Hostname: page-component-586b7cd67f-dlnhk Total loading time: 0 Render date: 2024-11-24T06:24:28.744Z Has data issue: false hasContentIssue false

Mediterranean diet scoring systems: understanding the evolution and applications for Mediterranean and non-Mediterranean countries

Published online by Cambridge University Press:  22 July 2021

Heather L. Hutchins-Wiese*
Affiliation:
Eastern Michigan University, School of Health Science, 313 Marshall Building, Ypsilanti, MI 48197, USA
Connie W. Bales
Affiliation:
Duke University Medical Center, Department of Medicine, Durham, USA Durham VA Health Care System, Durham, USA
Kathryn N. Porter Starr
Affiliation:
Duke University Medical Center, Department of Medicine, Durham, USA Durham VA Health Care System, Durham, USA
*
*Corresponding author: Heather L. Hutchins-Wiese, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The Mediterranean diet (MedD) is a flexible dietary pattern which has such variability that has led to inconsistencies in definitions and assessment. The purpose of this narrative review is to evaluate scoring systems in a cultural and geographic context, from Mediterranean and non-Mediterranean countries, for comparison and application. The early MedD scoring systems (i.e. Trichopoulou’s MedD Scale (T-MDS) and alternative MedD Scale (aMed)) are widely applied throughout the world but use population-specific median cut-offs which limit interpretation and cross-study comparisons. The T-MDS and aMed also do not account for non-traditional MedD foods which are consumed in greater quantities than when the scoring systems were developed. Scoring systems developed after the MedD pyramid publication in 2011 have generally used these recommendations as a basis for food group intake cut-offs, incorporating more foods/food groups as negative components, and some have included dietary and lifestyle behaviours. The different approaches to MedD assessment have created much variability in the foods/food group components included in scoring systems. Assessments that include dietary and lifestyle behaviours may reflect the nutrition transition occurring in Mediterranean countries and better guide clinical intervention approaches. While the new scoring systems are theorised to better capture MedD adherence and behaviours, comparisons are sparse in the literature and none exists outside of Europe. Consensus on food and dietary behaviours to include as well as the methodology for assigning points in MedD scoring systems is needed to advance our understanding of MedD and health relationships to promote public health messaging and clinical application.

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

Epidemiological studies have provided us with a broader understanding of the relationship between diet and disease states, but this understanding is shaped by the inherent limitations of dietary assessment tools applied to a given study population. The study of the Mediterranean diet (MedD) is an a priori approach to diet pattern analysis as it includes elements of a dietary pattern with available evidence(Reference Schulze and Hu1). This approach is important when considering the wide application of the MedD, the multiple tools for assessing adherence and the potential health benefits.

The potential cardiovascular health benefits of consuming a MedD were first brought to the attention of the world by Ansel Keys(Reference Keys, Aravanis and Blackburn2). Since then, additional health benefits have emerged including reduced overall mortality as well as reduced risk of some cancers, neurodegenerative diseases and diabetes(Reference Dinu, Pagliai and Casini3). While there is no single MedD, the traditional dietary pattern is characterised by intake of foods from the olive-growing region of the Mediterranean basin observed up till the 1960s with emphasis on a high intake of vegetables, cereals, fruits, olive oil, legumes, fish, moderate intake of wine, with limited red and processed meats and processed sweets(Reference Trichopoulou, Martínez-González and Tong4). Olive oil and lipid ratios that reflect a primarily plant-based diet with moderate wine consumption are hallmarks of the traditional MedD. The broad definition and lack of specific terms(Reference Davis, Bryan and Hodgson5) to define the MedD, i.e. nutrients rather than food groups, or specific Mediterranean foods within the food groups, make it difficult to identify and quantify the MedD. However, the MedD pyramids help with defining the diet and have evolved over the last 25 years(Reference Bach-Faig, Berry and Lairon6Reference Willett, Sacks and Trichopoulou10). The MedD pyramid evolution reflects the nutritional transitions that have occurred in the Mediterranean region and variabilities that allow for application to other cultures and traditions. The most recently published and applied MedD pyramids were developed by an International group of MedD researchers, the International Foundation of MedD(Reference Bach-Faig, Berry and Lairon6,Reference Serra-Majem, Tomaino and Dernini9,Reference Dernini, Berry and Serra-Majem11) .

Lifestyle is also emphasised in the MedD. This is fitting, since the origin of the word ‘diet’ is the Greek concept of ‘diaita’, meaning lifestyle. The traditional MedD is a lifestyle and cultural practice. Indeed, UNESCO recognised the MedD as an intangible heritage in 2013(12). In the UNESCO statement, specific foods are not highlighted, rather the food-based lifestyle and cultural heritage of that region ‘…a set of skills, knowledge, rituals, symbols and traditions, ranging from the landscape to the table. Eating together is the foundation of the cultural identity…’(12). The 2011 MedD pyramid recognised these lifestyle activities including: physical activity, adequate rest, culinary activities, conviviality, biodiversity and seasonality, and traditional, local and eco-friendly products(Reference Bach-Faig, Berry and Lairon6). The interpretation of some of these recommendations, such as ‘traditional, local, and eco-friendly products’, will vary throughout the world; therefore, special cultural consideration is needed with the growing popularity of the MedD for its potential health impacts. The latest revision of the MedD pyramid places greater emphasis on the environmental impact of foods, sustainability of the food system and the need for individual countries to adapt the MedD to their ‘food systems and culture-rooted cuisines’(Reference Serra-Majem, Tomaino and Dernini9).

While the unique dietary and lifestyle features of the MedD have individual health associations, it is the synergistic effect of the diet components that infers its unique health benefit(Reference de Groot, van Staveren and Burema13Reference Zaslavsky, Zelber-Sagi and Shikany17). This is encompassed by MedD scoring systems; they encapsulate this dietary pattern into a numeric score for assessment with health outcomes. Reviews of the validity, reliability and content of MedD scoring systems for adherence have been conducted(Reference Hernández-Ruiz, García-Villanova and Guerra Hernández18Reference Zaragoza-Martí, Cabañero-Martínez and Hurtado-Sánchez20). Despite these examinations, a comparative application of these scoring systems in Mediterranean and non-Mediterranean countries has not been evaluated. This review will discuss scoring systems used in both Mediterranean and non-Mediterranean countries to obtain an understanding of cultural and geographic similarities and differences, with the goal of enhancing future applications of MedD assessment around the world. To provide a historical and time-dependent landscape for comparisons and applications, we will first review the evolution of the MedD in both Mediterranean and non-Mediterranean countries.

Evolution of Mediterranean diet scoring systems in Mediterranean countries

The Mediterranean region encompasses land from three continents and a number of cultural and religious traditions. This has resulted in a slightly different interpretation of the MedD dependent on the region in which the scoring system was originally intended. For example, wine or alcohol consumption was removed from some scoring systems to account for religious beliefs, or adjustments made for the predominant source of grains by region of the Mediterranean. These adaptations present a challenge in standardising the components that make up the MedD, even within Mediterranean countries. This section will review the evolution of the most prominent MedD scoring systems from Greece, Spain and Italy as these were the Mediterranean countries first studied for the health effects of the MedD; then, MedD scoring systems from Eastern Mediterranean and Southern Mediterranean regions will be discussed. For all scoring systems, a higher score reflects higher compliance to the traditional MedD or MedD pyramid recommendations.

Mediterranean region: Greece

The first MedD scoring system and the most commonly applied, with slight modifications over the years, is the MedD Scale (MDS) originally devised by Trichopoulou (T-MDS) and colleagues in 1995 (see Table 1)(Reference Trichopoulou, Kouris-Blazos and Wahlqvist21). In 2003, fish was added as a beneficial component to the T-MDS(Reference Trichopoulou, Costacou and Bamia15). Furthermore, in 2005, Trichopoulou modified the T-MDS’s lipid ratio to include PUFA to the MUFA:SFA ratio and only included fruits, rather than both ‘fruits and nuts’ together(Reference Trichopoulou, Orfanos and Norat22), for use in nine European countries in the EPIC study (Denmark, France, Germany, Greece, Italy, the Netherlands, Spain, Sweden and the UK). Understanding the evolution of the T-MDS and other Mediterranean-based MedD scoring systems is essential for scholars studying the MedD to be able to interpret and apply research findings published at different points in time. Throughout this review, the year of publication will be assigned to the T-MDS to allow for rapid identification and to reflect the slight but meaningful differences in reported intakes from these three original T-MDS publications.

Table 1. Mediterranean diet scoring system food components in Mediterranean countries

T-MDS, Trichopoulou-Mediterranean Diet Scale; mT-MDS, modified T-MDS; rMED, revised T-MDS; MLDS, Mediterranean-Like Diet Score; MDSS, Mediterranean Diet Serving Score; MedD, Mediterranean Diet; LBAS, Literature-Based Assessment Score; SSB, sugar-sweetened beverages.

* Also included in the score are use of herbs, spices, garnish (+), snacks (–), salt at meals (–), as well as lifestyle behaviours; + included in score as beneficial component; – included in score as negative component; M included in score as moderate intake with upper and lower intake cut-offs; 0 not included in score.

Specifically pasta.

Excluding potatoes.

§ Specific Mediterranean vegetables.

|| Including raw and cooked.

And fruit and vegetable juices.

** And dried fruits.

†† And seeds, excluding juices.

‡‡ And olives.

§§ And nuts.

|||| Including cream and margarine.

¶¶ Full fat only.

*** In Sanchez et al. 2006 only.

††† Excluding milk and yogurt.

‡‡‡ Excluding poultry and rabbit.

§§§ And processed meats.

|||||| Wine and beer.

¶¶¶ MUFA + PUFA:SFA.

**** And/or carbonated beverages.

†††† Including SSB.

‡‡‡‡ Manufactured sweets.

The Panagiotakos Mediterranean Diet Score (MedDietScore), developed in 2006, is also a commonly applied scoring system based on the MedD pyramid recommendations(7,Reference Panagiotakos, Pitsavos and Stefanadis23) . This system includes eleven foods/food group questions on a 0–5 scale resulting in a wider ranging score (0–55). Some differences from the T-MDS are that the MedDietScore includes potatoes and olive oil (instead of MUFA:SFA ratio) as positive factors, but nuts are not included, and white meat/poultry is a negative factor. Dietary intake from FFQ data was first applied for monthly intakes but was converted to weekly intakes for ease of use(Reference Panagiotakos, Pitsavos and Stefanadis23,Reference Panagiotakos, Pitsavos and Arvaniti24) .

Mediterranean region: Spain

The T-MDS, 2003, was applied to a Spanish population in a few different ways, depending on the study. All of the Spanish T-MDS adaptations used tertiles rather than median cut-off values, others replaced the lipid ratio with olive oil and other food group changes (see Table 1)(Reference Benítez-Arciniega, Mendez and Baena-Díez25Reference Schröder, Marrugat and Vila28). The Mediterranean-Like Diet Score was developed in 2011 and included components of the T-MDS, 2005 with some changes to meats and dairy groups (See Table 1)(Reference Benítez-Arciniega, Mendez and Baena-Díez25).

Two scoring systems out of Spain are based on the 2011 MedD pyramid(Reference Bach-Faig, Berry and Lairon6). The Mediterranean Diet Serving Score (MDSS) uses a weighted scoring system and includes upper and lower limits for food group intake on a meal, day or week frequency(Reference Monteagudo, Mariscal-Arcas and Rivas29). The MEDLIFE tool is the only assessment tool to incorporate a number of dietary behaviours and lifestyle factors with the food intake questions(Reference Sotos-Prieto, Moreno-Franco and Ordovás30,Reference Sotos-Prieto, Santos-Beneit and Bodega31) . This scoring system includes foods/food groups in totals per d rather than breaking down to the meal intake as done by Monteagudo and colleagues. Dietary habits and specific physical activity, rest, social habits and conviviality questions are also included, with scoring for each question using a simple yes/no (1/0 points) format(Reference Sotos-Prieto, Moreno-Franco and Ordovás30,Reference Sotos-Prieto, Santos-Beneit and Bodega31) .

The fourteen-point Mediterranean Diet Adherence Score (MEDAS)(Reference Schröder, Fitó and Estruch32) is a self-report screening questionnaire that was developed for use in the PREDIMED study for rapid adherence assessment. It has also been used to determine MedD adherence from FFQ or diet record data. This tool has been adapted and applied around the world (see Table 2)(Reference Hebestreit, Yahiaoui-Doktor and Engel33Reference Li, Guasch-Ferré and Chung43).

Table 2. MEDAS validation studies in non-Mediterranean countries

SSB, sugar-sweetened beverages; NHS, Nurse’s Health Study; HPFS, Health Professionals Follow-up Study; NA, Not Available.

* MEDAS components(Reference Schröder, Fitó and Estruch32), include one point for intake above recommended cut-offs for vegetables, fruits, nuts, legumes/pulses, olive oil, fish, sofrito and preference for white meat over red meat and olive oil as the main source of fat. One point for moderate wine intake. One point for intake below the recommended cut point for butter/cream/margarine, red meat and sausages, SSB and/or carbonated beverages, and commercial pastries. See ref. 32 for list of how the intake questions were asked.

Mediterranean region: Italy

MedD scoring systems from Italy have used modifications to the T-MDS or have been developed independently. The Italian arm of the EPIC study modified the T-MDS into the ‘Italian Mediterranean Index’ using tertiles for cut-offs(Reference Agnoli, Krogh and Grioni44). This scoring system is specific to the cultural food practices of Italy (see Table 1).

