultry, fish and crustaceans), cereals (rice, pasta, wheat), fruits (fresh fruit, processed fruit and dry fruit) and vegetables (fresh vegetables and prepared vegetables). A food group was considered to have been consumed if at least 30 g was ingested during the 3 d. A DDS score was calculated for each individual, and it varied from 0 to 5. The mean DDS score was calculated for each pattern. Associations between dietary patterns and diet quality scores were also assessed using ANOVA adjusted for covariates, as described above. The mean of quality scores of each dietary pattern was thus compared with the overall mean.

Finally, mean contaminant exposure levels were calculated for each dietary pattern. Associations between dietary patterns and exposure levels were assessed using ANOVA-adjusted covariates described above. On the basis of the ANOVA model, specific exposure levels were identified by comparing the mean contaminant levels of each dietary pattern with the overall mean.

All values were survey-weighted means. A P value of 0·05 was used as the threshold of significance. All analyses were implemented in the software R version 3.0.2. The LS-NMF algorithm was implemented using the R package ‘NMF’( Reference Gaujoux and Seoighe 78 ). The package ‘Factominer’ was used to run the clustering( Reference Lê, Josse and Husson 55 ). The package ‘Survey’ was used to account for the complex INCA2 sampling frame design( Reference Lumley 79 ).

Results

Identification of dietary patterns

By combining graphical and interpretability criteria, seven distinct CS summarised the consumption behaviours of the 2600 individuals with respect to the sixty-six food groups. The inclusion of additional CS did not provide any further useful information for the interpretation of the dietary patterns. Moreover, additional CS were difficult to interpret, as they were composed of very few food groups (data not shown). Food groups with a score ≥2·5 % were considered as main contributors to a CS. Table 2 shows the relative contribution of the main food groups associated with each of the seven CS, designated as ‘Tradition’, ‘Snacking’, ‘Mediterranean’, ‘Simplicity’, ‘Dietetic’, ‘High-fat/sugar/salt’ and ‘Pleasant-and-convenient’ food behaviours. No strong Pearson’s correlations (<0·2715) were found between the different CS, suggesting that food behaviours related to each CS were independent of each other.

Table 2 Food consumption characteristics of each dietary pattern

CS, consumption system.

* CS contributing significantly more than the overall population (name and % of contribution).

Foods contributing >2·5 % to the construction of the CS (name and % of contribution).

Individuals in the population (%).

Then, seven dietary patterns with homogeneous CS combinations were identified and named according to their food consumption patterns. The major CS that best described each dietary pattern were identified and presented in Table 2. In brief, the first dietary pattern called ‘Small eater’ represented 23·0 % of the population. It consisted of consumers who used all the CS but to a lesser extent than the overall population, which means that they consumed all foods but in a lower quantity than the overall population. The second dietary pattern called ‘Health conscious’ grouped 12·6 % of the population and was characterised by individuals who used the dietetic CS significantly more than the overall population, which was mainly associated with low-fat or light foods, soups, fruits, tea and herbal tea and, paradoxically, cakes and pastries. The third dietary pattern, named ‘Mediterranean’, grouped 13·0 % of the population and was represented by individuals who used the Mediterranean CS significantly more than the overall population, which was characterised by unprocessed foods (vegetables, oil, herbs and spices, unprocessed fish, unprocessed fruit, etc.) and dairy products (condiments and cold dips (not low-fat), yogurt and cottage cheese (30–40 % fat)). Individuals in the fourth dietary pattern called ‘Sweet and processed’ grouped 13·5 % of the population. This pattern was characterised by food behaviour represented by the Pleasant-and-convenient CS characterised by an association of sweetened products such as breakfast cereals, fruit juices, chocolate bars/confectionery, dairy desserts and meals easy to prepare such as puff pastries, quiches, warm sauces, cereal-based mixed dishes, etc. The fifth dietary pattern identified as ‘Traditional’ accounted for 16·5 % of the population and was represented by individuals who followed the Tradition CS significantly more than the overall population and the High-fat/sugar/salt CS. Individuals in this pattern were therefore characterised by a consumption of foods such as alcohol (in particular wine), processed meat, cheese, bread products with wheat flour, coffee, red meat, but also crackers, confectionery without chocolate, grains and nuts, cakes and pastries, and sweetened biscuits, which characterised the High-fat/sugar/salt CS. The sixth pattern, identified as ‘Snacker’, was represented by 11·5 % of the population and was characterised by individuals who followed the Snacking CS, mainly represented by take-away products such as sandwiches, pizza, sodas and colas, puff pastries (such as ham puff pastry, ‘bouchée à la reine’, etc.) and processed foods such as processed potato products and cereal-based mixed dishes (as spaghetti carbonara, pasta gratin, etc.). This pattern also followed the High-fat/sugar/salt CS more than the overall population. The last dietary pattern called ‘Basic consumer’ accounted for 10·0 % of the population and was characterised by individuals who followed the Simplicity CS, which associated mostly simple foods such as butter/other animal fat, refined pasta/rice/wheat, unprocessed potatoes, yogurt and cottage cheese (20 % fat), bread and bread products (including bread, loaf and rusk).

Characterisation of dietary patterns

OR and 95 % from logistic regressions are detailed in the Table 3 for men and women separately. Regardless of sex, the probability of belonging to the Health-conscious and Mediterranean dietary patterns (only for men in Traditional pattern) increased with age, conversely to the probability of belonging to the Sweet-and-processed and Snacker dietary patterns. In addition, both women and men in the Health-conscious pattern were more likely to have a higher wealth index, as well as women from the Mediterranean pattern. In contrast, men in the Snacker pattern were more likely to have a relatively low wealth index. Women from the Traditional and Small-eater patterns were more likely to have a low educational level conversely to women from the Mediterranean pattern. Women belonging to the Traditional, Snacker or Health-conscious dietary patterns were more likely to live in households experiencing food insecurity, compared with women from the Small-eater, Mediterranean and Sweet-and-processed dietary patterns. Among men, individuals from the Sweet-and-processed dietary pattern were more likely to live in households experiencing food insecurity, conversely to men belonging to the Traditional and Small-eater dietary patterns. The Mediterranean and Snacker dietary patterns had a higher probability of living in large towns or cities.

