Hostname: page-component-78c5997874-lj6df Total loading time: 0 Render date: 2024-11-16T13:22:16.515Z Has data issue: false hasContentIssue false

Trends in blood lipids and fat soluble vitamins in Catalonia, Spain (1992–2003)

Published online by Cambridge University Press:  01 November 2007

Lluís Serra-Majem*
Affiliation:
Community Nutrition Research Centre, University of Barcelona Science Park, Baldiri Reixac 4, Torre D4A1, 08028 Barcelona, Spain Department of Clinical Sciences, University of Las Palmas de Gran Canaria, Las Palmas de Gran Canaria, Spain Division of Public Health, Department of Health, Generalitat of Catalonia, Barcelona, Spain
Ma Cruz Pastor-Ferrer
Affiliation:
Department of Biochemistry, Hospital Germans Trias i Pujol, Badalona, Spain
Conxa Castell
Affiliation:
Division of Public Health, Department of Health, Generalitat of Catalonia, Barcelona, Spain
Lourdes Ribas-Barba
Affiliation:
Community Nutrition Research Centre, University of Barcelona Science Park, Baldiri Reixac 4, Torre D4A1, 08028 Barcelona, Spain
Blanca Román-Viñas
Affiliation:
Community Nutrition Research Centre, University of Barcelona Science Park, Baldiri Reixac 4, Torre D4A1, 08028 Barcelona, Spain
Laia Font Ribera
Affiliation:
Community Nutrition Research Centre, University of Barcelona Science Park, Baldiri Reixac 4, Torre D4A1, 08028 Barcelona, Spain
Antoni Plasencia
Affiliation:
Division of Public Health, Department of Health, Generalitat of Catalonia, Barcelona, Spain
Lluis Salleras
Affiliation:
Department of Public Health, University of Barcelona, Barcelona, Spain
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

The purpose of this study was to assess the 10-year trend in lipid and antioxidant vitamin levels in the Catalan population from 1992 to 2003.

Design

Two cross-sectional surveys were carried out in Catalonia, Spain, during 1992–93 and 2002–03. A subsample of the individuals participating in the surveys agreed to undergo a biochemical evaluation.

Subjects

Eight hundred and eighty individuals (393 males and 487 females) in the 1992–93 nutritional survey and 429 individuals (205 males and 224 females) in the 2002–03 nutritional and health survey. The subjects’ ages ranged from 18 to 74 years.

Results

Mean total cholesterol decreased from 5.3 to 5.1 mmol l−1 (P < 0.005), and the prevalence of hypercholesterolaemia decreased, especially in males (from 23% to 10% in males from 50 to 64 years old, P < 0.05). Mean cholesterol high-density lipoprotein (HDL) values decreased in the entire sample (from 1.4 to 1.3 mmol l−1, P < 0.001) and there was an increase in the percentage of population with low values of HDL (from 10% to 19%, P < 0.001). An increase in the percentage of the population with values of α-tocopherol at marginal risk levels (from 6% to 9%) and with low values of β-carotene (from 59% to 66%) was observed. The mean values for retinol increased in both males (from 1.99 to 2.44 μmmol l−1, P < 0.001) and females (from 1.69 to 2.29, P < 0.001).

Conclusion

Although there was a decrease in the percentage of population with hypercholesterolaemia, the decrease in HDL cholesterol worsened the lipid profile of the Catalan population. The increase in the values of some antioxidant vitamins did not affect the entire population since an increase in the number of individuals with marginal values was observed.

Type
Original Article
Copyright
Copyright © The Authors 2007

Biochemical markers are useful for the evaluation of nutritional status within a population, to estimate their dietary intake and to determine the prevalence of risk factors for the leading causes of morbidity and mortality.

Plasma lipid levels are one of the main risk factors for the prevention of cardiovascular diseases, which are the principal cause of mortality in developed countries. Although mortality related to cardiovascular diseases have stabilised in Spain in the last decadesReference Boix, Medrano and Almazán1, trends of hospital morbidity rates related to such diseases have shown an increase2. Even though ischaemic heart disease is still the leading cause of mortality among Spanish males and the third cause of mortality among Spanish females, Spain exhibits a lower rate of mortality related to cardiovascular diseases compared to countries in central and northern EuropeReference Levi, Lucchini, Negri and La Vecchia3, Reference Sarti, Rastenyte, Cepaitis and Tuomilehto4. On the other hand, the prevalence of hypercholesterolaemia in Spain increased from 6% in 1987 to 15% in 1999 and decreased to 11% in 2001Reference Cerrato Crespán, Boix Martínez and Medrano Albero5.