In southern Italy, in 2016, Zito and colleagues applied a short MedD questionnaire with up to nine total points from FFQ dietary data(Reference Zito, Polese and Vozzella45). Additionally, two assessment tools were developed in northern and southern Italy for direct patient use, the QueMed and MEDI-Quest, respectively (Table 1). The QueMed is a self-administered questionnaire that assigned points for responses of never or seldom (0) to high frequency (5)(Reference Gnagnarella, Dragà and Misotti46). The MEDI-Quest scoring system included traditional and non-traditional food groups with pre-defined food group cut-offs for assigning 0, 1 or 2 points(Reference Vitale, Racca and Izzo47). The MEDI-Quest only evaluates frequency of intake and was developed as a nutrition education tool as well as for MedD assessment(Reference Vitale, Racca and Izzo47).

Eastern and southern Mediterranean region

The Lebanon MedD Index and Israeli(i)-MEDAS represent the eastern Mediterranean region. The Lebanon MedD Index used factor analysis from a traditional Lebanese dietary pattern to identify nine foods/food groups(Reference Naja, Hwalla and Itani48). While this tool differed in some components from the MedD, core components such as olive oil, fruit and vegetables are consistent with other MedD scoring systems(Reference Naja, Hwalla and Itani48). A scoring system was recently developed to represent the southern Mediterranean region using the MedD pyramid(Reference Bach-Faig, Berry and Lairon6). The Moroccan-modified MedD includes twelve components, with foods within the food groups specific to the Southern Mediterranean food culture as well as western-type foods(Reference El Kinany, Mint Sidi Deoula and Hatime49).

Multi-country-derived MedD scoring system

An a posteriori calculation was determined by Sofi and colleagues(Reference Sofi, Abbate and Gensini50) in 2012 proposing cut-offs for intake based on the literature rather than the median or tertile intakes of the study population. This calculation used food groups of the T-MDS, 2003 except for replacing the lipid ratio with olive oil. A subsequent meta-analysis (2014) and application (2017) of the literature-based score (LBAS) has intake cut-offs that are more in line with MedD pyramid recommendations (Table 1)(Reference Sofi, Macchi and Abbate51,Reference Sofi, Dinu and Pagliai52) . While this scoring system removes the limitation of median intakes from the T-MDS, it does not account for non-traditional MedD intake such as sweets, processed or fast food/takeout foods, or sugar-sweetened beverages (SSB). Ignoring the intake of non-traditional foods in a MedD scoring system will likely underestimate true intakes, especially when applied to non-Mediterranean countries.

Consistencies and deviations of scoring systems developed in Mediterranean countries

The application of MedD scoring systems in the Mediterranean region has evolved over the last 25 years to better reflect the lifestyle and dietary changes that this region faces, particularly in the younger generations. As illustrated in Table 1, the scoring systems out of Greece only measure ‘traditional’ MedD foods. Some scoring systems out of Spain and Italy have begun to also include non-traditional foods (sweets, processed or fast food/takeout food, SSB) as negative components which is more in line with modern food intakes around the world. While the inclusion of more foods better aligns with modern food intakes, this has also increased variability and inconsistency in the MedD literature.

Evolution of Mediterranean diet assessment tools in non-Mediterranean countries

The application of MedD scoring systems originally developed to assess food intake patterns of adults in the Mediterranean region is commonly applied to non-Mediterranean countries with varied levels of adjustment and validation for the specific population. The most commonly used application is a modification of the T-MDS, 2003 by Fung and colleagues in 2005 called the Alternative Mediterranean Diet Scale (aMed), see Table 3 and 4 (Reference Fung, Hu and McCullough53,Reference Fung, McCullough and Newby54) .

Table 3. Mediterranean diet scoring systems in non-Mediterranean countries

PyrMDS, Pyramid-based Mediterranean Diet score; NU-AGE, New Dietary Strategies Addressing the Specific Needs of Elderly Population for Healthy Aging in Europe; MediCul, MedD and Culinary Index; T-MDS, Trichopoulou-Mediterranean Diet Scale; jMD, Japanese MedD Score; aMed, alternate Mediterranean Diet Scale; MDI, MedD Index; MSDPS, Mediterranean-Style Dietary Pattern Score; MedD, Mediterranean diet; mMedD, modified MedD; BPRHS, Boston Puerto Rican Health Study; mMedD, modified MedD; MEPA, Mediterranean Eating Pattern for Americans; RCT, randomised controlled trial; MCI, mild cognitive impairment.

Table 4. Mediterranean diet scoring system food components from US studies

aMed, alternate Mediterranean Diet Scale; MSDPS, Mediterranean-Style Dietary Pattern Score; BPRHS, Boston Puerto Rican Health Study; T-MDS, Trichopoulou-Mediterranean Diet Scale; MedD, Mediterranean diet; mMedD, modified MedD; MEPA, Mediterranean Eating Pattern for Americans; SSB, sugar-sweetened beverages; M, Moderation. + included in score as beneficial component; – included in score as negative component; M included in score as moderate intake with upper and lower intake cut-offs; 0 not included in score.

* Total CHO.

White bread/starches.

Refined grains.

§ Excluding potatoes.

|| And green leafy vegetables.

And nuts.

** And fruit and vegetable juice.

†† And berries.

‡‡ And olives.

§§ Only oil used.

|||| Full fat cheese/cream cheese.

¶¶ Milk and yogurt.

*** Beer.

††† MUFA + PUFA:SFA.

‡‡‡ Diet beverages.

§§§ Fried vegetables.

The MEDAS tool has garnered worldwide popularity in recent years as a rapid and direct assessment measurement. For example, MEDAS was validated for direct self-report use in Germany, the UK, Canada and the USA(Reference Hebestreit, Yahiaoui-Doktor and Engel33,Reference Papadaki, Johnson and Toumpakari34,Reference Ghisi, Mahajan and da Silva Chaves41,Reference Bottcher, Marincic and Nahay42) . The multiple study applications have strengthened the validity and reliability for use in research and clinic settings or via telephone interviews(Reference Hebestreit, Yahiaoui-Doktor and Engel33Reference Gregório, Rodrigues and Salvador35). Table 2 outlines the application and evolution of MEDAS throughout the world. Of note, some have modified the MEDAS to remove or add questions and thus have resulted in scores that range from 0–12 to 0–17(Reference Abu-Saad, Endevelt and Goldsmith38,Reference Li, Guasch-Ferré and Chung43) . The scores vary slightly depending on the country of origin and study design (see Table 2). For instance, young adults in a university setting had the lowest average MEDAS score (males 4·11 (2·33) and females 5·00 (1·9)) when using the 0–14 scale(Reference Bottcher, Marincic and Nahay42). Comparing Mediterranean and European countries, differences were also observed (see Table 2)(Reference García-Conesa, Philippou and Pafilas36).

Non-Mediterranean European countries

Differences in lifestyle and diet on the European content impact health outcomes. The northern European country’s climate, food procurement and preferences differ from the Mediterranean basin.

Application of previously developed scoring systems

The EPIC study used the T-MDS, 2005 and found that highest MedD adherence was in Greece, followed by Spain, Italy, then France; the Netherlands had the lowest average T-MDS, 2005 score(Reference Trichopoulou, Orfanos and Norat22). The Sofi LBAS, with pre-determined food group intake cut-offs, was applied to dietary data in the Health Alcohol and Psychosocial Factors in Eastern Europe study which included urban centres in Poland, Russia and the Czech Republic. High LBAS scores occurred in only 25 % of all subjects with the lowest scores from the Russian cohort(Reference Stefler, Malyutina and Kubinova55). When compared with the T-MDS, 2005, the LBAS demonstrated greater odds reduction of all cause and cardiovascular mortality(Reference Stefler, Malyutina and Kubinova55).

Scoring systems for specific use in the UK

The PyrMDS scoring system used a different approach than T-MDS and is based on the 2011 MedD pyramid recommendations to assess MedD adherence in the UK, EPIC-Norfolk prospective cohort (Tables 3 and 5)(Reference Tong, Wareham and Khaw56). A new scoring system, the New Dietary Strategies Addressing the Specific Needs of Elderly Population for Healthy Aging in Europe (NU-AGE) Index, was developed to assess MedD like intake patterns in a year-long intervention study in older adults throughout Europe (Tables 3 and 5)(Reference Jennings, Berendsen and de Groot57,Reference Berendsen, Santoro and Pini58) . Similar to the Alternative Healthy Eating Index(Reference McCullough, Feskanich and Stampfer59), the NU-AGE Index uses a continuous scale (0–10) for sixteen food items, which is a different approach than other MedD scoring systems(Reference Jennings, Berendsen and de Groot57). PyrMED, Nu-AGE Index and LBAS used pre-determined cut-offs for assigning points within the scoring systems; these studies demonstrate utility for populations outside of the Mediterranean region.

Table 5. Mediterranean diet scoring system food components in non-Mediterranean countries

PyrMDS, Pyramid-based Mediterranean Diet Score; NU-AGE, New Dietary Strategies Addressing the Specific Needs of Elderly Population for Healthy Aging in Europe; MediCul, MedD and Culinary Index; MDS, Mediterranean Diet Scale; jMD, Japanese MedD Score; aMed, alternate Mediterranean Diet Scale; T-MDS, Trichopoulou-Mediterranean Diet Scale; MedD, Mediterranean diet; MDI, MedD Index; SSB, sugar-sweetened beverages; M, Moderation. + included in score as beneficial component; – included in score as negative component; M included in score as moderate intake with upper and lower intake cut-offs; 0 not included in score.

* All grains.

Excluding potatoes.

And nuts.

§ And pulses.

|| Primary lipid.

Not fermented.

** Or fermented.

†† And peanuts.

‡‡ And fatty meats.

§§ Red wine.

|||| MUFA + PUFA:SFA.

¶¶ Salt in general.

Australia

As the original associations between the MedD and health expanded, so too did research and assessment outside of European countries. Some studies applied scoring systems developed in Mediterranean countries, while others developed new MedD adherence tools.

Application of previously developed scoring systems

An early assessment of the MedD in 1999 was conducted in Melbourne with application of the T-MDS, 1995 (energy adjusted) to FFQ dietary data from Anglo-Celt Australian and Greek-Australian older adults(Reference Kouris-Blazos, Gnardellis and Wahlqvist60). Eighty-one percentage of the Greek-Australian sample had four of eight possible points, whereas only 28 % of the Anglo-Celt Australians reached that level of MedD adherence(Reference Kouris-Blazos, Gnardellis and Wahlqvist60). In 2011, the Melbourne Collaborative Cohort Study applied the T-MDS, 2003 with olive oil instead of the MUFA:SFA ratio to measure MedD adherence(Reference Hodge, English and Itsiopoulos61). More recently, the MEDAS was also applied in a Australian randomised controlled trial(Reference Parletta, Zarnowiecki and Cho37).

Scoring systems for specific use in Australia

Two new scoring systems were developed in Australia (see Tables 3 and 5). The fifteen-point MedLey tool was used to monitor dietary changes over the course of a 6-month intervention study(Reference Davis, Hodgson and Woodman62). Additionally, in 2018, the MedD and Culinary Index (MediCul) was developed for self-report of Australian adults and older adults and includes food groups as well as dietary and lifestyle behaviours(Reference Radd-Vagenas, Fiatarone Singh and Daniel63,Reference Radd-Vagenas, Fiatarone Singh and Inskip64) . Lifestyle questions included home gardening, frequency of cooking main meals at home (alone and with others) and daytime napping habits(Reference Radd-Vagenas, Fiatarone Singh and Daniel63).

Asian countries

MedD scoring systems have been adapted to Chinese, Korean, Japanese and Iranian food culture. Most have applied either the T-MDS or aMed, although one new tool was developed for assessing MedD in Japan.

Application of previously developed scoring systems

The first international study assessing the MedD in those with Asian heritage involved Chinese cohorts from four different geographic locations: a rural area of southern China, Hong Kong, San Francisco and Sydney(Reference Woo, Woo and Leung65). The dietary intakes, assessed via a validated FFQ, were applied to an eight-component MedD scoring system first used by DeGroot and colleagues in Greece (Table 5)(Reference de Groot, van Staveren and Burema13). The Chinese cohorts who were older had higher rates of adherence; these rates were even higher than some findings in Greece(Reference Woo, Woo and Leung65). The aMed or T-MDS has also been applied in Chinese populations with mixed results on chronic disease outcomes(Reference Chan, Chan and Woo66Reference Wu, Song and Chen70). These differential findings are possibly due to differences in dietary patterns of older and younger adults and geographic location of the population (urban/rural, mainland or Singapore Chinese heritage)(Reference Woo, Woo and Leung65).

A large epidemiological study of the Korean population applied principles of the aMed score to develop a Korean-modified MedD score(Reference Kim and Je71). Some of the food groups were modified, and foods included within the groupings reflected Korean dietary intakes (Table 5). Specifically, the MUFA:SFA ratio was removed due to lack of information on the fatty acids of foods in the Korean diet(Reference Kim and Je71). Even with the removal of a key MedD feature, higher Korean-modified MedD scores associated with lower prevalence of the metabolic syndrome, abdominal obesity and hypertriacylglycerolaemia(Reference Kim and Je71).

The Okinawan people of Japan are known for longevity, and the traditional Okinawan diet is a prominent factor in that longevity; in fact, the diet shares similarities with the MedD pattern(Reference Willcox, Scapagnini and Willcox72). The T-MDS, 2005 was applied to data from adults in the Japanese annual nationwide nutrition survey (Table 3 and 5), and results showed that the T-MDS, 2005 did not correlate with the Japanese dietary recommendations but that MedD adherence significantly increased with age(Reference Murakami, Livingstone and Sasaki73). The Japanese-modified T-MDS, 2005 did associate positively with a number of beneficial food groups and nutrients and was inversely associated with total and LDL-cholesterol but no other measures of cardiometabolic risk(Reference Murakami, Livingstone and Sasaki73).