Table 3 Demographic and socio-economic determinants of each dietary pattern by sex (Odds ratios and 95 % confidence intervals)

Nutritional intake for each dietary pattern is shown in Table 4. The energy intake was lower than the overall population for the Small-eater but higher for the Sweet-and-processed, Traditional and Basic-consumer dietary patterns. These three latter dietary patterns were also characterised by higher intake of SFA, mainly because of a higher consumption of savoury or sweet pastries, chocolate for Sweet-and-processed pattern and higher consumption of animal products (i.e. butter, cream, cheese or red meat) for Traditional and Basic-consumer patterns. The Health-conscious and Mediterranean dietary patterns had higher intake of fibres than the overall population, primarily because of a higher consumption of fruits, vegetables and wholemeal bread (for Health-conscious pattern only), leading also to higher intake of many minerals and vitamins than the overall population. In addition, Sweet-and-processed pattern showed higher intake of some minerals and vitamins, probably because of a higher consumption of fruits juice and breakfast cereals (which are, for most of them, fortified). Conversely, the Small-eater, Snacker, Traditional and Basic-consumer dietary patterns showed intake of almost all mineral and vitamins studied, which was lower than the overall population. Only the Traditional and Health-conscious dietary patterns had higher intake of Na than the overall population, primarily because of a high consumption of cheese and processed meat and a high consumption of wholemeal bread and bottled water for each pattern, respectively.

Scores of nutritional quality (DDS, MAR, ED) were significantly different across dietary patterns (Table 4). Mostly because of an insufficient intake of fruits and vegetables, the Traditional and Snacker dietary patterns showed significantly lower DDS values than the overall population; 20·4 and 30·7 % of individuals from the Traditional and Snacker dietary patterns, respectively, had a DDS value of 4, and 13·5 and 6·3 %, respectively, had a DDS value of 3 (data not shown). Conversely, the Health-conscious and Mediterranean dietary patterns consumed at least 30 g of dairy products, meat, cereals, fruits and vegetables over 3 d, leading to higher DDS values than the overal population; 95 and 92 % of consumers, respectively, had a DDS value of 5 (data not shown). The MAR, a composite indicator for nutrient adequacy, was higher than the mean in the overall population for individuals from the Health-conscious and Mediterranean dietary patterns, as well as for Sweet-and-processed and Basic-consumer dietary patterns. Individuals from the Health-conscious and Mediterranean patterns, who consumed higher amounts of foods with high nutritional density and low ED, such as fruits, vegetables and unprocessed fish, had also a lower ED than the overall population. ED was higher than the mean in the overall population for the Small-eater, Traditional and Snacker dietary patterns, patterns for which the MAR was significantly lower than the overall population.

Table 4 Nutrient intake and diet quality indicators of each by dietary pattern (Survey-weighted mean values and standard deviations)

Vit, vitamins; carbo, carbohydrates; pop., population; MAR, mean adequacy ratio.

* ANOVA adjusted for sex, season, level of education, wealth index, occupational status, household size, food insecurity, household composition, municipality size and region, and total energy intake (except for the variable energy), significant at P<0·05.

Nutritional intake significantly lower than the overall population; significant at P<0·05.

Nutritional intake significantly higher than the overall population.

For the ten substances considered in this study, Table 5 gives the mean exposure levels for each dietary pattern. Except for acrylamide and DON and its derivatives, the Snacker dietary pattern was significantly less exposed than the overall population for all substances studied. This result can be attributed to relatively low consumption of foods that are recognised as contributors to substance exposure. On the contrary, the Health-conscious and Mediterranean dietary patterns were more exposed than the overall population to numerous substances. For instance, these patterns showed the highest exposure level to Pb, primarily because of higher consumption of water and hot drinks. Furthermore, as a result of their higher consumption of vegetables, individuals from the Health-conscious and Mediterranean dietary patterns were more exposed to Al than the overall population. The Health-conscious dietary pattern was also more exposed to PCB-NDL, primarily because of higher consumption of fish and fish products. The Basic-consumer dietary pattern was also significantly more exposed than the overall population to Cd, because of higher consumption of bread products, and to PCB-NDL, mostly because of high consumption of butter and other dairy products. Because of their high consumption of alcohol (mainly wine), individuals belonging to the Traditional dietary pattern were more exposed to sulphites than the overall population.

Table 5 Contaminant exposure levels of each dietary pattern (Survey-weighted means and standard deviations)

bw, Body weight; TEQ, toxicity equivalent quantity.

* DON, deoxynivalenol; NDL-PCB, non-dioxin-like polychlorinated biphenyls; PCDD, polychlorinated dibenzo-p-dioxins and dibenzofurans; DL-PCB, dioxin-like polychlorinated biphenyl ANOVA adjusted for sex, season, level of education, wealth index, occupational status, household size, food insecurity, household composition, municipality size and region and total energy intake, significant at P<0·05.

Contaminant exposure level significantly higher than the overall population.

Contaminant exposure level significantly lower than the overall population; significant at P<0·05.

Discussion

This study identified seven main dietary patterns in the adult population in France, with very distinct food consumption behaviours. These patterns reflected specific nutritional intake and food contaminant exposure levels, as well as particular demographic and socio-economic determinants. According to their CS composition, these patterns were named Small eater, Health conscious, Mediterranean, Sweet and processed, Traditional, Snacker and Basic consumer. The results of this study were consistent with other studies, both national and international. Indeed, the patterns reported as reproducible in the review of Newby & Tucker( Reference Newby and Tucker 80 ) (Healthy, Western, Alcohol/Drinker, and Sweets/Dessert) are similar to some patterns we observed here. Nevertheless, although some patterns were comparable across populations (in many diverse countries and continent), there was natural variation in food consumption, which can be partly attributed to the specificity of French food culture.

