Relation of Minimally Processed Foods and Ultra-Processed Foods with the Mediterranean Diet Score, Time-Related Meal Patterns and Waist Circumference: Results from a Cross-Sectional Study in University Students

Ultra-processed foods (UPF) are defined as ready-to-eat, or ready-to-heat products, deriving from industrial procedures [1]. Examples of UPF are cereal bars, savory snacks, processed meats, pre-packaged frozen dishes, soft drinks, sweetened drinks, “instant” soups and sauces, etc. [1]. According to the degree of the procession, the NOVA food system classifies foods into four categories: category 1—unprocessed or minimally processed foods (MPF), category 2—processed culinary ingredients, category 3—processed foods (PF), and category 4—UPF [1]. Examples of foods belonging to NOVA categories 1–4 are the following: NOVA category 1 MPF: fruits, vegetables, nuts, eggs, etc.; NOVA category 2—processed culinary ingredients: olive oil, sugar, honey, butter; NOVA category 3—PF: tomato paste, freshly-made cheeses, canned fish, etc. NOVA category 4—UPF: fast foods, soft drinks, processed breads, biscuits, breakfast cereals and bars, sweetened yogurts, etc. Food processing affects food availability and food quality in a positive and negative way [2]. For example, several borne deriving diseases, such as hepatitis A or high microbial load, have been described for minimally processed foods (MPF) [3,4]. On the contrary, several health problems have also been attributed to UPF consumption [5], possibly related to their worse nutritional quality [6].

There is increasing evidence, according to meta-analyses, that the consumption of specific UPF, such as processed meat and beverages high in sugar, increases the risk of cardiovascular disease (CVD) [7], and mortality in cardiovascular patients [8]. The recent statement of the American Heart Association underlines that unprocessed forms of meat and poultry should be chosen and that MPF should be preferred over UPF to improve cardiovascular health [9]. Moreover, UPF consumption is related to CVD risk factors such as obesity, high blood pressure, and metabolic syndrome in epidemiologic studies [10,11,12]. Concerning obesity, many studies are reporting a positive relationship between UPF consumption and adiposity indices with a cross-sectional or longitudinal design [11,12,13,14,15], while there is only one clinical trial supporting the same hypothesis [16]. UPF are high in energy and saturated fat and they are palatable and convenient, which may, in part, explain their association with obesity [6].

This unique profile of UPF may also make them “attractive” food choices for university students for many reasons: new exposures, social circuits, food insecurity, poor cooking skills, migration, product characteristics, and an energy dense option if a main meal is skipped during classes and tight schedules [6,17,18,19,20,21,22,23]. Dietary habits can affect adiposity in university students [24]. More particularly, the embracement of healthy nutritional schemes, such as the Mediterranean diet [25,26,27], as well as meal characteristics, such as frequency, eating main meals, and breakfast [20,24,28,29], have been negatively associated with obesity in university students. Gender differences have also been described, with female students choosing more fruits, less fat and eating breakfast more frequently [30,31,32,33]. Data from epidemiological studies have shown that UPF consumption is related to younger age, male sex and obesity [34]. However, few studies have assessed the consumption of UPF in university students specifically [23,33,35,36,37], and even fewer their health-associated effects in this subgroup [36,37,38].

We have previously shown that dietary quality scores, such as the Food Compass Score, which includes NOVA categorization in its calculation, are associated with better nutritional habits and an “early eating” pattern in university students [39]. Moreover, a pattern high in fast foods and sweets, which are considered UPF, has been associated with a higher probability of overweight and obesity as well as a higher WC in men of the same cohort [24].

To our knowledge, there is no study investigating the levels of UPF consumption and specific UPF foods in Greek adults categorized with the NOVA system. Moreover, there are scarce data on the relation of UPF and health correlates of UPF in young adults [36,37,38] as well as chrononutrition, as expressed by meal/snack timing of intake [40]. Therefore, the rational of this study was to shed light in the UPF consumption in Greece, and its potential relation to adiposity and chronotype. More specifically, the present work aimed to assess the extent of UPF intake and investigate the relation of UPF and MPF consumption with adiposity and early/late meal patterns in a sample of Greek university students.