Scoring system for specific use in Asia

A specific Japanese MedD scoring system reflects MedD pyramid recommendations as well as Japanese intake patterns and was shown to be inversely associated with obesity(Reference Kanauchi and Kanauchi74). The components of the Japanese MedD scoring system can be found in Table 5.

Mexico and South American countries

Application of previously developed scoring systems

A study of middle-aged women in Mexico applied the T-MDS, 2003, with the addition of sweets and sugar products(Reference Sahrai, Huybrechts and Biessy75). The Sahrai et al.’s study labelled the MedD scoring system as ‘aMed’, which is typically the abbreviation used for Fung’s modifications of the T-MDS, 2003. However, this study did not use the Fung modifications as dairy products were included as a negative factor and fruits and nuts were grouped together. Instead, the changes were based on Wu and colleague’s modifications to the T-MDS, 2003, see Table 5 (Reference Wu, Yu and Tseng76). The inclusion of the specific foods within these food groups (i.e. white flour products, rice, pasta, baked goods) likely made a meaningful difference as the Wu-modified T-MDS, 2003 score associated with lower waist circumference and waist:hip ratios in Mexican women(Reference Sahrai, Huybrechts and Biessy75). In 2020, the MEDAS scale was carefully translated and applied in Brazilian Portuguese-speaking adults (Table 2)(Reference Vieira, Gottschall and Vinholes40).

Scoring systems for specific use in Chile

Leighton and colleagues developed a MedD scoring system that applied the principles of the traditional MedD with customary Chilean food practices(Reference Leighton, Polic and Strobel77). The graded scoring system reflected a gradual increase in MedD scores over the 12-month study and improved metabolic syndrome markers(Reference Leighton, Polic and Strobel77). The Chilean MedD Index is a slightly modified version from that of Leighton and colleagues(Reference Echeverría, McGee and Urquiaga78). This score preserved the integrity of the MedD while including cultural practices in Chile. Likeness of the two geographic regions may influence some of the easily applicable aspects of the MedD to the Chilean diet(Reference Echeverría, Dussaillant and McGee79).

Canada

Application of previously developed scoring systems

In 2019, the MEDAS tool was adapted for use in a Canadian cardiac rehabilitation programme(Reference Ghisi, Mahajan and da Silva Chaves41). The original MEDAS (interviewer-administered) was compared with a self-administered version with sample pictures of portion sizes and food examples relevant to the typical Canadian diet. Psychometric validation of the MEDAS tool in this population verified internal consistency, reliability and criterion and construct validity(Reference Ghisi, Mahajan and da Silva Chaves41).

Scoring systems for specific use in Canada

A French–Canadian group developed a MedD scoring system to determine adherence to a MedD intervention in mid-aged women based on the Oldways MedD pyramid(Reference Goulet, Lamarche and Nadeau80). This tool reflected changes in intake for MedD adherence and cardiometabolic markers(Reference Goulet, Lamarche and Nadeau80).

USA

Most of the research on the MedD and health in North America has been conducted in the USA.

Application of previously developed scoring systems

The aMed is the most widely used MedD scoring system for epidemiological purposes in the USA and has demonstrated associations with all-cause mortality, obesity, heart disease, cognitive impairment and cancer(Reference Fung, Hu and McCullough53,Reference Fung, McCullough and Newby54,Reference Fung, Rexrode and Mantzoros81Reference Zheng, Hur and Nguyen84) . MedD assessment in US cohort studies is often accompanied by other dietary pattern assessments (i.e. Healthy Eating Index (HEI) or Alternative Healthy Eating Index). The comparisons between dietary patterns often demonstrate superior risk reduction from HEI or Alternative Healthy Eating Index compared with aMed. HEI and Alternative Healthy Eating Index include refined grains, added sugars and saturated fats for limited intake; these scores also have a wider scoring range (0–100) compared with the 0–9 score range for aMed. One reason the aMed may not demonstrate similar risk reduction may be due to the narrow score range and inadequate inclusion of food components that are typically seen in Western diets.

The MedDietScore(Reference Panagiotakos, Pitsavos and Stefanadis23,Reference Panagiotakos, Pitsavos and Arvaniti24) was applied to the Chicago Health and Aging Project(Reference Bienias, Beckett and Bennett85), Memory and Aging Project(Reference Tangney, Li and Wang86) and the Building Research in Diet and Cognition(Reference Sanchez-Flack, Tussing-Humphreys and Lamar87) study with grams of intake translated to serving sizes. These studies have cognition outcomes with Chicago Health and Aging Project and Building Research in Diet and Cognition focusing on urban African American older adults(Reference Bienias, Beckett and Bennett85,Reference Sanchez-Flack, Tussing-Humphreys and Lamar87) . While the MedDietScore does not measure intake of non-Mediterranean foods, it provides a graded scale to reflect dietary changes in an intervention study.

Some epidemiological studies that focus on the health of racial and ethnic minorities in the USA have assessed diet by modifying the T-MDS or aMed to capture study population usual intakes (Table 3 and 4)(Reference Wu, Yu and Tseng76,Reference Mattei, Sotos-Prieto and Bigornia88,Reference Levitan, Ahmed and Arnett89) . The CARDIA study, for example, assessed MedD adherence with a modified MDS (mMDS) calculated based on the T-MDS, 2003 and aMed(Reference Steffen, Van Horn and Daviglus90). Even with relatively similar total energy intakes, participants with lower mMDS scores had more than two servings of snack foods (high in solid fat and/or added sugar) compared with those with a higher mMDS(Reference Steffen, Van Horn and Daviglus90). A recent CARDIA publication applied the MedDietScore from FFQ data with the MUFA:SFA ratio replacing olive oil. Regardless of the scoring system used, those with higher MedD adherence in the CARDIA study at baseline were more likely to be white and more physically active(Reference Steffen, Van Horn and Daviglus90,Reference McEvoy, Hoang and Sidney91) . A complete assessment of MedD adherence in racial and ethnic US minorities is beyond the scope of this review but has been previously addressed by Sotos-Prieto & Mattei(Reference Sotos-Prieto and Mattei92).

Scoring systems for specific use in the USA

Scoring systems developed in the USA account for non-traditional MedD foods and behaviours in different ways (Table 4). The MSDPS is based on MedD pyramid recommendations, accounts for overconsumption of foods, includes Mediterranean and non-Mediterranean food intake and is continuously scaled(Reference Rumawas, Dwyer and McKeown93). While this scoring system attempts to remove the limitations of prior MedD adherence scores for a non-Mediterranean population, it is a complex calculation that, to date, has only been applied by one group outside of the original application studies(Reference Jessri, Rashidkhani and Hajizadeh94,Reference Rumawas, Meigs and Dwyer95) .

A modified MedD score was developed specifically for the lifestyle of US firefighters (Tables 3 and 4); this scoring system included graded points (0–4) and non-traditional MedD foods(Reference Yang, Farioli and Korre96,Reference Sotos-Prieto, Christophi and Black97) . Another scoring system, MEDI-Lifestyle, focused on lifestyle factors(Reference Lan, Fernandez-Montero and Yiannakou98). The MEDI-Lifestyle assessed diet with the MEDAS (total score weighted as one component) along with six other lifestyle questions including non-smoking, weight control (BMI ≤ 30 kg/m2), physical activity, limited television viewing, adequate sleep and napping, all one point each(Reference Lan, Fernandez-Montero and Yiannakou98). Lifestyle assessments of conviviality and culinary activities, unique features of the traditional Mediterranean lifestyle, were not included. Similar to findings on MedD scoring systems, the individual lifestyle factors did not inversely associate with hypertension risk, but the synergistic MEDI-Lifestyle score did demonstrate reduced risk(Reference Lan, Fernandez-Montero and Yiannakou98). This further exemplifies the important consideration of a healthy lifestyle rather than a limited number of healthy activities. Application of the modified MedD scores and MEDI-Lifestyle to different populations will require adaptation as some questions specifically ask about food intake and behaviours at the firehouse or at home.

A short Mediterranean-like diet pattern screening tool, the Mediterranean Eating Pattern for Americans (MEPA), was developed for use in the USA that can be delivered electronically or via phone(Reference Cerwinske, Rasmussen and Lipson99). Food groups include those typically found in MedD scoring systems with some specificity and intake amounts that reflect the typical American diet (Tables 3 and 4). MEPA-III added five more components; some food components are provided in more detail and/or had altered serving size cut-offs for point values(Reference Weaver, Goldman and Ribbens100). The self-administered MEPA-III was shown to have concordance with FFQ-derived MEPA-III foods and total scores, as well as construct validity and acceptability in an older sample of Parkinson’s disease patients(Reference Weaver, Goldman and Ribbens100,Reference Ribbens, Rasmussen and Goldman101) ; acceptability and application of MEPA-III in a more racially and ethnically diverse sample of adults are warranted.

Comparisons between and across Mediterranean diet scoring systems

The ability to compare MedD adherence within and across countries and populations on a broad scale is difficult because of the many choices in scoring systems and adaptations made for use in specific populations, cultures and countries. Some studies have directly compared different scoring systems in the same population or used the same scoring system to compare different populations, as described below.

Comparing the same Mediterranean diet scoring system across different populations

Comparison of the same tool across different populations has occurred using the MEDAS and MDSS. The MEDAS was assessed in adults from five Mediterranean countries and two Balkan countries (Greece, Portugal, Italy, Spain, Cyprus, Republic of North Macedonia and Bulgaria) on two occasions using direct self-report and compared with a 3-d food record(Reference García-Conesa, Philippou and Pafilas36). This study found highest adherence in the Spanish population, where the assessment tool was originally developed, with lowest adherence from Macedonia and Bulgaria. The lowest level of agreement between 3-d food records and the MEDAS was in the Balkan countries, while Greece had the highest level of agreement(Reference García-Conesa, Philippou and Pafilas36). The MDSS was compared in Spanish, Moroccan and Palestine adults(Reference Benhammou, Heras-González and Ibáñez-Peinado102). Dietary intake was assessed using three 24-h recalls, country-specific validated FFQ and the MDSS. There was no significant difference in MDSS scores between the countries; however, significant nutrient and food group differences did occur. Vegetable and nut intake was below recommendations and meat intake (white and red) above recommendations in all three countries with Palestine and Moroccan adults consuming significantly more than Spanish adults(Reference Benhammou, Heras-González and Ibáñez-Peinado102). These findings highlight the importance of examining food components, not just the total score, when making cross-cultural assessments to interpret how different cultures may be adhering to MedD recommendations. For instance, high meat intake is a cultural norm in many non-Mediterranean countries and is a hurdle to address when designing and implementing MedD intervention studies and recommendations outside the Mediterranean region(Reference Murphy and Parletta103).

Comparing Mediterranean diet scoring systems within the same population

Aoun and colleagues compared five different MedD scoring systems: the T-MDS, 2003(Reference Trichopoulou, Costacou and Bamia15), MedDietScore(Reference Panagiotakos, Pitsavos and Arvaniti24), Chilean MedDietScore(Reference Leighton, Polic and Strobel77), Short MedD questionnaire(Reference Zito, Polese and Vozzella45,Reference Martínez-González, Fernández-Jarne and Serrano-Martínez104) and MedD pattern score(Reference Martínez-González, Fernández-Jarne and Serrano-Martínez105) in Lebanese adults using data and food groups extrapolated from the same FFQ. The scores positively correlated with one another; agreement was highest between (1) the T-MDS, 2003 and MedDietScore and (2) the T-MDS, 2003 and Short MedD questionnaire(Reference Aoun, Bou Daher and El Osta106). There was a high degree of non-adherence, regardless of the scale used, and no scale was associated with BMI(Reference Aoun, Bou Daher and El Osta106). Naja and colleagues compared the Lebanese MedD Index with the EPIC-T-MDS(Reference Trichopoulou, Orfanos and Norat22) and MedD scoring systems that were representative of four Mediterranean countries: Greece (MedDietScore(Reference Panagiotakos, Pitsavos and Stefanadis23)), Italy (Italian-TDS(Reference Agnoli, Krogh and Grioni44)), Spain (r-Med(Reference Buckland, González and Agudo27)) and France (MedD Quality Index(Reference Gerber107)). Fruits, vegetables and olive oil were the common factors included in all scales tested; fish was included in all scales except the Lebanese MedD Index(Reference Naja, Hwalla and Itani48). Lipids were assessed differently by region of origin. The French and Lebanese scales included cholesterol and SFA, while the ratio of MUFA:SFA was used in the Spanish, Greek, Italian and EPIC scales(Reference Naja, Hwalla and Itani48). Both Lebanese-based studies found that older participants reported greater adherence to the traditional MedD.

A short (nineteen open-ended questions) food intake survey for Greek adults was used to test the T-MDS and MEDAS, compared with T-MDS derived from FFQ dietary data to determine if a shorter overall dietary assessment tool could be used in place of the FFQ in epidemiological studies(Reference Bamia, Martimianaki and Kritikou108). The FFQ-T-MDS estimated intake using g/d, whereas the shorter food intake survey used servings/d. The two T-MDS scoring systems were moderately correlated (r s = 0·31) and even less with MEDAS (r s = 0·23)(Reference Bamia, Martimianaki and Kritikou108).