First of all, two dietary patterns in particular are consistently reported in industrialised countries: one is less healthful and designated as a ‘Western-style’ pattern, and the other is more healthful and called the ‘Prudent’ pattern( Reference Hu 18 , Reference Kant 24 , Reference Wu 81 , Reference Sofianou, Fung and Tucker 82 ). First, the Western-style pattern generally features high consumption of bread, red and processed meat, starchy foods and high-fat products and is relatively similar to the patterns described as Traditional and Basic-consumer in this study. However, some disparities remained. On one hand, the Basic-consumer pattern was also characterised by a higher consumption of basic and unprocessed foods (egg, unprocessed potatoes, pulses) than the overall population with relatively high consumption of dairy products (cream, yogurt and butter), which may specifically reflect an older French model( Reference Mahe, Francou and Colin 27 , Reference Mahe, Tavoularis and Pilorin 83 ). On the other hand, high consumption of alcoholic drinks (in particular wine), observed in our Traditional dietary pattern, is not particularly noticed for the ‘Western’ diet. Other French studies have revealed an Alcohol/meat dietary pattern, but distinctive only in its amount of alcohol and meat consumed( Reference Kesse-Guyot, Bertrais and Péneau 28 , Reference Charreire, Kesse-Guyot and Bertrais 84 , Reference Bessaoud, Tretarre and Daurès 85 ). Our Traditional pattern seems to reflect at least one aspect of the French culinary culture, with its strong attachment for conviviality, and pleasure of eating( Reference Mahe, Tavoularis and Pilorin 83 , Reference Poulain 86 ). The dietary behaviours of these two ‘Western-like’ dietary patterns led to less healthy nutritional intake, with high energy and SFA intake and low vitamins and minerals intake. Individuals from these patterns were likely to have a lower socio-economic status. The results tend to support the assumption, often reported in the literature, that consumption is strongly influenced by socio-economic status and notably confirm a strong relationship between a higher consumption of energy-dense foods (such as fried products, cereals, potatoes, meat and meat products) and a lower socio-economic status( Reference Darmon and Drewnowski 87 Reference Trichopoulou, Naska and Costacou 89 ). Second, the Mediterranean and Health-conscious patterns were comparable to the ‘Prudent’ pattern, commonly identified in the literature. The name Mediterranean was chosen following the definition of a Mediterranean diet in the literature, such as a high consumption of whole grains and carbohydrates, fruits, vegetables, fish, olive oil, legumes and low to moderate amounts of saturated animal fats, red meat and wine( Reference Sofi 90 , Reference Georgoulis, Kontogianni and Yiannakouris 91 ). Effectively, our Mediterranean pattern was characterised by a high consumption of fruits, vegetables, fish and oil, of which 56 % was olive oil (against 52 % in the overall population). Moreover, the Mediterranean Diet Score proposed by Trichopoulou et al.( Reference Trichopoulou, Costacou and Bamia 92 ) has been calculated for each individual and confirmed the existence of this Mediterranean pattern among the French adult population (data not shown). Nevertheless, our Mediterranean pattern was not characterised by a high consumption of legumes and whole-grain products, as described in the literature( Reference Sofi 90 , Reference Georgoulis, Kontogianni and Yiannakouris 91 ). Similar patterns have also been identified in other French studies( Reference Kesse-Guyot, Bertrais and Péneau 28 , Reference Bertin, Touvier and Dubuisson 29 , Reference Charreire, Kesse-Guyot and Bertrais 84 ), but which were also characterised by high consumption of breakfast cereals, which was not observed in this study. The Health-conscious pattern describes individuals who ate more dietetic products. Few studies have identified a group of consumers characterised by high consumption of dietary products( Reference Hearty and Gibney 93 , Reference Ax, Warensjö Lemming and Becker 94 ). The consumption of diet products appeared long before the INCA2 study – that is in the 1980s( 95 ); thus, the identification of such a pattern was probably because of the level of aggregation of foods chosen in this study, which identified diet products separately. Consumers in both these dietary patterns seemed to have the most nutritious dietary behaviour with a nutrient-dense diet, a higher MAR and higher consumption of foods with low ED. These dietary patterns were associated with higher socio-economic status, which support the association between a higher socio-economic status and so-called healthy foods, such as wholemeal cereal-based products, fruits and vegetables or fish already identified in the literature( Reference Darmon and Drewnowski 87 , Reference Vlismas and Stavrinos 88 ).

In addition, we identified two patterns (Snacker and Sweet and processed) characterised by a high consumption of processed and modern foods (i.e. easy to prepare and to eat). Only one such pattern per study has generally been reported in the literature, either under the name of Processed/Unhealthy foods, characterised by the high consumption of high-energy beverages and savoury snacks( Reference Bertin, Touvier and Dubuisson 29 , Reference Hearty and Gibney 93 ), or Sweets( Reference Venkaiah, Brahman and Vijayaraghavan 96 Reference Newby, Muller and Hallfrisch 98 ), with a high consumption of dairy desserts and sweet products. These two profiles were both characterised by high energy intake and SFA intake. Conversely to the description of the pattern ‘Sweet foods and breakfast cereal’ identified by Hearty et al.( Reference Hearty and Gibney 93 ) among Irish adults, individuals in the Sweet-and-processed dietary pattern also had higher intake in some vitamins and minerals than the overall population, probably because of a higher consumption of fruits juices and fortified breakfast cereals. In both these dietary patterns, they were more likely to be younger, which confirms the negative association observed by Adams & White( Reference Adams and White 99 ) between age and energy from ultra-processed foods (i.e. ready-to-eat, convenient and accessible foods such as breakfast cereals, biscuits, mixed dishes, pizza, etc.).