The rational of this study was to shed light on the UPF consumption in Greece, specific foods contributing to UPF intake and the potential relation of UPF to chronotype and health correlates, such as adiposity. The present study documented a positive association of UPF consumption with central adiposity in male university students, while there was no relation of UPF to BMI. Moreover, UPF consumption was negatively associated with adherence to the Mediterranean diet and an “early eating” pattern, and positively associated with a “late eating” pattern. MPF consumption was positively associated with Mediterranean diet adherence and an “early eating” pattern.

The present study adds to the existing literature, since few studies have addressed UPF consumption in young adults, such as university students [23,33,35,36,37] and even fewer have tested the effects of UPF consumption on health in this subgroup [36,37,38]. Moreover, there is no other study in a young adult Greek population assessing UPF consumption. Previous studies in Greece were performed on parents and showed that 32% of participants had a high intake of UPF [47], which is not directly comparable to our results, which are expressed as % of energy. Moreover, UPF provided 25.2% of total calories in a Greek menu for hospitalized subjects [48]. UPF provided 40.7 ± 13.6% of total energy in the present study. This is higher than other Mediterranean countries, such as Spain (24%) [49] and Italy (10%) [8], comparable to other countries such as France (36%) [34] and Australia (42%) [50], and lower than values reported for Britain (56.8%) [51], or the USA (58%) [52].

As recently reviewed, there are nine cross-sectional studies and seven longitudinal studies showing a positive association between UPF consumption and obesity [12]. The relation of UPF intake to obesity and/or central obesity can be explained by the fact that UPF constitute highly palatable, energy-dense food choices, which usually have higher sugar, sodium, and saturated fat content [6]. Moreover, UPF intake is related to increased sugar and decreased fiber consumption, as well as an increased eating rate, all of which constitute obesogenic factors [12,16]. They can also promote higher glucose peaks and decreased satiety compared to MPF [53]. In addition to nutrient-related mechanisms, UPF may have contaminants from food packaging, such as bisphenol-A (BPA) and phthalates, which have been linked to obesity [54,55]. Several additives used in UPF production, such as sodium benzoate, and monosodium glutamate, may also be obesogenic [55,56].

In the present study, UPF consumption was positively related to WC but not to BMI. Most available studies have assessed only BMI or the probability of being overweight and obese [12], while some have assessed WC and/or abdominal obesity [11,57,58,59]. It is of additive value that all prospective studies have shown a consistent increase in central adiposity with UPF consumption over time [60,61], a finding which is in the same direction with our results. However, it is noted that a positive relation of UPF consumption to both BMI and WC was observed in these studies [11,13,58], while in the study of Rauber et al. UPF consumption was positively related to odds of obesity but not to odds of abdominal obesity [51]. The apparent discrepancy of the above observations and our results may be explained by the relatively small sample size in our study and the population characteristics (such as younger age, Mediterranean population). Moreover, BMI is not as a good of a marker of adiposity as WC, since it may be increased in cases of individuals with increased muscle mass [62]. This phenomenon may be more prevalent in younger ages, since muscle mass is usually higher [62]. The inflammation-related correlations of BMI and abdominal fat may be also differentiated, as we have previously shown [63,64]. Interestingly, ultra-processed beverages have been related to increased values of WC, suggesting that additives, syrups and oligosaccharides, found in ultra-processed beverages can lead to insulin resistance and hormonal disturbances, relating to central and visceral adiposity [65,66].

There is only one clinical trial to investigate the causal role of UPF consumption in adiposity. In that randomized cross-over controlled trial in 20 weight-stable adults, the consumption of UPF for two weeks was related to an increased energy intake by ~500 kcal/day and weight gain of ~1 kg in the same time period [16]. Moreover, the study showed a reduction in ghrelin secretion, an increase in the satiety hormone PYY and a reduction in inflammatory markers with the unprocessed diet [16]. However, WC was not measured in this well-controlled study [16].