Two comparisons of different MedD scoring systems were assessed in Spanish populations, one in a healthy young undergraduate sample of Spanish students and the other from the control group of the Multi-Case Control study of Spanish adults(Reference Milà-Villarroel, Bach-Faig and Puig109,Reference Olmedo-Requena, González-Donquiles and Dávila-Batista110) . The Spanish young adult study used dietary data from a FFQ to calculate ten MedD scoring systems. Most of the scoring systems were in fair agreement with one another (r s = 0·5–0·7) and satisfactorily measured MedD adherence(Reference Milà-Villarroel, Bach-Faig and Puig109). Using factor analysis, fruits, vegetables and the MUFA:SFA ratio strongly correlate with the MedD factor(Reference Milà-Villarroel, Bach-Faig and Puig109). More recently, Olmedo-Requena and colleagues found similarly moderate correlations between five scoring systems in a sample of Spanish adults(Reference Olmedo-Requena, González-Donquiles and Dávila-Batista110). Data from all scales tested (T-MDS, 2003, aMed, rMED, MedDietScore and LBAS) were normally distributed; however, the MedDietScore’s distribution showed higher variability, likely due to the wider scoring range(Reference Olmedo-Requena, González-Donquiles and Dávila-Batista110).

The first assessment of multiple MedD scoring systems outside of the Mediterranean region was from the UK, EPIC-Norfolk prospective cohort study using four MedD assessment methods (T-MDS, 2005, LBAS, rMED and PyrMDS)(Reference Tong, Wareham and Khaw56). The T-MDS, 2005 used median intake cut-offs and a 0–9 point range, rMED used tertile cut-offs with a 0–18 point range, LBAS used literature-based serving size cut-offs with a 0–18 point range and PyrMDS used MedD pyramid recommended intakes with a 0–15 point range. The PyrMDS included more food groups than the other scoring systems and had the strongest association with CVD outcomes(Reference Tong, Wareham and Khaw56). All scoring systems had fair to moderate correlations with one another. The lowest correlation was between T-MDS, 2005 and PyrMDS (r s = 0·53), while the highest correlation was between T-MDS, 2005 and rMED (r s = 0·81), the latter correlation only differed in cut-offs(Reference Tong, Wareham and Khaw56). Comparisons of MedD scoring systems applied to countries outside of Europe and the Mediterranean basin are needed to critically assess components of MedD scoring systems to provide empirical evidence for choosing which foods and food groups are most important in these scoring systems to strengthen this body of literature.

Considerations for application of Mediterranean diet assessment tools

There is no single measure to assess adherence to the MedD (as demonstrated above) which is not surprising considering the various approaches taken in following the MedD across the globe. However, this non-conformity and flexibility also bring significant variability to the measurement tools developed for MedD assessment. Scoring systems vary in the number of components, component categories, measurement scales, statistical parameters used for cut-offs and the positive, negative or moderate contributions components have to the total score.(Reference Milà-Villarroel, Bach-Faig and Puig109)

Dietary measurement is strengthened when using standardised, validated tools. However, a limitation of the current MedD literature is the different scoring systems used, many of which lack full validation and reproducibility, as discussed in a comprehensive review by Zaragoza-Martini and colleagues(Reference Zaragoza-Martí, Cabañero-Martínez and Hurtado-Sánchez20). This section considers dietary assessment methodology, the foods included (or excluded) in scoring systems, non-MedD patterns, lifestyle components, geography and differences in foods and food preparation, clinical application of scoring systems, and last, challenges and opportunities for MedD scoring system application.

Methodological challenges in dietary assessment

Most MedD scoring systems calculate dietary pattern adherence from dietary data collected from FFQ, a few use diet records or 24-h recalls. The reported intake of individual foods is grouped into food categories that are then applied to the dietary pattern scoring system calculation. The multiple step process of applying dietary pattern scoring systems can add a potential source of bias or error. When publishing dietary pattern scoring systems, the foods assigned to each food group and the groups included for the specific analysis should be included with supplementary material to limit this area of potential bias and to allow for more uniform cross-study assessments. The FFQ, the most commonly used dietary assessment method in epidemiological research, is limited by recall and estimation difficulty for usual intake over a long period of time; limited detail for preparation, mixed foods or home-made and store-bought options; and under- or over-reporting(Reference Brown111Reference Willett, Howe and Kushi113). Some of the limitations are reconciled when extremely low or high dietary energy estimates are removed from the analysis. Study-specific alterations for MedD scoring systems are sometimes needed based on available dietary and lifestyle data. For instance, when FFQ dietary data from large US cohort studies were applied to the MEDAS, there was not available information for two of the questions, so instead of a fourteen-point scoring system, the MEDAS was reduced to a twelve-point scoring system for this application(Reference Li, Guasch-Ferré and Chung43). Additional areas for consideration are the application of energy adjustments, units of intake, population-based cut-offs and advances in dietary assessment technology.

Energy adjustment is recommended for comparing diet–disease relationships(Reference Willett, Howe and Kushi113). However, the use of energy adjustment and units of intake is applied inconsistently in MedD scoring systems. Interestingly, the Spanish application of T-MDS, 2003 from FFQ or 24-h recall dietary data found that MedD adherence had similar agreement and no proportional bias in energy-adjusted and non-energy-adjusted scores(Reference Benítez-Arciniega, Mendez and Baena-Díez25). Both energy-adjusted and non-energy-adjusted MedD adherence can be found in the available literature. Serving sizes are typically used to self-report dietary intake, while g/d is an option when MedD scores are determined indirectly from other dietary assessment methods. Some argue for the simplicity and accuracy of the cut-offs for scoring using g/d(Reference Bamia, Martimianaki and Kritikou108), while others point out limitations of this use(Reference Hoffman and Gerber114).

MedD scoring systems are calculated from indirect (FFQ, 24-h recalls or diet record data) or direct self-report questioning to determine adherence. The MedDietScore, although first developed using FFQ data, has been applied in a direct questioning format as have the LBAS, MediCul and MEPA-III scoring systems(Reference Sofi, Dinu and Pagliai52,Reference Radd-Vagenas, Fiatarone Singh and Daniel63,Reference Sanchez-Flack, Tussing-Humphreys and Lamar87,Reference Weaver, Goldman and Ribbens100,Reference Bihuniak, Ramos and Huedo-Medina115) . Alternatively, MEDAS was not only developed for use in an interview or direct self-report format but has also had dietary data applied indirectly from other assessment methodologies(Reference García-Conesa, Philippou and Pafilas36,Reference Li, Guasch-Ferré and Chung43,Reference Bamia, Martimianaki and Kritikou108) . The low or moderate correlations observed when comparing different scoring systems, even in the same population, highlight the inherent issues when applying dietary data from different assessment methods to scoring systems, even in the same population(Reference Bamia, Martimianaki and Kritikou108).

Cut-offs, component scoring and total score are also inconsistent throughout the MedD literature. The T-MDS and aMed use median cut-offs from each study sample (in g/d or serving sizes), and the T-MDS modifications have applied tertiles as cut-offs, while other studies have used MedD pyramid recommendations or literature-based median or tertile cut-offs. The use of population-dependent, sex-specific cut-offs (median or tertiles) has resulted in vastly different food group median intakes(Reference Sofi, Macchi and Abbate51) and difficulty in cross-study comparisons. Application of MedD pyramid recommended intakes for cut-offs has increased in the last few years, and this has, unfortunately, added to the variability in scoring components. Some scoring systems use weighted or graded scoring (MDSS(Reference Monteagudo, Mariscal-Arcas and Rivas29), mMDS(Reference Yang, Farioli and Korre96,Reference Sotos-Prieto, Christophi and Black97) , Chilean MDI(Reference Echeverría, McGee and Urquiaga78)), while others use 0 or 1 point for meeting the recommendation or not (MEDAS(Reference Schröder, Fitó and Estruch32), MEDLIFE(Reference Sotos-Prieto, Moreno-Franco and Ordovás30), MEPA(Reference Cerwinske, Rasmussen and Lipson99,Reference Weaver, Goldman and Ribbens100) , Japanese MedD scoring system(Reference Kanauchi and Kanauchi74)). Alternatively, some scoring systems use continuous scales (MSDPS(Reference Rumawas, Dwyer and McKeown93), PyrMDS(Reference Tong, Wareham and Khaw56), NU-AGE Index(Reference Jennings, Berendsen and de Groot57)) or variable frequencies of intakes (MediCul(Reference Radd-Vagenas, Fiatarone Singh and Daniel63,Reference Radd-Vagenas, Fiatarone Singh and Inskip64) ). Even when using the same cut-off methodology, some studies with tertiles use 0–2 points, while other apply 1–3, creating a 0–18 or 9–27 scale range. Finally, the total score and number of components within a scoring system can alter the weight of each individual component. Some scoring systems have added or removed items to accommodate cultural differences, this practice limits cross-cultural and cross-country comparisons and should be limited moving forward. Scoring systems with more components place less weight on each individual component, whereas scoring systems with fewer components have more weight from each individual component. For instance, weight of each food component in the T-MDS is 1/9th, whereas a score with more factors such as the MEDAS with 14 or the MEDLIFE with 26 has less weight for each individual component (1/14th and 1/26th, respectively). The influence of a score’s individual component quantity on total score or nutrient values and health outcomes is unknown.

The application of smartphone and other technology to assess dietary intake has recently been applied to the MedD(Reference Vasiloglou, Lu and Stathopoulou116). The methodological intricacies and appropriate calculation of amount ingested require further validation studies(Reference Eldridge, Piernas and Illner117), but it is a promising new approach(Reference Vasiloglou, Lu and Stathopoulou116). This application is best suited for use in intervention trials or clinical practice, as it is designed to provide real-time feedback for meeting food and nutrient intake goals.

Inconsistencies in food components of Mediterranean diet scoring systems

Some food components are largely universal in all scoring systems, while others may or may not be included at all or may differ in the way in which they are included. Tables 3, 4 and 5 include an extensive list of scoring systems, with the food components listed as to whether they are considered as positive, negative or moderate contributors to MedD adherence. Even the universal MedD scoring system components, fruits and vegetables, have some variability. For instance, in some scores, the fruit group includes nuts, but most separate the two, or only include fruits. Similarly, vegetables may or may not include potatoes. Potatoes are one of the more variable components, having been included as a separate negative component, as a separate moderate component, in the grains/cereals category, or not at all. Grains are a consistent component of a MedD but are included in different ways depending on the scoring system. The term ‘cereals’ was first used and since then has been reframed to include only whole-grain cereals in many of the updated scoring systems, while others differentiate between whole grains and refined grains or total carbohydrates. One of the more widely used scoring systems, MEDAS, does not include cereals or grains but does include commercial pastries as a negative component.

The MedD pyramid recommends moderate intake of a variety of protein sources including legumes, fish, poultry, nuts, seeds and eggs with limited red and processed meat. There are variations in the way meat is included in scoring systems. Red and/or processed meat is consistently scored as a negative component. The original T-MDS, 1995 did not include fish, although now it is considered a consistently positive component of scoring systems. Legumes are included in most scoring systems as nuts, which are sometimes included with fruits. Nuts have also been grouped with olives(Reference Sotos-Prieto, Moreno-Franco and Ordovás30), with legumes(Reference Vitale, Racca and Izzo47), or all three combined(Reference Rumawas, Dwyer and McKeown93). Most scoring systems include all nuts into the nuts category; the type of nut included largely depends on the geographic and cultural preferences of the study population. The Feeding America’s Bravest study, for example, specifically excludes peanuts and peanut butter from its intervention and scoring(Reference Sotos-Prieto, Cash and Christophi118), while the Korean adaptation of the aMed score included peanuts with fish as one of the beneficial food groups(Reference Kim and Je71).

Unsaturated fat intake is one of the hallmarks of the MedD. The original T-MDS, 1995/2003 included a lipid ratio (MUFA:SFA) which was slightly altered in the T-MDS, 2005 (PUFA + MUFA:SFA) to encompass all unsaturated fat intake. The lipid ratio, however, cannot be used in direct self-report scoring systems. MEDAS includes two questions regarding olive oil use and also butter, cream and/or margarine intake as a detrimental component(Reference Schröder, Fitó and Estruch32). In non-Mediterranean countries, some tools continue to use the lipid ratio, while others use olive oil or other dietary lipids. For instance, Chilean MedD scoring systems have multiple positive components for PUFA and MUFA to reflect that region’s intake of vegetable, olive and canola oils, and avocado(Reference Leighton, Polic and Strobel77,Reference Echeverría, McGee and Urquiaga78) . The inclusion of avocado as a healthy unsaturated dietary fat source was also included in the MEPA-III scoring system(Reference Weaver, Goldman and Ribbens100); however, it was argued against when defining a traditional MedD(Reference Martínez-González, Hershey and Zazpe119).

Wine is a traditional MedD component; however, some regions of the world and cultures have very low wine or alcoholic beverage consumption. The intake of wine or alcohol in general is the one component, when included in the scoring system, that always has an upper limit. While moderate wine consumption with meals is a unique aspect of the Mediterranean lifestyle, there are cultural and religious differences around the world that preclude its inclusion in the adaptation of scoring systems.

Dairy products are a daily recommendation on MedD pyramids but is one of the more controversial components of MedD scoring systems due to the low intake in the Mediterranean region in the 1960s. Some include the measurement of dairy products but do so negatively, while others do not include measurement of dairy intake at all. Alternatively, low fat dairy or ‘milk and yogurt’ or ‘fermented’ dairy products are sometimes included as a positive component, with high-fat dairy or sweetened dairy as a negative component. This high variability in how dairy products are accounted for in MedD scoring systems adds difficulty in determining how to assess its contribution to the MedD pattern and health implications.

Sweets are at the top of the MedD pyramid, indicating that intakes should be limited; however, sweets were not considered at all in the early adoption of MedD scoring systems. The MAI was the first to include sweets in a scoring system from the Mediterranean region; this scoring system included SSB, sweet baked goods (cakes, pies, cookies) and sugar(Reference Alberti-Fidanza and Fidanza120). Sweets are more commonly included as a negative component in newly developed or modified scoring systems in the last decade or so as either a dietary behaviour, SSB or commercial baked goods and/or confectionary sweets. Findings from the PREDIMED study showed that high consumption of nuts and low consumption of SSB were dietary components from the MEDAS that had the strongest inverse association with abdominal adiposity(Reference Martínez-González, García-Arellano and Toledo121). This emphasises the importance of including non-traditional MedD foods in scoring systems.