Finally, the Small-eater dietary pattern in our study was characterised by a significantly lower consumption of all foods compared with the overall population, with lower intake of micronutrients. To our knowledge, only two studies identified a similar pattern, but these studies were performed among an elderly population( Reference Corrêa Leite, Nicolosi and Cristina 100 , Reference Schroll, Carbajal and Decarli 101 ). In our study, although no association was observed between this dietary pattern and age, individuals belonging to the Small-eater pattern had a tendency to be older (11, 17, 32, 21 and 19 % of individuals from the Small-eater pattern were 18–24, 25–34, 34–49, 50–64 and >64 years old, respectively; data not shown). Because the presence of under-reporters might have suggested potential bias, their distribution was studied. In fact, under-reporters did not represent the majority of individuals from this pattern (48 % of individuals from the Small-eater pattern were identified as under-reporters), and, consequently, those individuals who had lower energy intake than the overall population could be considered as real small consumers.

As reported in other studies, dietary patterns can highlight the specific food habits, preferences and availability of the countries(80,102). The multiplicity of dietary patterns identified in this work clearly reflects the contradictory attitudes of the French population toward food, such as health awareness, indulgence, pleasure, conviviality, but also convenience and practicality( Reference Laisney 103 , Reference Laisney 104 ). These different food consumption behaviours were also noticeable in the BMI, as defined by the World Health Organization( 5 ). For instance, profiles with ‘healthy’ food behaviour (i.e. the Health-conscious and Mediterranean patterns) had a lower proportion of individuals considered as overweight (32·8 and 29·1 %, respectively) or obese (13·0 and 10·9 %) than the more ‘unhealthy’ profiles, such as the Traditional pattern (44 % of overweight and 15·5 % of obese individuals).

One original aspect of our work was to focus, in addition to the nutritional quality of the diet, on food contaminant exposure levels of each dietary pattern. Whereas Health-conscious and Mediterranean dietary patterns seemed to have healthy dietary behaviours, these two groups of consumers seemed to be more at risk for exposure to some chemical substances. In comparison with health-based guidance values (HBGV)( 51 ), the Health-conscious pattern was considered to be at risk for its exposure to Pb, Cd, inorganic As and Al, and the Mediterranean pattern was identified to be at risk for its exposure to Pb, inorganic As, organic Hg and NDL-PCB. Conversely, the Snacker pattern had a higher ED, a lower MAR and, in comparison with recommended nutrient intake values, the highest prevalence of inadequate nutrient intake (data not shown). However, according to the HBGV, its exposure to the ten substances studied was not considered to match at-risk levels (except for acrylamide exposure). Finally, our results suggest that diets should be analysed further according to a risk:benefit ratio. Unfortunately, no comparison can be made here because, to our knowledge, to date, no other study in the literature has characterised the dietary patterns by levels of contaminant exposure.

Otherwise, this study shows that the novel factorial analysis used, the NMF, was well adapted to determining dietary patterns and successfully summarised the precise variability of food consumption in a given population. Moreover, by using an appropriate algorithm, this is the first study on this topic for which individual sampling weight was taken into account in the NMF to be representative of the French adult population( Reference Béchaux, Zetlaoui and Tressou 23 , Reference Zetlaoui, Feinberg and Verger 34 ). In contrast to PCA, for which dietary patterns are constructed based on an opposition of ‘foods consumed’ and ‘non-consumed’, the NMF constructs food behaviour patterns using only a positive association of foods, which may better reflect reality. In addition, although it is well known that food consumption is a multidimensional phenomenon, classical factorial analysis approaches mean that one dietary pattern corresponds to one common underlying dimension (factor) of food consumption( Reference Hu 18 , Reference Kesse-Guyot, Bertrais and Péneau 28 ). With NMF, one dietary pattern can be represented by different CS. Thus, as an example, consumers from the Traditional dietary pattern were characterised by foods composing the Traditional CS (processed meat, alcoholic drinks, coffee, etc.) but also the High-fat/sugar/salt CS (grains and nuts, crackers, etc.). Moreover, our study used different levels of aggregation of foods and distinguished some dietary patterns that were previously confounded in other studies and provided a better characterisation of those patterns. For instance, Bertin et al.( Reference Bertin, Touvier and Dubuisson 29 ) identified five dietary patterns named Traditional, Diversified, Processed, Prudent and Sandwiches using a PCA based on the average frequency of consumption of forty-three food groups from the INCA2 survey. According to the foods that characterised the dietary patterns, the Processed pattern was similar to the Snacker and Sweet-and-processed patterns of this study, and the Prudent pattern was similar to the Health-conscious and Mediterranean dietary patterns. Furthermore, the Processed pattern identified by Bertin et al.( Reference Bertin, Touvier and Dubuisson 29 ) differed from the overall population only by the higher consumption of sandwiches and lower consumption of other foods, whereas our Snacker dietary pattern included individuals who consumed higher quantities of several foods (sandwiches, pizza, sodas and colas, processed potato products, etc.) than the overall population. These differences further demonstrate that the NMF provides a better characterisation of the different food consumption behaviours.

Another major strength of this study was that it was based on two robust national studies. First, the INCA2 survey was conducted on a large and representative sample of the French adult population using a complex sampling frame design, with a robust collection of dietary intake using a 7-d food record, as well as numerous variables relative to demographic and socio-economic status( Reference Dubuisson, Lioret and Touvier 37 ). For the TDS2 study, a complex food sampling plan covering 90 % of the French diet was designed, taking into account the seasonal nature of products and the regional variations, leading to an accurate assessment of the population exposure at the national level( Reference Sirot, Volatier and Calamassi-Tran 50 ). In addition, the use of factorial analysis raises some concerns about the degree of subjectivity involved in the analytical process (e.g. the determination of the number of CS, the level of aggregation of foods, the determination of the number of patterns identified). However, as highlighted in Newby & Tucker( Reference Newby and Tucker 80 ), the consistency and reproducibility with regard to other national and international studies help to confirm the validity of our findings.

In conclusion, from the INCA2 survey, we identified seven distinct dietary patterns in the French adult population, with specific demographic, socio-economic, nutritional and environmental characteristics. These findings provide new information on the diversity of food consumption in France and give an overview of the nutritional quality of the different food consumption behaviours. From a public health perspective, our results provide interesting insights for developing behaviourally targeted policies. In addition, because of contradictory results for a given dietary pattern between high-quality nutritional intake and high contaminant exposure levels (and vice versa), this study also demonstrates the necessity to analyse the risks and the benefits of food consumption behaviours, particularly in a public health context. Finally, the food consumption data were collected several years ago (i.e. 2006–2007) and the third INCA survey is currently underway, potentially providing the opportunity to assess the trends in dietary patterns at the national level.