There are few studies examining sex differentiations in the relation of UPF consumption to obesity relationship, which show that the relationship is mostly apparent in women [57,58]. This is in contrast with our findings, since the UPF-central adiposity relation was documented in men in the present study and no relation was documented between UPF consumption and BMI. The observed discrepancy between our and the aforementioned studies is not related to the absolute intake of UPF, since the reported intake of UPF in the study of Pestoni et al. was 26% [57], in the study of Sung et al. was 57.5% [58] and in our study in between. However, the particularity of the Mediterranean population in the present study may in part explain the observed differences. For example, a recent study in Spanish students has shown that men had higher UPF consumption, and especially higher consumption of energy drinks, alcohol, and cereal bars, which could explain a possible association with obesity [35]. In the present study, men had a higher consumption of processed beverages, ultra-processed meats, sauces/condiments and fast foods/pizza, as portions/day and/or % energy, while women had a higher consumption of processed cereals/bars and sweets (% energy). Further studies are needed to clarify potential sex-differentiations in this diet-health hypothesis.

The inverse association of UPF consumption with Mediterranean diet adherence has been documented in the literature [67,68,69]. This association is in line with our findings and can be explained as a nutritional “shift” from fresh traditional Mediterranean meals to UPF, i.e., easy, ready-to-eat meals and beverages. It is noteworthy that the present study also found a relation of UPF consumption to a “late eating” pattern, which provides a sociological context for UPF consumption and a possible additional explanation of their association with obesity. Indeed, it seems that the participants who had a higher intake of UPF most commonly consumed snacks late. There are scarce data on the relation of UPF and chrononutrition, as expressed by meal/snack timing of intake [40]. A recent study found that subjects having an “early eating” (“morning”) pattern reported lower consumption of sweets, sweeteners, ultra-processed fats and seasonings [40]. Late meals have been associated with lower basal energy expenditure and obesity, as recently reviewed [70], underlying the emerging role of chrono-nutrition [70]. Mistimed eating can also result in hormonal dysregulation, such as leptin, cortisol, adiponectin, pro-opiomelanocortin, gastric inhibitory polypeptide and others, which can, in turn, promote weight gain [71]. Interestingly, the consumption of UPF has also been related to cancer [72] and cardiovascular risk factors [10], which are both related to obesity [73,74].

The strengths of our study include the assessment of UPF consumption in a Greek population not previously reported, as well as adjustment for underreporting. The following limitations should be taken into account. The cross-sectional design of our study cannot prove causality. Moreover, the generalizability of the presented results may be limited since university students in Peloponnese were included. The subgroup of men studied was relatively small. However, the achieved power with post-hoc power analysis taking into account the partial R² corresponding to the explanatory ability of UPF consumption on 1/WC in men (R² change = 0.152) was 97.3%. The clinical significance of our finding should be considered, since the beta coefficients in our model were relatively small. This, in part, may be explained by the multi-factorial nature of the measured dependent variables, i.e., WC and/or BMI. Moreover, most correlation coefficients between UPF, MPF consumption, MedDietScore and early/late eating meal patterns were <0.3, suggesting weak associations. A recent study has also reported a relatively low coefficient of association regarding Mediterranean diet score and UPF (rho = −0.35; p = 0.001) [67]. The magnitude of associations of dietary variables with early/late eating meal patterns is also in line with previous results from our group [24,39]. Several errors may be present in dietary assessment since an FFQ was used. However, we have partially accounted for potential estimation errors, since underreporting was considered in statistical analysis. The financial status of students, as well as their exact living conditions (alone, with roommates or family) were not assessed in the present study and these variables may affect UPF intake. Regarding the NOVA food classification system there is a debate about its usefulness since some argue that it has “little additive value” over nutrient values [75]. In contrast, others underline that ultra-processed foods also have a different physical structure [5]. Moreover, it is not always clear if some food products are UPF or not. For example, industrial bread made from simple materials such as wheat flour, water, salt and yeast, is a processed food, while if it contains emulsifiers or colors is UPF. These differentiations cannot be easily captured in nutritional epidemiology. Regarding meals, there is no consensus about the definition of snacks or meals [76]. Moreover, no information on the content/quality of meals consumed were available. Finally, data for energy expenditure were not available from the participants, which could potentially impact on our findings.

In conclusion, the present study confirmed a high UPF consumption among Greek university students, and provided the first evidence regarding UPF consumption in young Greek adults. The results of the present work showed that UPF consumption was positively related to WC in male university students. Nutritional and sociodemographic correlates of UPF consumption, such as low Mediterranean diet adherence and having a “late eating” pattern serve as a basis to better understand the UPF consumption-central obesity relation in young adults and should be considered in nutrition education programs when targeting reductions in UPF consumption to lower centripetal adiposity, associated with increased cardiometabolic risk.