There have been suggestions that the inclusion of key nutrients rather than specific food components may aid in the standardisation of the MedD and development of a universal MedD scoring system. While nutrient assessment may eliminate the differences in specific food components included in the MedD scoring system, it will also remove the extremely important, and often overlooked, lifestyle component. Further, foods in the MedD contain essential nutrients and bioactive constituents beneficial to human health (e.g., extra virgin olive oil, fruits, vegetables). Many of the bioactive constituents of MedD foods (i.e. polyphenols, carotenoids) are more difficult to measure and content differs by location and growing conditions. A potential solution may be the inclusion of both specific food components and key nutrients, thereby expanding the use of the MUFA:SFA ratio currently used in some MedD scoring systems to also include specific fibre and added sugar recommendations.

Non-Mediterranean diet patterns

A reality for many areas of the world is regular intake of fast food/take-away and fried foods. Fast-food consumption (restaurant fast food or pizza takeout) is a common dietary behaviour in the USA and Australia(Reference Fryar, Hughes and Herrick122,Reference Machado, Steele and Levy123) ; likewise, the intake of fast foods and ultra-processed foods is increasing worldwide(Reference De Vogli, Kouvonen and Gimeno124). Fast food/takeout and/or fried foods were added to scoring systems from some countries as a negative factor(Reference Radd-Vagenas, Fiatarone Singh and Inskip64,Reference Steffen, Van Horn and Daviglus90,Reference Yang, Farioli and Korre96,Reference Sotos-Prieto, Christophi and Black97,Reference Cerwinske, Rasmussen and Lipson99,Reference Weaver, Goldman and Ribbens100) . A recent report showed that high consumption of ‘western diet components’ such as fried foods, refined grains, sweets, red and processed meats, full-fat dairy and pizza attenuated the positive effect of the MedDietScore on cognition in older adults in the USA(Reference Agarwal, Dhana and Barnes125). This study highlights the importance of assessing MedD components as well as foods that do not align with the MedD pattern.

The traditional MedD in Crete and southern Italy had little processed foods because they were not readily available in these regions until the 1960s. This has changed, and processed foods are now available in all industrialised countries. The Mediterranean region is in a period of nutrition transition where the culture of food and lifestyle are changing. MedD scoring systems need to be able to capture the traditional as well as non-traditional foods consumed to truly identify MedD adherence and potential health benefits.

Lifestyle/dietary behaviour assessment

Meal preparation and food pattern behaviours particular to the traditional MedD such as limited snacking, lunch as the largest meal of the day, and eating meals with others, as well as lifestyle behaviours such as physical activity are not captured by the majority of MedD scoring systems(Reference Hoffman and Gerber114). The MedD pyramid recommendations have always included physical activity as part of diet recommendations(7,8,Reference Willett, Sacks and Trichopoulou10) , but physical activity is not included in scoring systems. Epidemiological studies have consistently found that those with higher MedD adherence also report higher levels of physical activity(Reference Trichopoulou, Costacou and Bamia15,Reference Sánchez-Villegas, Bes-Rastrollo and Martínez-González26,Reference Fung, Hu and McCullough53,Reference Fung, Hu and Wu82,Reference Steffen, Van Horn and Daviglus90) . The more recent MedD pyramid recommendations also include conviviality(8), as well as rest, culinary activities and sustainable habits(Reference Bach-Faig, Berry and Lairon6). Sustainability has taken on a more central role in the promotion of the MedD pyramid with the inclusion of the ecological impact of the pyramid’s food choices(Reference Serra-Majem, Tomaino and Dernini9). Assessment of these factors of the Mediterranean lifestyle, together with diet and/or dietary lifestyle habits, is sparse but needed to help promote these behaviours as a Mediterranean lifestyle.

The MEDLIFE tool includes the most comprehensive lifestyle assessment. The original MEDLIFE tool publication included both a dietary habits section and lifestyle questions regarding physical activity and sleep from validated surveys(Reference Sotos-Prieto, Moreno-Franco and Ordovás30). In a second MEDLIFE publication applied to a different sample of Spanish adults, two questions were added to the dietary behaviours section: (1) ‘do you prefer and consume seasonal and traditional local products, fresh and minimally processed foods?’ and (2) ‘do you prefer and consume with moderation trying to choose small portion sizes?’; two additional questions in the lifestyle section were also added: (1) ‘how much time do you spend having lunch during weekdays?’ and (2) ‘do you usually eat in company (with family, friends, and colleagues)?’(Reference Sotos-Prieto, Santos-Beneit and Bodega31). This was the first questionnaire to include all aspects of the MedD pyramid’s lifestyle factors; however, these new questions could not be validated in comparison with other assessment tools because no one had ever asked such questions within a dietary survey before. This tool was applied to a working population in Croatia(Reference Pavičić Žeželj, Kenđel Jovanović and Dragaš Zubalj126) and in the Feeding America’s Bravest study of firefighters(Reference Hershey, Sotos-Prieto and Ruiz-Canela127). These studies, unfortunately, did not include the conviviality questions in the total MEDLIFE score. The MEDLIFE scoring system is specifically validated for working adults as the lifestyle questions differentiate between weekend and weekdays and would need modification for application to other populations. The MediCul scoring system included questions on snacking and meals cooked at home(Reference Radd-Vagenas, Fiatarone Singh and Daniel63,Reference Radd-Vagenas, Fiatarone Singh and Inskip64) . MEPA-III included use of pre-packaged meals as a negative factor(Reference Weaver, Goldman and Ribbens100). Finally, lifestyle scores have been included with MedD scoring systems in two other instances in Greek and Italian studies(Reference Anastasiou, Yannakoulia and Kontogianni128Reference Godos, Ferri and Caraci131). While a total score including both lifestyle and diet was not integrated, there were associations between the lifestyle factors and MedD scores.

At this time, there is a gap in knowledge regarding the added health benefit when one or more lifestyle/dietary behaviour components (i.e., conviviality, rest, culinary activities, sustainability habits and physical activity) are incorporated with the food components of the MedD. Moreover, application of these lifestyle/dietary behaviour components, in combination with food components, is grossly lacking in the MedD scoring systems. The assessment of lifestyle practices and dietary habits affiliated with the traditional Mediterranean culture is needed, especially in assessments of younger adults and outside the Mediterranean region(Reference Serra-Majem, Tomaino and Dernini9).

Geographic location and differences in food and food preparation

Agricultural practices, cultivar varieties, food procurement and preparation differ throughout the world and influence the content of nutrients found in key MedD food components(Reference Hoffman and Gerber132). Hoffman & Gerber exposed many issues with application of MedD assessment in a changing Mediterranean region as well as for non-Mediterranean countries(Reference Hoffman and Gerber114). Their review focused on foods, food production and food preparation differences in Mediterranean and non-Mediterranean countries. The geographic and cultural diversity in European countries from the EPIC study demonstrates some of the differences on the continent. In a Greek population, MUFA:SFA ratio is a proxy for olive oil intake; however, animal fat is a more common source of MUFA in the diet from northern EPIC countries(Reference Hoffman and Gerber114). In some updated applications of the T-MDS, the lipid ratio has been replaced by olive oil(Reference Sánchez-Villegas, Bes-Rastrollo and Martínez-González26,Reference Buckland, González and Agudo27) but not others(Reference Fung, Hu and McCullough53,Reference Fung, McCullough and Newby54) . This dietary fat issue was eloquently discussed by deLorgeril who pointed out that SFA are found in many processed foods and the food sources of dietary fats should be considered, not just the lipid ratio and olive oil in order to modernise the MedD concepts for application to cultures and traditions outside the Mediterranean region(Reference Trichopoulou, Martínez-González and Tong4).

Climate differences and seasonality are also a factor. For instance, within the EPIC study, northern countries had lower intakes of raw vegetables compared with the southern Mediterranean countries(Reference Agudo, Slimani and Ocké133). Indeed, a study of young adults in Cyprus and the USA found that the young adults from Cyprus reported seasonality and heat as a driver for intake of more salads and lighter fare(Reference Angastinioti, Zakrajsek and Hutchins-Wiese134). Capturing seasonal differences in dietary data is often a challenge when asking subjects to report recent intake. Some studies have tried to address seasonality in dietary assessment for shorter time frames; the MediCul scoring system included a seasonal intake question, and a novel statistical model was applied to NU-AGE dietary data to account for seasonal variation when using multiple 7-d food records throughout a year-long study(Reference Radd-Vagenas, Fiatarone Singh and Inskip64,Reference Giampieri, Ostan and Guidarelli135) .

Traditional diets and food preparation techniques from areas outside the Mediterranean basin also add complexity for application of assessment tools and defining MedD adherence. The traditional diet in Asian countries has some similarities in food group consumption with the emphasis on vegetables, legumes and non-refined grains. However, foods that are included within food group categories and food preparation and cooking techniques differ greatly. Soyabeans were not originally included as a food component of the MedD(Reference Martínez-González, Hershey and Zazpe119). However, soyabeans are the most commonly consumed legume in Asian countries and were included in the Japanese MedD scoring system’s legumes food group (tofu, fermented soyabeans and miso)(Reference Kanauchi and Kanauchi74). The nutritional components of soya differ from other legumes in that soya products have high levels of isoflavones(Reference Messina136) and would not be considered a key nutrient of traditional legumes in a MedD, but for cultural adaptation purposes maybe considered in an Asian, Mediterranean-Like Diet Pattern. An early adaptation of a MedD intervention was the ‘Indo-MedD’ in which the recommended fat sources were walnuts, almonds, mustard seed and/or soyabean oil(Reference Singh, Dubnov and Niaz137). This study did not apply a MedD scoring system and has been specifically identified by some as a non-MedD intervention due to the use of mustard seed and soyabean oil rather than olive oil(Reference Martínez-González, Hershey and Zazpe119). While the exclusion of foods outside of the Mediterranean basin will limit the applicability of this dietary pattern for cultures outside of this region, some basic features of the diet, i.e., olive oil as the principle fat used in cooking and food preparation or MUFA:SFA ratios need be preserved. Due to these differences, it may be more appropriate to think about both foods and nutrients. Future research is needed to identify the essential key nutrients and level of nutrient pattern(s) that reproduce the cardiometabolic benefits observed with the traditional MedD.

Other regions of the world, such as the agricultural areas of Chile, California, south-western Australia and South Africa have similarities with the Mediterranean basin ecosystem(Reference Echeverría, Dussaillant and McGee79). Cross-national studies that evaluate foods consumed, food preparation and cooking practices, and biomarkers of intake with MedD scoring systems and health outcomes are needed to better understand similarities and differences in traditional and modernised dietary behaviours in areas of the world known for longevity and for having similarities to Mediterranean climate and agriculture.

Clinical application

Time required for administration is an important consideration when choosing assessment tools for use in clinical practice. Of the possible MedD scoring system options, MEDAS is the most attractive for clinical use due to its short length overall, direct questions and easy scoring. Recently, the MEDAS was adopted and validated for use in a clinical rehabilitation unit with the addition of images to define serving sizes and food items(Reference Ghisi, Mahajan and da Silva Chaves41). MEDAS is designed as a rapid MedD screening tool; other scoring systems with finer grading of points are helpful in intervention studies and clinical monitoring to account for partial adoption of food behaviours.

There are a few examples of graded scoring systems from Mediterranean and non-Mediterranean countries. The MedDietScale and QueMD have the widest pre-defined component scales (0–5 for each food/food group)(Reference Panagiotakos, Pitsavos and Arvaniti24,Reference Gnagnarella, Dragà and Misotti46) . The wider range of scoring allows for more discrete differentiation between intakes and has been applied to several MedD intervention trials in the USA(Reference Sanchez-Flack, Tussing-Humphreys and Lamar87,Reference Bihuniak, Ramos and Huedo-Medina115,Reference Tangney, Kwasny and Li138) . The Chilean MedD score has graded points with a possible total score of 14(Reference Leighton, Polic and Strobel77,Reference Echeverría, McGee and Urquiaga78) . In the USA, a 0–4 point system for food groups/behaviours has been successfully applied to assess firefighter intakes and adherence to a MedD intervention(Reference Yang, Farioli and Korre96,Reference Sotos-Prieto, Christophi and Black97,Reference Sotos-Prieto, Cash and Christophi118) . Two scores from Europe use continuous scaling. The PyrMDS is scaled continuously 0–1 for fifteen food items, while NU-AGE is also continuously scaled (0–10) for sixteen food items(Reference Tong, Wareham and Khaw56,Reference Jennings, Berendsen and de Groot57) . This continuous scaling limits rapid assessment in a clinic setting but has potential if online software becomes available for feedback in real time. Last, the MediCul scoring system is validated for use in Australian older adults with chronic conditions, but the length of the survey (fifty questions and approximately 20 min to complete) is often too long in a clinical office setting. This survey could be completed prior to a clinic visit when the web-based version is used(Reference Radd-Vagenas, Fiatarone Singh and Daniel63).