Acknowledgements

The authors wish to thank the CIQUAL for providing the national food composition tables, the Institut de Sondage Lavialle (ISL) team for the collection of data, and all the families for their cooperation.

This research received institutional support from the French agency for food, environmental and occupational health safety (ANSES).

R. G. designed the study, analysed and interpreted the data, wrote the manuscript and had primary responsibility for final content. C. B. and S. H. contributed to the analytical approach, the interpretation of the results and revised each draft. S. H., P. D.-P., C. D., V. S. and A. C. contributed to the design of the surveys (INCA2 and EAT2), to the data collection and help to write the paper.

The authors have no financial or personal conflicts of interest to declare.

Supplementary Material

For supplementary material/s referred to in this article, please visit http://dx.doi.org/10.1017/S0007114516001549

References

1. Willett, WC & Stampfer, MJ (2013) Current evidence on healthy eating. Annu Rev Public Health 34, 7795.Google Scholar
2. Martinez-Gonzalez, MA & Bes-Rastrollo, M (2014) Dietary patterns, Mediterranean diet, and cardiovascular disease. Curr Opin Lipidol 25, 2026.Google Scholar
3. de la Fuente-Arrillaga, C, Martinez-Gonzalez, M, Zazpe, I, et al. (2014) Glycemic load, glycemic index, bread and incidence of overweight/obesity in a Mediterranean cohort: the SUN project. BMC Public Health 14, 1091.Google Scholar
4. He, J (1999) Dietary sodium intake and subsequent risk of cardiovascular disease in overweight adults. JAMA 282, 2027.Google Scholar
5. World Health Organization (2015) Obesity and overweight. WHO. http://www.who.int/mediacentre/factsheets/fs311/en/ (accessed March 2015).Google Scholar
6. Reddy, KS & Katan, MB (2004) Diet nutrition and the prevention of hypertension and cardiovascular diseases. Public Health Nutr 7, 167186.Google Scholar
7. Sayon-Orea, C, Bes-Rastrollo, M, Gea, A, et al. (2014) Reported fried food consumption and the incidence of hypertension in a Mediterranean cohort: the SUN (Seguimiento Universidad de Navarra) project. Br J Nutr 112, 984991.Google Scholar
8. McCartney, DMA, Byrne, DG & Turner, MJ (2015) Dietary contributors to hypertension in adults reviewed. Ir J Med Sci 184, 8190.Google Scholar
9. de Oliveira Otto, MC, Mozaffarian, D, Kromhout, D, et al. (2012) Dietary intake of saturated fat by food source and incident cardiovascular disease: the Multi-Ethnic Study of Atherosclerosis. Am J Clin Nutr 96, 397404.CrossRefGoogle ScholarPubMed
10. Lee, D-H, Folsom, AR & Jacobs, DR (2005) Iron, zinc, and alcohol consumption and mortality from cardiovascular diseases: the Iowa Women’s Health Study. Am J Clin Nutr 81, 787791.CrossRefGoogle ScholarPubMed
11. Mente, A, de Koning, L, Shannon, HS, et al. (2009) A systematic review of the evidence supporting a causal link between dietary factors and coronary heart disease. Arch Intern Med 169, 659.Google Scholar
12. Liu, J & Ma, DWL (2014) The role of n-3 polyunsaturated fatty acids in the prevention and treatment of breast cancer. Nutrients 6, 51845223.CrossRefGoogle ScholarPubMed
13. Wang, Q, Hao, J, Guan, Q, et al. (2014) The Mediterranean diet and gastrointestinal cancers risk. Recent Pat Food Nutr Agric 6, 2326.CrossRefGoogle ScholarPubMed
14. Glade, MJ (1999) Food, nutrition, and the prevention of cancer: a global perspective. American Institute for Cancer Research/World Cancer Research Fund, American Institute for Cancer Research, 1997. Nutrition 15, 523526.Google Scholar
15. Jacobs, DR & Tapsell, LC (2007) Food, not nutrients, is the fundamental unit in nutrition. Nutr Rev 65, 439450.Google Scholar
16. Gerber, M (2001) The comprehensive approach to diet: a critical review. J Nutr 131, 3051S3055S.CrossRefGoogle ScholarPubMed
17. Jacobs, DR & Steffen, LM (2003) Nutrients, foods, and dietary patterns as exposures in research: a framework for food synergy. Am J Clin Nutr 78, 508S513S.Google Scholar
18. Hu, FB (2002) Dietary pattern analysis: a new direction in nutritional epidemiology. Curr Opin Lipidol 13, 39.Google Scholar
19. Michels, KB & Schulze, MB (2005) Can dietary patterns help us detect diet–disease associations? Nutr Res Rev 18, 241.CrossRefGoogle ScholarPubMed
20. Moeller, SM, Reedy, J, Millen, AE, et al. (2007) Dietary patterns: challenges and opportunities in dietary patterns research. J Am Diet Assoc 107, 12331239.CrossRefGoogle ScholarPubMed
21. Nutrition Evidence Library (2014) A Series of Systematic Reviews on the Relationship Between Dietary Patterns and Health Outcomes. Alexandria, VA: Department of Agriculture, Center for Nutrition Policy and Promotion.Google Scholar
22. Tucker, KL (2010) Dietary patterns, approaches, and multicultural perspective. This is one of a selection of papers published in the CSCN–CSNS 2009 Conference, entitled Can we identify culture-specific healthful dietary patterns among diverse populations undergoing nutrition transition? Appl Physiol Nutr Metab 35, 211218.CrossRefGoogle Scholar
23. Béchaux, C, Zetlaoui, M, Tressou, J, et al. (2013) Identification of pesticide mixtures and connection between combined exposure and diet. Food Chem Toxicol 59, 191198.Google Scholar
24. Kant, AK (2004) Dietary patterns and health outcomes. J Am Diet Assoc 104, 615635.CrossRefGoogle ScholarPubMed
25. Schulze, MB & Hoffmann, K (2006) Methodological approaches to study dietary patterns in relation to risk of coronary heart disease and stroke. Br J Nutr 95, 860869.CrossRefGoogle ScholarPubMed
26. Wirfält, E, Drake, I & Wallström, P (2013) What do review papers conclude about food and dietary patterns? Food Nutr Res 57, 10.3402/fnr.v57i0.20523.Google Scholar
27. Mahe, T, Francou, A, Colin, J, et al. (2011) Comparaison des modèles alimentaires Français et Etat-uniens (Comparison of French and American Diet Models). Crédoc. Cahier de Recherche no. 283. Paris: Crédoc.Google Scholar
28. Kesse-Guyot, E, Bertrais, S, Péneau, S, et al. (2009) Dietary patterns and their sociodemographic and behavioural correlates in French middle-aged adults from the SU.VI.MAX cohort. Eur J Clin Nutr 63, 521528.Google Scholar
29. Bertin, M, Touvier, M, Dubuisson, C, et al. (2015) Dietary patterns of French adults: associations with demographic, socio-economic and behavioural factors. J Hum Nutr Diet 29, 241254.CrossRefGoogle Scholar
30. Escalon, H, Bossard, C & Beck, F (2009) Typologie des mangeurs (Typology of eaters). In Baromètre Santé Nutrition 2008 (Health and Nutrition Barometer 2008), pp. 305325 [H Escalon, C Bossard and F Beck, editors]. Saint-Denis: INPES.Google Scholar
31. Kipnis, V, Midthune, D, Buckman, DW, et al. (2009) Modeling data with excess zeros and measurement error: application to evaluating relationships between episodically consumed foods and health outcomes. Biometrics 65, 10031010.CrossRefGoogle ScholarPubMed
32. Shlens, J (2014) A tutorial on principal component analysis. Int J Remote Sensing 51, 112.Google Scholar
33. Lee, DD & Seung, HS (1999) Learning the parts of objects by non-negative matrix factorization. Nature 401, 788791.Google Scholar
34. Zetlaoui, M, Feinberg, M, Verger, P, et al. (2011) Extraction of food consumption systems by nonnegative matrix factorization (NMF) for the assessment of food choices. Biometrics 67, 16471658.Google Scholar
35. Sy, MM, Feinberg, M, Verger, P, et al. (2013) New approach for the assessment of cluster diets. Food Chem Toxicol 52, 180187.Google Scholar
36. Agence française de sécurité sanitaire, alimentation, environnement, travail (ANSES) (2009) INCA2 (2006–2007). Report of the Individual and the National Study on Food Consumption no. 199. Maisons-Alfort: French Food Safety Agency (AFSSA).Google Scholar
37. Dubuisson, C, Lioret, S, Touvier, M, et al. (2010) Trends in food and nutritional intakes of French adults from 1999 to 2007: results from the INCA surveys. Br J Nutr 103, 10351048.Google Scholar
38. Lioret, S, Touvier, M, Dubuisson, C, et al. (2009) Trends in child overweight rates and energy intake in france from 1999 to 2007: relationships with socioeconomic status. Obesity 17, 10921100.Google Scholar
39. French National Institute of Statistics and of Economic Studies (INSEE) (2007) Enquête emploi de 2005 (Employment Survey 2005). Insee Résultats 68, 14.Google Scholar
40. European Food Safety Authority (2009) General principles for the collection of national food consumption data in the view of a pan-European dietary survey. EFSA J 7, 51.Google Scholar
41. Lioret, S, Dubuisson, C, Touvier, M, et al. (2010) Trends in food and nutritional intakes of French adults from 1999 to 2007: results from the INCA surveys. Br J Nutr 103, 10351048.Google Scholar
42. Hercberg, S, Deheeger, M & Preziosi, P (editors) (1994) Portions alimentaires: manuel-photos pour l’estimation des quantités (Portion Sizes: Picture Booklet for the Estimation of Quantities). Paris: Polytechnica.Google Scholar
43. McCann, SE, Marshall, JR, Brasure, JR, et al. (2001) Analysis of patterns of food intake in nutritional epidemiology: food classification in principal components analysis and the subsequent impact on estimates for endometrial cancer. Public Health Nutr 4, 989997.Google Scholar
44. Bailey, RL, Gutschall, MD, Mitchell, DC, et al. (2006) Comparative strategies for using cluster analysis to assess dietary patterns. J Am Diet Assoc 106, 11941200.CrossRefGoogle ScholarPubMed
45. Grieger, JA, Scott, J & Cobiac, L (2011) Dietary patterns and breast-feeding in Australian children. Public Health Nutr 14, 19391947.CrossRefGoogle ScholarPubMed
46. Fillol, F, Dubuisson, C, Lafay, L, et al. (2011) Accounting for the multidimensional nature of the relationship between adult obesity and socio-economic status: the French second National Individual Survey on Food Consumption (INCA 2) dietary survey (2006–2007). Br J Nutr 106, 16021608.Google Scholar
47. Darmon, N, Bocquier, A, Vieux, F, et al. (2009) L’insécurité alimentaire pour raisons financières en France (Food insecurity for financial reasons in France). In Trav. L’Observatoire Natl. Pauvr. L’Exclusion Soc., pp. 583602 [La documentation Française, editor]. Yvry: INRA.Google Scholar
48. Feinberg, M, Favier, J-C & Laussucq, C (1995) Répertoire général des aliments (General Inventory of Foods). Paris: Institut national de la recherche agronomique: Technique & Documentation – Lavoisier.Google Scholar
49. Ireland J, du Chaffaut L, Oseredczuk M, et al. (2008) French Food Composition Table, version 2008.1. French Food Safety Agency (Afssa). http://www.afssa.fr/TableCIQUAL/index.html (accessed February 2014).Google Scholar