Challenges and opportunities for application of Mediterranean diet scoring systems

Assessment methodology, cultural and lifestyle factors need to be considered when applying MedD scoring systems. Understanding the impact of MedD adherence in a variety of research and geographical settings is essential to this field. Observational cohort findings from long-term, real-life application of dietary adherence cannot be recreated in a randomised controlled trial but add to this body of literature(Reference Blumberg, Heaney and Huncharek139). The importance of randomised controlled trial in varying geographic locations is to understand the health implications when changing the diet to a Mediterranean-Like Diet Pattern. Countries outside of the Mediterranean basin have challenges in acceptability of Mediterranean style food practices that were not an issue for the groundbreaking PREDIMED study. Therefore, feasibility and acceptability studies, with application of appropriate MedD scoring systems, are warranted first steps when conducting MedD trials in non-Mediterranean countries.

A number of other reviews have made recommendations to advance the field(Reference Davis, Bryan and Hodgson5,Reference Hernández-Ruiz, García-Villanova and Guerra Hernández18,Reference Zaragoza-Martí, Cabañero-Martínez and Hurtado-Sánchez20,Reference Olmedo-Requena, González-Donquiles and Dávila-Batista110) . Conformity in defining the food and food groups or nutrients included in a universal MedD scoring system has been emphasised(Reference Olmedo-Requena, González-Donquiles and Dávila-Batista110); the challenge is considering the population of interest. Nomenclature may help with applying concepts of the MedD to other areas of the world. Use of the terms ‘MedD style’ or ‘Mediterranean Like Diet’ patterns when describing assessment or interventions may better capture some of the factors that need to be considered when applying MedD scoring systems and interventions to non-Mediterranean countries. Wider application of some of the more recent scoring systems in the literature as well as comparisons between scoring systems is needed to better understand differences and similarities in traditional and modern MedD intakes from Mediterranean and non-Mediterranean countries.

In the midst of a pandemic, with obesity being at its highest levels in history, energetic excess also needs to be considered. The application of the T-MDS with limited food components and use of median intakes where energetic excess is commonplace does not adequately capture dietary intake. The need for a priori cut-offs and definitions that are in accordance with foods and nutrients of the MedD was emphasised by others as well(Reference Davis, Bryan and Hodgson5,Reference Hernández-Ruiz, García-Villanova and Guerra Hernández18,Reference Zaragoza-Martí, Cabañero-Martínez and Hurtado-Sánchez20,Reference Olmedo-Requena, González-Donquiles and Dávila-Batista110) . Therefore, increased use of MedD scoring systems that account for non-traditional MedD foods as negative components, serving size restrictions, total diet energy density and/or overconsumption is needed to fully capture modern MedD and disease relationships. Additionally, understanding what ideal nutrient profiles (i.e. fibre, phytonutrients) that can elicit a metabolic effect similar to those found from traditional MedD studies will be helpful in identifying the most appropriate scoring system for wide scale use. Reframing the MedD as a concept(Reference Trichopoulou, Martínez-González and Tong4) of healthy eating and lifestyle/dietary behaviours is an opportunity which can be applied to anyone from any culture or region of the world.

Conclusions

This review highlighted the evolution of MedD scoring systems developed for use in Mediterranean countries as well as the evolution of scoring systems (either modified or new) for use in non-Mediterranean countries. The evolution reflects the emergence of MedD pyramid recommendations and inclusion of non-typical MedD foods to capture the nutrition transition observed in Mediterranean countries and for populations outside of the Mediterranean region.

While the evolution of MedD scoring systems may improve MedD adherence measurement for a specific population, we do not have a consensus to identify MedD adherence across countries and regions. This is largely due to the lack of consensus on an absolute definition of the MedD(Reference Davis, Bryan and Hodgson5) and the need to consider ‘Mediterranean Like Dietary Patterns’ when referring to interventions and degrees of adherence outside of the Mediterranean region, especially in cultures with vastly different foods, food preparation and cooking practices. In 2020, the MedD Pyramid was updated and, for the first time, revisions addressed the use of the MedD outside of the Mediterranean regions(Reference Serra-Majem, Tomaino and Dernini9). The new guidelines suggest that the basic MedD Pyramid recommendations should be used as a guide and countries adapt the MedD Pyramid to their ‘country-specific contexts and cuisines’(Reference Serra-Majem, Tomaino and Dernini9). We believe this is the first step to identifying the key basic food components that should be included in MedD scoring systems. To move the field forward, agreement to key food components is essential. In Table 6, the numerous components currently included in the MedD scoring systems are presented and, using the updated MedD pyramid, highlight the key food components of the MedD and bring awareness to the components that require more clarity and additional study.

Table 6. Key and uncertain components

* Portion = Serving or portion size based on frugality and local habits. MDP MedD Pyramid.

Moving forward, the research on application of MedD scoring systems needs to capture intake of foods that are not part of the MedD, uncertain MedD components, as well as traditional MedD foods and dietary/lifestyle behaviours. The newer scoring systems that reflect the most recent MedD pyramid recommendations(Reference Bach-Faig, Berry and Lairon6,Reference Serra-Majem, Tomaino and Dernini9) such as the MDSS(Reference Monteagudo, Mariscal-Arcas and Rivas29), MEDLIFE(Reference Sotos-Prieto, Santos-Beneit and Bodega31) and PyrMDS(Reference Tong, Wareham and Khaw56) as well as the more widely validated MEDAS may prove greater utility in identifying true intake from a variety of cultures, as it relates to a Mediterranean-Like Dietary Pattern. Ideally, there should be a simple format for use in epidemiological and intervention trials, as well as for clinical practice. However, the likelihood that one scoring system will meet all needs is unrealistic. We will continue to see the use of a number of different scoring systems. Future systematic reviews should consider the source of MedD data, country of origin and usual dietary practices when making cross-cultural assessments for MedD and health outcomes. We recommend striving for agreement on the number food groups to include, how they are measured and the dietary behaviours and lifestyle factors to include. This approach will improve epidemiological research favouring comparisons across cultures and geographic regions and further next steps in advancing our understanding of MedD and disease relationships.

Acknowledgements

None.

This work was supported by the US Department of Veterans Affairs Rehabilitation Research and Development Service Program (IK2 RX002348 to K. N. P. S.; I01 RX002843 to C. W. B.).

H. L. H. W. conceptualised, wrote and edited the manuscript. C. W. B. supported conceptualisation and provided significant and meaningful edits to the manuscript. K. N. P. S. supported conceptualisation and provided equal, significant and meaningful edits to the manuscript.

The authors have no conflicts of interest to report.