50. Sirot, V, Volatier, JL, Calamassi-Tran, G, et al. (2009) Core food of the French food supply: second Total Diet Study. Food Addit Contam Part Chem Anal Control Expo Risk Assess 26, 623639.CrossRefGoogle ScholarPubMed
51. French Agency for Food, Environmental and Occupational Health & Safety (ANSES) (2011) Second French Total Diet Study, TDS 2. Report 1-Inorganic Contaminants, Minerals, Persistent Organic Pollutants, Mycotoxins and Phytoestrogens. Maisons-Alfort: ANSES.Google Scholar
52. French Agency for Food, Environmental and Occupational Health & Safety (ANSES) (2011) Second French Total Diet Study, TDS 2. Report 2 – Pesticide Residues, Additives, Acrylamide and Polycyclic Aromatic Hydrocarbons. Maisons-Alfort: ANSES.Google Scholar
53. Wang, G, Kossenkov, AV & Ochs, MF (2006) LS-NMF: a modified non-negative matrix factorization algorithm utilizing uncertainty estimates. BMC Bioinformatics 7, 175185.CrossRefGoogle ScholarPubMed
54. Kaufman, L (2005) Finding Groups in Data: An Introduction to Cluster Analysis. Hoboken, NJ: Wiley.Google Scholar
55. , S, Josse, J & Husson, F (2008) FactoMineR: an R package for multivariate analysis. J Stat Softw 25, 118.Google Scholar
56. Lebart, L, Morineau, A & Piron, M (1997) Statistique Exploratoire Multidimensionnelle (Multidimensional and Exploratory Statistics), 2nd ed., pp. 1–480. Paris: Dunod.Google Scholar
57. Novaković, R, Cavelaars, A, Geelen, A, et al. (2014) Review article socio-economic determinants of micronutrient intake and status in Europe: a systematic review. Public Health Nutr 17, 10311045.Google Scholar
58. Bocquier, A, Vieux, F, Lioret, S, et al. (2015) Socio-economic characteristics, living conditions and diet quality are associated with food insecurity in France. Public Health Nutr 7, 110.Google Scholar
59. Hanna, KL & Collins, PF (2015) Relationship between living alone and food and nutrient intake. Nutr Rev 73, 594611.Google Scholar
60. Wang, Y-M, Mo, B-Q, Takezaki, T, et al. (2003) Geographical variation in nutrient intake between urban and rural areas of Jiangsu province, China and development of a semi-quantitative food frequency questionnaire for middle-aged inhabitants. J Epidemiol 13, 8089.Google Scholar
61. Cappuccio, FP, Ji, C, Donfrancesco, C, et al. (2015) Geographic and socioeconomic variation of sodium and potassium intake in Italy: results from the MINISAL-GIRCSI programme. BMJ Open 5, e007467.Google Scholar
62. Wirt, A & Collins, CE (2009) Diet quality – what is it and does it matter? Public Health Nutr 12, 2473.Google Scholar
63. Alkerwi, A (2014) Diet quality concept. Nutrition 30, 613618.Google Scholar
64. Kant, AK & Graubard, BI (2005) Energy density of diets reported by American adults: association with food group intake, nutrient intake, and body weight. Int J Obes 29, 950956.CrossRefGoogle ScholarPubMed
65. Vieux, F, Soler, L-G, Touazi, D, et al. (2013) High nutritional quality is not associated with low greenhouse gas emissions in self-selected diets of French adults. Am J Clin Nutr 97, 569583.CrossRefGoogle Scholar
66. Kant, AK (1996) Indexes of overall diet quality: a review. J Am Diet Assoc 96, 785791.Google Scholar
67. Ledikwe, JH, Blanck, HM, Khan, LK, et al. (2006) Low-energy-density diets are associated with high diet quality in adults in the United States. J Am Diet Assoc 106, 11721180.Google Scholar
68. American Institute for Cancer Research & World Cancer Research Fund (2007) Food, Nutrition, Physical Activity and the Prevention of Cancer: A Global Perspective: A Project of World Cancer Research Fund International. Washington, DC: American Institute for Cancer Research.Google Scholar
69. Swinburn, BA, Caterson, I, Seidell, JC, et al. (2004) Diet, nutrition and the prevention of excess weight gain and obesity. Public Health Nutr 7, 123146.Google Scholar
70. Keller, HH, Ostbye, T & Bright-See, E (1997) Predictors of dietary intake in Ontario seniors. Can J Public Health 88, 305309.Google Scholar
71. Krebs-Smith, SM, Smiciklas-Wright, H, Guthrie, HA, et al. (1987) The effects of variety in food choices on dietary quality. J Am Diet Assoc 87, 897903.CrossRefGoogle ScholarPubMed
72. Maillot, M, Darmon, N, Vieux, F, et al. (2007) Low energy density and high nutritional quality are each associated with higher diet costs in French adults. Am J Clin Nutr 86, 690696.Google ScholarPubMed
73. Torheim, LE, Ouattara, F, Diarra, MM, et al. (2004) Nutrient adequacy and dietary diversity in rural Mali: association and determinants. Eur J Clin Nutr 58, 594604.Google Scholar
74. Ruel, MT (2003) Operationalizing dietary diversity: a review of measurement issues and research priorities. J Nutr 133, 3911S3926S.CrossRefGoogle ScholarPubMed
75. Lucenteforte, E, Garavello, W, Bosetti, C, et al. (2008) Diet diversity and the risk of squamous cell esophageal cancer. Int J Cancer 123, 23972400.Google Scholar
76. Garavello, W, Giordano, L, Bosetti, C, et al. (2008) Diet diversity and the risk of oral and pharyngeal cancer. Eur J Nutr 47, 280284.Google Scholar
77. Drewnowski, A, Henderson, SA, Shore, A, et al. (1996) Diet quality and dietary diversity in France implications for the French paradox. J Am Diet Assoc 96, 663669.CrossRefGoogle ScholarPubMed
78. Gaujoux, R & Seoighe, C (2010) A flexible R package for nonnegative matrix factorization. BMC Bioinformatics 11, 367.Google Scholar
79. Lumley, T (2015) Analysis of complex survey samples. J Stat Softw 9, 1–19.Google Scholar
80. Newby, PK & Tucker, KL (2004) Empirically derived eating patterns using factor or cluster analysis: a review. Nutr Rev 62, 177203.Google Scholar
81. Wu, K (2006) Dietary patterns and risk of prostate cancer in US men. Cancer Epidemiol Biomarkers Prev 15, 167171.Google Scholar
82. Sofianou, A, Fung, TT & Tucker, KL (2011) Differences in diet pattern adherence by nativity and duration of US residence in the Mexican-American population. J Am Diet Assoc 111, 15631569.e2.CrossRefGoogle ScholarPubMed
83. Mahe, T, Tavoularis, G & Pilorin, T (2009) La Gastronomie s’inscrit dans la continuité du modèle alimentaire Français. Crédoc. Cahier de Recherche no. 267. Paris: Crédoc.Google Scholar
84. Charreire, H, Kesse-Guyot, E, Bertrais, S, et al. (2011) Associations between dietary patterns, physical activity (leisure-time and occupational) and television viewing in middle-aged French adults. Br J Nutr 105, 902910.Google Scholar
85. Bessaoud, F, Tretarre, B, Daurès, J-P, et al. (2012) Identification of dietary patterns using two statistical approaches and their association with breast cancer risk: a case-control study in southern France. Ann Epidemiol 22, 499510.Google Scholar
86. Poulain, J-P (2001) Manger aujourd’hui attitudes, normes et pratiques (Eat Today: Norms, Attitudes, Usages). Toulouse: Privat.Google Scholar
87. Darmon, N & Drewnowski, A (2008) Does social class predict diet quality? Am J Clin Nutr 87, 11071117.Google Scholar
88. Vlismas, K & Stavrinos, V (2009) Socio-economic status, dietary habits and health-related outcomes in various parts of the world: a review. Cent Eur J Public Health 17, 5563.Google Scholar
89. Trichopoulou, A, Naska, A & Costacou, T (2002) Disparities in food habits across Europe. Proc Nutr Soc 61, 553558.Google Scholar
90. Sofi, F (2009) The Mediterranean diet revisited: evidence of its effectiveness grows. Curr Opin Cardiol 24, 442446.CrossRefGoogle ScholarPubMed
91. Georgoulis, M, Kontogianni, M & Yiannakouris, N (2014) Mediterranean Diet and diabetes: prevention and treatment. Nutrients 6, 14061423.Google Scholar
92. Trichopoulou, A, Costacou, T, Bamia, C, et al. (2003) Adherence to a Mediterranean diet and survival in a Greek population. N Engl J Med 348, 25992608.Google Scholar
93. Hearty, ÁP & Gibney, MJ (2009) Comparison of cluster and principal component analysis techniques to derive dietary patterns in Irish adults. Br J Nutr 101, 590.Google Scholar
94. Ax, E, Warensjö Lemming, E, Becker, W, et al. (2016) Dietary patterns in Swedish adults; results from a national dietary survey. Br J Nutr 115, 95104.Google Scholar
95. Institut national de prévention et d’éducation pour la santé (France) (2008) Baromètre santé environnement 2007 (Health, Nutrition and Environment Barometer 2007). Saint-Denis: Éd. INPES.Google Scholar
96. Venkaiah, K, Brahman, GNV & Vijayaraghavan, K (2011) Application of factor analysis to identify dietary patterns and use of factor scores to study their relationship with nutritional status of adult rural populations. J Health Popul Nutr 29, 327338.Google Scholar
97. Lin, H, Bermudez, OI & Tucker, KL (2003) Dietary patterns of Hispanic elders are associated with acculturation and obesity. J Nutr 133, 36513657.Google Scholar
98. Newby, PK, Muller, D, Hallfrisch, J, et al. (2004) Food patterns measured by factor analysis and anthropometric changes in adults. Am J Clin Nutr 80, 504513.Google Scholar
99. Adams, J & White, M (2015) Characterisation of UK diets according to degree of food processing and associations with socio-demographics and obesity: cross-sectional analysis of UK National Diet and Nutrition Survey (2008–2012). Int J Behav Nutr Phys Act 12, 160172.Google Scholar
100. Corrêa Leite, ML, Nicolosi, A, Cristina, S, et al. (2003) Dietary and nutritional patterns in an elderly rural population in Northern and Southern Italy: (I). A cluster analysis of food consumption. Eur J Clin Nutr 57, 15141521.Google Scholar
101. Schroll, K, Carbajal, A, Decarli, B, et al. (1996) Food patterns of elderly Europeans. SENECA investigators. Eur J Clin Nutr 50, Suppl. 2, S86S100.Google Scholar
102. Engeset, D, Hofoss, D, Nilsson, LM, et al. (2015) Dietary patterns and whole grain cereals in the Scandinavian countries – differences and similarities. The HELGA project. Public Health Nutr 18, 905915.Google Scholar
103. Laisney, C (2011) L’évolution de l’alimentation en France. Panorama des tendances lourdes (Evolution of the diet in France. Overview of the major trends). Futuribles 371, 18.Google Scholar
104. Laisney, C (2011) L’évolution de l’alimentation en France. Tendances émergentes et ruptures possibles (Evolution of the diet in France. Emerging trends and possible breakdowns). Futuribles 372, 14.Google Scholar
Figure 0

Table 1 Nomenclature (food groups and consumption rate among the 2600 individuals)

Figure 1

Table 2 Food consumption characteristics of each dietary pattern

Figure 2

Table 3 Demographic and socio-economic determinants of each dietary pattern by sex (Odds ratios and 95 % confidence intervals)

Figure 3

Table 4 Nutrient intake and diet quality indicators of each by dietary pattern (Survey-weighted mean values and standard deviations)

Figure 4

Table 5 Contaminant exposure levels of each dietary pattern (Survey-weighted means and standard deviations)

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