References

Schulze, MB & Hu, FB (2002) Dietary patterns and risk of hypertension, type 2 diabetes mellitus, and coronary heart disease. Curr Atheroscler Rep 4, 462467.CrossRefGoogle ScholarPubMed
Keys, A, Aravanis, C, Blackburn, H, et al. (1980) Seven Countries. A Multivariate Analysis of Death and Coronary Heart Disease. Cambridge, MA: Harvard University Press.CrossRefGoogle Scholar
Dinu, M, Pagliai, G, Casini, A, et al. (2018) Mediterranean diet and multiple health outcomes: an umbrella review of meta-analyses of observational studies and randomised trials. Eur J Clin Nutr 72, 3043.CrossRefGoogle ScholarPubMed
Trichopoulou, A, Martínez-González, MA, Tong, TY, et al. (2014) Definitions and potential health benefits of the Mediterranean diet: views from experts around the world. BMC Med 12, 112.CrossRefGoogle ScholarPubMed
Davis, C, Bryan, J, Hodgson, J, et al. (2015) Definition of the Mediterranean Diet; a literature review. Nutrients 7, 91399153.CrossRefGoogle ScholarPubMed
Bach-Faig, A, Berry, EM, Lairon, D, et al. (2011) Mediterranean diet pyramid today. Science and cultural updates. Public Health Nutr 14, 22742284.CrossRefGoogle ScholarPubMed
Ministry of Health and Welfare, Supreme Scientific Health Council (1999) Dietary guidelines for adults in Greece. Arch Hell Med 16, 516524.Google Scholar
Oldways Cultural Food Traditions (2009) Oldways Mediterranean Diet Pyramid. https://oldwayspt.org/resources/oldways-mediterranean-diet-pyramid (accessed April 2021).Google Scholar
Serra-Majem, L, Tomaino, L, Dernini, S, et al. (2020) Updating the Mediterranean Diet pyramid towards sustainability: focus on environmental concerns. Int J Environ Res Public Health 17, 8758.CrossRefGoogle ScholarPubMed
Willett, WC, Sacks, F, Trichopoulou, A, et al. (1995) Mediterranean diet pyramid: a cultural model for healthy eating. Am J Clin Nutr 61, 1402S1406S.CrossRefGoogle ScholarPubMed
Dernini, S, Berry, EM, Serra-Majem, L, et al. (2017) Med Diet 4.0: the Mediterranean diet with four sustainable benefits. Public Health Nutr 20, 13221330.CrossRefGoogle ScholarPubMed
UNESCO (2013) Mediterranean Diet. Cyprus, Croatia, Spain, Greece, Italy, Morocco and Portugal Inscribed in 2013 on the Representative List of the Intangible Cultural Heritage of Humanity. https://ich.unesco.org/en/RL/mediterranean-diet-00884 (accessed April 2021).Google Scholar
de Groot, LC, van Staveren, WA & Burema, J (1996) Survival beyond age 70 in relation to diet. Nutr Rev 54, 211212.CrossRefGoogle ScholarPubMed
Gardener, H, Wright, CB, Gu, Y, et al. (2011) Mediterranean-style diet and risk of ischemic stroke, myocardial infarction, and vascular death: the Northern Manhattan Study. Am J Clin Nutr 94, 14581464.CrossRefGoogle ScholarPubMed
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.CrossRefGoogle Scholar
Zappalà, G, Buscemi, S, Mulè, S, et al. (2018) High adherence to Mediterranean diet, but not individual foods or nutrients, is associated with lower likelihood of being obese in a Mediterranean cohort. Eat Weight Disord EWD 23, 605614.CrossRefGoogle Scholar
Zaslavsky, O, Zelber-Sagi, S, Shikany, JM, et al. (2018) Anatomy of the Mediterranean Diet and mortality among older women with frailty. J Nutr Gerontol Geriatr 37, 269281.CrossRefGoogle ScholarPubMed
Hernández-Ruiz, A, García-Villanova, B, Guerra Hernández, EJ, et al. (2015) Description of indexes based on the adherence to the mediterranean dietary pattern: a review. Nutr Hosp 32, 18721884.Google Scholar
Waijers, PMCM, Feskens, EJM & Ocké, MC (2007) A critical review of predefined diet quality scores. Br J Nutr 97, 219231.CrossRefGoogle ScholarPubMed
Zaragoza-Martí, A, Cabañero-Martínez, MJ, Hurtado-Sánchez, JA, et al. (2018) Evaluation of Mediterranean diet adherence scores: a systematic review. BMJ Open 8, e019033.CrossRefGoogle ScholarPubMed
Trichopoulou, A, Kouris-Blazos, A, Wahlqvist, ML, et al. (1995) Diet and overall survival in elderly people. BMJ 311, 14571460.CrossRefGoogle ScholarPubMed
Trichopoulou, A, Orfanos, P, Norat, T, et al. (2005) Modified Mediterranean diet and survival: EPIC-elderly prospective cohort study. BMJ 330, 991.CrossRefGoogle ScholarPubMed
Panagiotakos, DB, Pitsavos, C & Stefanadis, C (2006) Dietary patterns: a Mediterranean diet score and its relation to clinical and biological markers of cardiovascular disease risk. Nutr Metab Cardiovasc Dis 16, 559568.CrossRefGoogle ScholarPubMed
Panagiotakos, DB, Pitsavos, C, Arvaniti, F, et al. (2007) Adherence to the Mediterranean food pattern predicts the prevalence of hypertension, hypercholesterolemia, diabetes and obesity, among healthy adults; the accuracy of the MedDietScore. Prev Med 44, 335340.CrossRefGoogle Scholar
Benítez-Arciniega, AA, Mendez, MA, Baena-Díez, JM, et al. (2011) Concurrent and construct validity of Mediterranean diet scores as assessed by an FFQ. Public Health Nutr 14, 20152021.CrossRefGoogle ScholarPubMed
Sánchez-Villegas, A, Bes-Rastrollo, M, Martínez-González, MA, et al. (2006) Adherence to a Mediterranean dietary pattern and weight gain in a follow-up study: the SUN cohort. Int J Obes 30, 350358.CrossRefGoogle Scholar
Buckland, G, González, CA, Agudo, A, et al. (2009) Adherence to the Mediterranean diet and risk of coronary heart disease in the Spanish EPIC Cohort Study. Am J Epidemiol 170, 15181529.CrossRefGoogle Scholar
Schröder, H, Marrugat, J, Vila, J, et al. (2004) Adherence to the traditional mediterranean diet is inversely associated with body mass index and obesity in a spanish population. J Nutr 134, 33553361.CrossRefGoogle Scholar
Monteagudo, C, Mariscal-Arcas, M, Rivas, A, et al. (2015) Proposal of a Mediterranean Diet serving score. PLoS One 10, e0128594.CrossRefGoogle ScholarPubMed
Sotos-Prieto, M, Moreno-Franco, B, Ordovás, JM, et al. (2015) Design and development of an instrument to measure overall lifestyle habits for epidemiological research: the Mediterranean Lifestyle (MEDLIFE) index. Public Health Nutr 18, 959967.CrossRefGoogle ScholarPubMed
Sotos-Prieto, M, Santos-Beneit, G, Bodega, P, et al. (2015) Validation of a questionnaire to measure overall Mediterranean lifestyle habits for research application: the MEDiterranean LIFEstyle index (MEDLIFE). Nutr Hosp 32, 11531163.Google ScholarPubMed
Schröder, H, Fitó, M, Estruch, R, et al. (2011) A short screener is valid for assessing Mediterranean Diet adherence among older Spanish men and women. J Nutr 141, 11401145.CrossRefGoogle Scholar
Hebestreit, K, Yahiaoui-Doktor, M, Engel, C, et al. (2017) Validation of the German version of the Mediterranean Diet Adherence Screener (MEDAS) questionnaire. BMC Cancer 17, 341.CrossRefGoogle ScholarPubMed
Papadaki, A, Johnson, L, Toumpakari, Z, et al. (2018) Validation of the english version of the 14-Item Mediterranean Diet Adherence Screener of the PREDIMED Study, in people at high cardiovascular risk in the UK. Nutrients 10, 138.CrossRefGoogle ScholarPubMed
Gregório, MJ, Rodrigues, AM, Salvador, C, et al. (2020) Validation of the telephone-administered version of the Mediterranean Diet Adherence Screener (MEDAS) questionnaire. Nutrients 12, 1511.CrossRefGoogle ScholarPubMed
García-Conesa, M-T, Philippou, E, Pafilas, C, et al. (2020) Exploring the validity of the 14-item Mediterranean Diet Adherence Screener (MEDAS): a cross-national study in seven European countries around the Mediterranean region. Nutrients 12, 2960.CrossRefGoogle ScholarPubMed
Parletta, N, Zarnowiecki, D, Cho, J, et al. (2019) A Mediterranean-style dietary intervention supplemented with fish oil improves diet quality and mental health in people with depression: a randomized controlled trial (HELFIMED). Nutr Neurosci 22, 474487.CrossRefGoogle ScholarPubMed
Abu-Saad, K, Endevelt, R, Goldsmith, R, et al. (2019) Adaptation and predictive utility of a Mediterranean diet screener score. Clin Nutr Edinb Scotl 38, 29282935.CrossRefGoogle ScholarPubMed
Kwon, Y-J, Lee, H, Yoon, Y, et al. (2020) Development and validation of a questionnaire to measure adherence to the Mediterranean Diet in Korean Adults. Nutrients 12, 1102.CrossRefGoogle Scholar
Vieira, LM, Gottschall, CBA, Vinholes, DB, et al. (2020) Translation and cross-cultural adaptation of 14-item Mediterranean Diet Adherence Screener and low-fat diet adherence questionnaire. Clin Nutr ESPEN 39, 180189.CrossRefGoogle ScholarPubMed
Ghisi, GL, Mahajan, A, da Silva Chaves, GS, et al. (2019) Validation of a self-administered version of the Mediterranean diet scale (MDS) for cardiac rehabilitation patients in Canada. Int J Food Sci Nutr 70, 202211.CrossRefGoogle ScholarPubMed
Bottcher, MR, Marincic, PZ, Nahay, KL, et al. (2017) Nutrition knowledge and Mediterranean diet adherence in the southeast United States: validation of a field-based survey instrument. Appetite 111, 166176.CrossRefGoogle ScholarPubMed
Li, J, Guasch-Ferré, M, Chung, W, et al. (2020) The Mediterranean diet, plasma metabolome, and cardiovascular disease risk. Eur Heart J 41, 26452656.CrossRefGoogle ScholarPubMed
Agnoli, C, Krogh, V, Grioni, S, et al. (2011) A priori-defined dietary patterns are associated with reduced risk of stroke in a large Italian cohort. J Nutr 141, 15521558.CrossRefGoogle Scholar
Zito, FP, Polese, B, Vozzella, L, et al. (2016) Good adherence to Mediterranean diet can prevent gastrointestinal symptoms: a survey from Southern Italy. World J Gastrointest Pharmacol Ther 7, 564571.CrossRefGoogle ScholarPubMed
Gnagnarella, P, Dragà, D, Misotti, AM, et al. (2018) Validation of a short questionnaire to record adherence to the Mediterranean diet: an Italian experience. Nutr Metab Cardiovasc Dis NMCD 28, 11401147.CrossRefGoogle Scholar
Vitale, M, Racca, E, Izzo, A, et al. (2019) Adherence to the traditional Mediterranean diet in a population of South of Italy: factors involved and proposal of an educational field-based survey tool. Int J Food Sci Nutr 70, 195201.CrossRefGoogle Scholar
Naja, F, Hwalla, N, Itani, L, et al. (2015) A novel Mediterranean diet index from Lebanon: comparison with Europe. Eur J Nutr 54, 12291243.CrossRefGoogle ScholarPubMed
El Kinany, K, Mint Sidi Deoula, M, Hatime, Z, et al. (2020) Modified Mediterranean diet score adapted to a southern Mediterranean population and its relation to overweight and obesity risk. Public Health Nutr 1–7 (Epublication ahead of print version 29 July 2020).Google Scholar
Sofi, F, Abbate, R, Gensini, GF, et al. (2012) Identification of change-points in the relationship between food groups in the Mediterranean diet and overall mortality: an ‘a posteriori’ approach. Eur J Nutr 51, 167172.CrossRefGoogle ScholarPubMed
Sofi, F, Macchi, C, Abbate, R, et al. (2014) Mediterranean diet and health status: an updated meta-analysis and a proposal for a literature-based adherence score. Public Health Nutr 17, 27692782.CrossRefGoogle Scholar
Sofi, F, Dinu, M, Pagliai, G, et al. (2017) Validation of a literature-based adherence score to Mediterranean diet: the MEDI-LITE score. Int J Food Sci Nutr 68, 757762.CrossRefGoogle ScholarPubMed
Fung, TT, Hu, FB, McCullough, ML, et al. (2006) Diet quality is associated with the risk of estrogen receptor-negative breast cancer in postmenopausal women. J Nutr 136, 466472.CrossRefGoogle ScholarPubMed
Fung, TT, McCullough, ML, Newby, PK, et al. (2005) Diet-quality scores and plasma concentrations of markers of inflammation and endothelial dysfunction. Am J Clin Nutr 82, 163173.CrossRefGoogle Scholar
Stefler, D, Malyutina, S, Kubinova, R, et al. (2017) Mediterranean diet score and total and cardiovascular mortality in Eastern Europe: the HAPIEE study. Eur J Nutr 56, 421429.CrossRefGoogle ScholarPubMed
Tong, TYN, Wareham, NJ, Khaw, K-T, et al. (2016) Prospective association of the Mediterranean diet with cardiovascular disease incidence and mortality and its population impact in a non-Mediterranean population: the EPIC-Norfolk study. BMC Med 14, 135.CrossRefGoogle Scholar
Jennings, A, Berendsen, AM, de Groot, LCPGM, et al. (2019) Mediterranean-Style diet improves systolic blood pressure and arterial stiffness in older adults. Hypertension 73, 578586.CrossRefGoogle ScholarPubMed
Berendsen, A, Santoro, A, Pini, E, et al. (2014) Reprint of: a parallel randomized trial on the effect of a healthful diet on inflammageing and its consequences in European elderly people: design of the NU-AGE dietary intervention study. Mech Ageing Dev 136, 1421.CrossRefGoogle ScholarPubMed
McCullough, ML, Feskanich, D, Stampfer, MJ, et al. (2002) Diet quality and major chronic disease risk in men and women: moving toward improved dietary guidance. Am J Clin Nutr 76, 12611271.CrossRefGoogle ScholarPubMed
Kouris-Blazos, A, Gnardellis, C, Wahlqvist, ML, et al. (1999) Are the advantages of the Mediterranean diet transferable to other populations? A cohort study in Melbourne, Australia. Br J Nutr 82, 5761.CrossRefGoogle ScholarPubMed
Hodge, AM, English, DR, Itsiopoulos, C, et al. (2011) Does a Mediterranean diet reduce the mortality risk associated with diabetes: evidence from the Melbourne Collaborative Cohort Study. Nutr Metab Cardiovasc Dis NMCD 21, 733739.CrossRefGoogle ScholarPubMed
Davis, CR, Hodgson, JM, Woodman, R, et al. (2017) A Mediterranean diet lowers blood pressure and improves endothelial function: results from the MedLey randomized intervention trial. Am J Clin Nutr 105, 13051313.CrossRefGoogle ScholarPubMed
Radd-Vagenas, S, Fiatarone Singh, MA, Daniel, K, et al. (2018) Validity of the Mediterranean Diet and Culinary Index (MediCul) for online assessment of adherence to the ‘traditional’ diet and aspects of cuisine in older adults. Nutrients 10, 1913.CrossRefGoogle Scholar
Radd-Vagenas, S, Fiatarone Singh, MA, Inskip, M, et al. (2018) Reliability and validity of a Mediterranean diet and culinary index (MediCul) tool in an older population with mild cognitive impairment. Br J Nutr 120, 11891200.CrossRefGoogle Scholar
Woo, J, Woo, KS, Leung, SS, et al. (2001) The Mediterranean score of dietary habits in Chinese populations in four different geographical areas. Eur J Clin Nutr 55, 215220.CrossRefGoogle ScholarPubMed
Chan, R, Chan, D & Woo, J (2013) The association of a priori and a posterior dietary patterns with the risk of incident stroke in Chinese older people in Hong Kong. J Nutr Health Aging 17, 866874.CrossRefGoogle Scholar
Chen, G-C, Koh, W-P, Neelakantan, N, et al. (2018) Diet quality indices and risk of type 2 diabetes mellitus: the Singapore Chinese Health Study. Am J Epidemiol 187, 26512661.CrossRefGoogle ScholarPubMed
Neelakantan, N, Koh, W-P, Yuan, J-M, et al. (2018) Diet-Quality indexes are associated with a lower risk of cardiovascular, respiratory, and all-cause mortality among Chinese adults. J Nutr 148, 13231332.CrossRefGoogle ScholarPubMed
Wang, C, Lin, X-L, Fan, Y-Y, et al. (2016) Diet quality scores and risk of nasopharyngeal carcinoma in Chinese adults: a case-control study. Nutrients 8, 112.CrossRefGoogle ScholarPubMed
Wu, J, Song, X, Chen, G-C, et al. (2019) Dietary pattern in midlife and cognitive impairment in late life: a prospective study in Chinese adults. Am J Clin Nutr 110, 912920.CrossRefGoogle ScholarPubMed
Kim, Y & Je, Y (2018) A modified Mediterranean diet score is inversely associated with metabolic syndrome in Korean adults. Eur J Clin Nutr 72, 16821689.CrossRefGoogle ScholarPubMed
Willcox, DC, Scapagnini, G & Willcox, BJ (2014) Healthy aging diets other than the Mediterranean: a focus on the Okinawan diet. Mech Ageing Dev 136, 148162.CrossRefGoogle Scholar
Murakami, K, Livingstone, MBE & Sasaki, S (2019) Diet quality scores in relation to metabolic risk factors in Japanese adults: a cross-sectional analysis from the 2012 National Health and Nutrition Survey, Japan. Eur J Nutr 58, 20372050.CrossRefGoogle ScholarPubMed
Kanauchi, M & Kanauchi, K (2016) Development of a Mediterranean diet score adapted to Japan and its relation to obesity risk. Food Nutr Res 60, 32172.CrossRefGoogle ScholarPubMed
Sahrai, MS, Huybrechts, I, Biessy, C, et al. (2019) Association of a priori-defined dietary patterns with anthropometric measurements: a cross-sectional study in Mexican Women. Nutrients 11, 603.CrossRefGoogle ScholarPubMed
Wu, AH, Yu, MC, Tseng, C-C, et al. (2009) Dietary patterns and breast cancer risk in Asian American women. Am J Clin Nutr 89, 11451154.CrossRefGoogle ScholarPubMed
Leighton, F, Polic, G, Strobel, P, et al. (2009) Health impact of Mediterranean diets in food at work. Public Health Nutr 12, 16351643.CrossRefGoogle ScholarPubMed
Echeverría, G, McGee, EE, Urquiaga, I, et al. (2017) Inverse associations between a locally validated mediterranean diet index, overweight/obesity, and metabolic syndrome in Chilean adults. Nutrients 9, 862.CrossRefGoogle ScholarPubMed
Echeverría, G, Dussaillant, C, McGee, EE, et al. (2019) Promoting and implementing the Mediterranean Diet in the Southern Hemisphere: the Chilean Experience. Eur J Clin Nutr 72, 3846.CrossRefGoogle ScholarPubMed
Goulet, J, Lamarche, B, Nadeau, G, et al. (2003) Effect of a nutritional intervention promoting the Mediterranean food pattern on plasma lipids, lipoproteins and body weight in healthy French-Canadian women. Atherosclerosis 170, 115124.CrossRefGoogle ScholarPubMed
Fung, TT, Rexrode, KM, Mantzoros, CS, et al. (2009) Mediterranean diet and incidence of and mortality from coronary heart disease and stroke in women. Circulation 119, 10931100.CrossRefGoogle ScholarPubMed
Fung, TT, Hu, FB, Wu, K, et al. (2010) The Mediterranean and Dietary Approaches to Stop Hypertension (DASH) diets and colorectal cancer. Am J Clin Nutr 92, 14291435.CrossRefGoogle ScholarPubMed
Lopez-Garcia, E, Rodriguez-Artalejo, F, Li, TY, et al. (2014) The Mediterranean-style dietary pattern and mortality among men and women with cardiovascular disease. Am J Clin Nutr 99, 172180.CrossRefGoogle ScholarPubMed
Zheng, X, Hur, J, Nguyen, LH, et al. (2021) Comprehe nsive assessment of diet quality and risk of precursors of early-onset colorectal cancer. J Natl Cancer Inst 113, 543552.CrossRefGoogle Scholar
Bienias, JL, Beckett, LA, Bennett, DA, et al. (2003) Design of the Chicago Health and Aging Project (CHAP). J Alzheimers Dis JAD 5, 349355.CrossRefGoogle ScholarPubMed
Tangney, CC, Li, H, Wang, Y, et al. (2014) Relation of DASH- and Mediterranean-like dietary patterns to cognitive decline in older persons. Neurology 83, 14101416.CrossRefGoogle ScholarPubMed
Sanchez-Flack, JC, Tussing-Humphreys, L, Lamar, M, et al. (2021) Building research in diet and cognition (BRIDGE): baseline characteristics of older obese African American adults in a randomized controlled trial to examine the effect of the Mediterranean diet with and without weight loss on cognitive functioning. Prev Med Rep 22, 101302.CrossRefGoogle Scholar
Mattei, J, Sotos-Prieto, M, Bigornia, SJ, et al. (2017) The Mediterranean diet score is more strongly associated with favorable cardiometabolic risk factors over 2 years than other diet quality indexes in Puerto Rican adults. J Nutr 147, 661669.CrossRefGoogle ScholarPubMed
Levitan, EB, Ahmed, A, Arnett, DK, et al. (2016) Mediterranean diet score and left ventricular structure and function: the Multi-Ethnic Study of Atherosclerosis. Am J Clin Nutr 104, 595602.CrossRefGoogle ScholarPubMed
Steffen, LM, Van Horn, L, Daviglus, ML, et al. (2014) A modified Mediterranean diet score is associated with a lower risk of incident metabolic syndrome over 25 years among young adults: the CARDIA (Coronary Artery Risk Development in Young Adults) study. Br J Nutr 112, 16541661.CrossRefGoogle ScholarPubMed
McEvoy, CT, Hoang, T, Sidney, S, et al. (2019) Dietary patterns during adulthood and cognitive performance in midlife: the CARDIA study. Neurology 92, e1589e1599.CrossRefGoogle ScholarPubMed
Sotos-Prieto, M & Mattei, J (2018) Mediterranean Diet and cardiometabolic diseases in racial/ethnic minority populations in the United States. Nutrients 10, 352.CrossRefGoogle ScholarPubMed
Rumawas, ME, Dwyer, JT, McKeown, NM, et al. (2009) The development of the Mediterranean-style dietary pattern score and its application to the American diet in the Framingham offspring cohort. J Nutr 139, 11501156.CrossRefGoogle Scholar
Jessri, M, Rashidkhani, B, Hajizadeh, B, et al. (2012) Adherence to Mediterranean-Style dietary pattern and risk of esophageal squamous cell carcinoma: a case-control study in Iran. J Am Coll Nutr 31, 338351.CrossRefGoogle ScholarPubMed
Rumawas, ME, Meigs, JB, Dwyer, JT, et al. (2009) Mediterranean-Style dietary pattern, reduced risk of metabolic syndrome traits, and incidence in the Framingham offspring cohort. Am J Clin Nutr 90, 16081614.CrossRefGoogle ScholarPubMed
Yang, J, Farioli, A, Korre, M, et al. (2014) Modified Mediterranean diet score and cardiovascular risk in a North American working population. PLoS One 9, e87539.CrossRefGoogle Scholar
Sotos-Prieto, M, Christophi, C, Black, A, et al. (2019) Assessing validity of self-reported dietary intake within a mediterranean diet cluster randomized controlled trial among US firefighters. Nutrients 11, 2250.CrossRefGoogle ScholarPubMed
Lan, F-Y, Fernandez-Montero, A, Yiannakou, I, et al. (2020) A Mediterranean lifestyle is associated with lower hypertension prevalence and better aerobic capacity among new England firefighter recruits. J Occup Environ Med 62, 466471.CrossRefGoogle ScholarPubMed
Cerwinske, LA, Rasmussen, HE, Lipson, S, et al. (2017) Evaluation of a dietary screener: the Mediterranean Eating Pattern for Americans tool. J Hum Nutr Diet Off J Br Diet Assoc 30, 596603.CrossRefGoogle ScholarPubMed
Weaver, KE, Goldman, JG, Ribbens, N, et al. (2020) Validation of an online screener, the Mediterranean eating pattern for Americans-III in older patients with Parkinson’s disease. J Nutr Gerontol Geriatr 39, 3043.CrossRefGoogle ScholarPubMed
Ribbens, N, Rasmussen, HE, Goldman, JG, et al. (2020) Acceptability and reliability of the paper and online versions of the MEPA-III screener. J Hum Nutr 4, 8086.Google Scholar
Benhammou, S, Heras-González, L, Ibáñez-Peinado, D, et al. (2016) Comparison of Mediterranean diet compliance between European and non-European populations in the Mediterranean basin. Appetite 107, 521526.CrossRefGoogle ScholarPubMed
Murphy, KJ & Parletta, N (2018) Implementing a Mediterranean-Style diet outside the Mediterranean region. Curr Atheroscler Rep 20, 28.CrossRefGoogle ScholarPubMed
Martínez-González, MA, Fernández-Jarne, E, Serrano-Martínez, M, et al. (2004) Development of a short dietary intake questionnaire for the quantitative estimation of adherence to a cardioprotective Mediterranean diet. Eur J Clin Nutr 58, 15501552.CrossRefGoogle Scholar
Martínez-González, MA, Fernández-Jarne, E, Serrano-Martínez, M, et al. (2002) Mediterranean diet and reduction in the risk of a first acute myocardial infarction: an operational healthy dietary score. Eur J Nutr 41, 153160.CrossRefGoogle ScholarPubMed
Aoun, C, Bou Daher, R, El Osta, N, et al. (2019) Reproducibility and relative validity of a food frequency questionnaire to assess dietary intake of adults living in a Mediterranean country. PLoS One 14, e0218541.CrossRefGoogle Scholar
Gerber, M (2006) Qualitative methods to evaluate Mediterranean diet in adults. Public Health Nutr 9, 147151.CrossRefGoogle ScholarPubMed
Bamia, C, Martimianaki, G, Kritikou, M, et al. (2017) Indexes for assessing adherence to a Mediterranean Diet from data measured through brief questionnaires: issues raised from the analysis of a Greek Population Study. Curr Dev Nutr 1, e000075.CrossRefGoogle ScholarPubMed
Milà-Villarroel, R, Bach-Faig, A, Puig, J, et al. (2011) Comparison and evaluation of the reliability of indexes of adherence to the Mediterranean diet. Public Health Nutr 14, 23382345.CrossRefGoogle ScholarPubMed
Olmedo-Requena, R, González-Donquiles, C, Dávila-Batista, V, et al. (2019) Agreement among Mediterranean Diet pattern adherence indexes: MCC-Spain Study. Nutrients 11, 488.CrossRefGoogle ScholarPubMed
Brown, D (2006) Do food frequency questionnaires have too many limitations? J Am Diet Assoc 106, 15411542.CrossRefGoogle ScholarPubMed
Willett, W (1987) Nutritional epidemiology: issues and challenges. Int J Epidemiol 16, 312317.CrossRefGoogle ScholarPubMed
Willett, WC, Howe, GR & Kushi, LH (1997) Adjustment for total energy intake in epidemiologic studies. Am J Clin Nutr 65, 1220S1228S.CrossRefGoogle ScholarPubMed
Hoffman, R & Gerber, M (2013) Evaluating and adapting the Mediterranean diet for non-Mediterranean populations: a critical appraisal. Nutr Rev 71, 573584.CrossRefGoogle ScholarPubMed
Bihuniak, JD, Ramos, A, Huedo-Medina, T, et al. (2016) Adherence to a Mediterranean-Style diet and its influence on cardiovascular risk factors in postmenopausal women. J Acad Nutr Diet 116, 17671775.CrossRefGoogle ScholarPubMed
Vasiloglou, MF, Lu, Y, Stathopoulou, T, et al. (2020) Assessing Mediterranean Diet adherence with the smartphone: the Medipiatto Project. Nutrients 12, 3763.CrossRefGoogle ScholarPubMed
Eldridge, AL, Piernas, C, Illner, A-K, et al. (2018) Evaluation of new technology-based tools for dietary intake assessment – an ILSI Europe Dietary intake and exposure task force evaluation. Nutrients 11, 55.CrossRefGoogle ScholarPubMed
Sotos-Prieto, M, Cash, SB, Christophi, CA, et al. (2017) Rationale and design of feeding America’s bravest: Mediterranean diet-based intervention to change firefighters’ eating habits and improve cardiovascular risk profiles. Contemp Clin Trials 61, 101107.CrossRefGoogle ScholarPubMed
Martínez-González, , Hershey, MS, Zazpe, I, et al. (2017) Transferability of the Mediterranean Diet to Non-Mediterranean Countries. What is and what is not the Mediterranean Diet. Nutrients 9, 1226.CrossRefGoogle Scholar
Alberti-Fidanza, A & Fidanza, F (2004) Mediterranean adequacy index of Italian diets. Public Health Nutr 7, 937941.CrossRefGoogle ScholarPubMed
Martínez-González, MA, García-Arellano, A, Toledo, E, et al. (2012) A 14-item Mediterranean diet assessment tool and obesity indexes among high-risk subjects: the PREDIMED trial. PLoS One 7, e43134.CrossRefGoogle ScholarPubMed
Fryar, C, Hughes, J, Herrick, K, et al. (2018) Fast Food Consumption among Adults in the United States, 2013–2016. Hyattsville, MD: National Center for Health Statistics.Google ScholarPubMed
Machado, PP, Steele, EM, Levy, RB, et al. (2020) Ultra-processed food consumption and obesity in the Australian adult population. Nutr Diabetes 10, 39.CrossRefGoogle ScholarPubMed
De Vogli, R, Kouvonen, A & Gimeno, D (2014) The influence of market deregulation on fast food consumption and body mass index: a cross-national time series analysis. Bull World Health Organ 92, 99107.CrossRefGoogle ScholarPubMed
Agarwal, P, Dhana, K, Barnes, LL, et al. (2021) Unhealthy foods may attenuate the beneficial relation of a Mediterranean diet to cognitive decline. Alzheimers Dement J Alzheimers Assoc 17, 11571165.CrossRefGoogle ScholarPubMed
Pavičić Žeželj, S, Kenđel Jovanović, G, Dragaš Zubalj, N, et al. (2018) Associations between adherence to the mediterranean diet and lifestyle assessed with the MEDLIFE index among the working population. Int J Environ Res Public Health 15, 2126.CrossRefGoogle Scholar
Hershey, MS, Sotos-Prieto, M, Ruiz-Canela, M, et al. (2021) The Mediterranean lifestyle (MEDLIFE) index and metabolic syndrome in a non-Mediterranean working population. Clin Nutr 40, 24942503.CrossRefGoogle Scholar
Anastasiou, CA, Yannakoulia, M, Kontogianni, MD, et al. (2018) Mediterranean Lifestyle in Relation to Cognitive Health: results from the HELIAD Study. Nutrients 10, 1557.CrossRefGoogle ScholarPubMed
Marventano, S, Godos, J, Platania, A, et al. (2018) Mediterranean diet adherence in the Mediterranean healthy eating, aging and lifestyle (MEAL) study cohort. Int J Food Sci Nutr 69, 100107.CrossRefGoogle ScholarPubMed
Grosso, G, Marventano, S, D’Urso, M, et al. (2017) The Mediterranean healthy eating, ageing, and lifestyle (MEAL) study: rationale and study design. Int J Food Sci Nutr 68, 577586.CrossRefGoogle ScholarPubMed
Godos, J, Ferri, R, Caraci, F, et al. (2019) Adherence to the Mediterranean Diet is associated with better sleep quality in Italian adults. Nutrients 11, 976.CrossRefGoogle Scholar
Hoffman, R & Gerber, M (2015) Food processing and the Mediterranean Diet. Nutrients 7, 79257964.CrossRefGoogle ScholarPubMed
Agudo, A, Slimani, N, Ocké, MC, et al. (2002) Consumption of vegetables, fruit and other plant foods in the European Prospective Investigation into Cancer and Nutrition (EPIC) cohorts from 10 European countries. Public Health Nutr 5, 11791196.CrossRefGoogle ScholarPubMed
Angastinioti, E, Zakrajsek, A & Hutchins-Wiese, HL (2020) An exploratory study examining Mediterranean Diet perceptions, eating practices, and food choice of emerging adults from cyprus and the United States. World Nutr 11, 2243.CrossRefGoogle Scholar
Giampieri, E, Ostan, R, Guidarelli, G, et al. (2019) A novel approach to improve the estimation of a diet adherence considering seasonality and short term variability – The NU-AGE Mediterranean Diet Experience. Front Physiol 10, 149.CrossRefGoogle ScholarPubMed
Messina, MJ (1999) Legumes and soybeans: overview of their nutritional profiles and health effects. Am J Clin Nutr 70, 439S450S.CrossRefGoogle ScholarPubMed
Singh, RB, Dubnov, G, Niaz, MA, et al. (2002) Effect of an Indo-Mediterranean diet on progression of coronary artery disease in high risk patients (Indo-Mediterranean Diet Heart Study): a randomised single-blind trial. Lancet Lond Engl 360, 14551461.CrossRefGoogle ScholarPubMed
Tangney, CC, Kwasny, MJ, Li, H, et al. (2011) Adherence to a Mediterranean-type dietary pattern and cognitive decline in a community population. Am J Clin Nutr 93, 601607.CrossRefGoogle Scholar
Blumberg, J, Heaney, RP, Huncharek, M, et al. (2010) Evidence-based criteria in the nutritional context. Nutr Rev 68, 478484.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Mediterranean diet scoring system food components in Mediterranean countries

Figure 1

Table 2. MEDAS validation studies in non-Mediterranean countries

Figure 2

Table 3. Mediterranean diet scoring systems in non-Mediterranean countries

Figure 3

Table 4. Mediterranean diet scoring system food components from US studies

Figure 4

Table 5. Mediterranean diet scoring system food components in non-Mediterranean countries

Figure 5

Table 6. Key and uncertain components