Plasma levels of antioxidants have shown a relationship with all-cause mortalityReference De Waart, Schouten, Stalenhoef and Kok6, Reference Buijsse, Feskens, Schlettwein-Gsell, Ferry, Kok, Kromhout and de Groot7, cardiovascular diseaseReference Voutilainen, Nurmi, Mursu and Rissanen8, Reference Hak, Ma, Powell, Campos, Gaziano and Willett9, certain cancersReference Jenab, Riboli, Ferrari, Friesen, Sabate and Norat10, Reference Ziegler11, insulin resistanceReference Coyne, Ibiebele, Baade, Dobson, McClintock and Dunn12 and degenerative diseasesReference Hallfrisch, Muller and Singh13. Subclinical deficiencies of such vitamins are related to some of these diseases, especially in those subjects having greater oxidative stressReference Willett14.

In 1992–93, the Catalan government developed an Evaluation of Nutritional Status of the Catalan population, which included a biochemical assessmentReference Serra Majem, Ribas Barba, García Closas, Ramon, Salvador and Farran15Reference Garcia Closas, Serra Majem, Pastor, Olmos, Roman and Ribas17. Blood lipid analysis included total cholesterol (TC), low-density lipoprotein cholesterol (LDL), high-density lipoprotein cholesterol (HDL) and serum triglycerides (TG). β-Carotene, retinol and α-tocopherol were also determined.

Following WHO (World Health Organisation) recommendationsReference Puska18, the 1991 Health Plan for Catalonia19 established as part of its objectives that by the year 2000 less than 20% of the population would have hypercholesterolaemia. To evaluate the compliance with such recommendations, it was stated to develop population nutritional surveys periodically. In 2002–03, a new Nutrition and Health Examination Survey of the Catalan population included an evaluation of the biochemical status of the populationReference Serra Majem, Ribas Barba, Salvador Castell, Castell Abat, Román Viñas and Serra20, 21.

The purpose of this study was to evaluate the distribution of serum lipid levels (TC, HDL, LDL and TG) and fat-soluble vitamins in the adult population of Catalonia in 2002–03 and to analyse their trends since 1992–93, the latter being the date from which nutrition policies promoting healthy eating and lifestyle among the population had been implemented.

Material and Methods

Sample

The sample of the Evaluation of Nutritional Status of the Catalan population for the 1992–93 included 2346 persons aged 18 to 74 yearsReference Serra Majem, Ribas Barba, García Closas, Ramon, Salvador and Farran15. Thirty-eight per cent of the interviewees (n = 893) agreed to participate in the biochemical analysis of nutritional status. Of these persons, blood samples from a subsample of 378 individuals were randomly selected for determining levels of β-carotene, retinol and α-tocopherolReference Serra Majem, Ribas Barba, García Closas, Ramon, Salvador and Farran15Reference Garcia Closas, Serra Majem, Pastor, Olmos, Roman and Ribas17.

The biochemical analysis for 2002–03 was conducted in a subsample (n = 429) aged 18 to 74 years of those subjects participating in the Catalan Nutrition and Health Survey 2002–03 (n = 1396), which was in and of itself a subsample of the Catalan Health Survey 2000 (ESCA) (n = 8400) carried out by the Department of Health and Social Security of the Generalitat de Catalunya21.

Analytical determinants

ENCAT 1992–93 survey

In 1992–93, samples were obtained and processed by a mobile team at health centres that had been selected among those available in municipalities that were included in the sample. Blood samples were collected between 8 and 10 a.m. in 12-hour fasting conditionsReference Serra Majem, Ribas Barba, García Closas, Ramon, Salvador and Farran15Reference Garcia Closas, Serra Majem, Pastor, Olmos, Roman and Ribas17.

Samples were processed immediately after being collected. Blood was centrifuged at 3000 r.p.m. for 15 min at 8°C, after having undergone a period of pre-centrifugation for 30 min. Serum was fractioned into aliquot portions via disposable pipettes. Samples for lipid analysis were immediately placed in portable coolers, maintained at 4°C and sent to the Biochemistry Service at the Vall d’Hebrón Hospital in Barcelona for analysis within 24 hours post-extraction. Samples for analysing vitamins were frozen at −80°C and transported in portable freezers to the Biochemistry Service at the Germans Trias i Pujol Hospital in Badalona.

Serum TC, high-density cholesterol (HDL), low-density cholesterol (LDL) and triglycerides (TG) were analysed. TC and TG were determined by enzymatic methods CHOD-PAP and GPO-PAP, respectively, using the autoanalyser Hitachi 747 and reagents from Boehringer-Mannheim.

HDL was determined by the Assmann et al. Reference Assmann, Schriewer, Schmitz and Hagele22 method, after precipitation of LDL, very low-density lipoproteins and chylomicrons with phosphotungstanic acid and magnesium chloride. LDL was calculated with the Friedewald formula (LDL = TC−(TG/5 + HDL)) only for those samples having triglyceride concentrations lower than 300 mg dl−1Reference Garcia Closas, Serra Majem, Chacón, Olmos, Ribas and Salleras16, Reference Friedewald, Levy and Fredrickson23.

Serum concentrations of β-carotene, retinol and α-tocopherol were obtained by high-resolution liquid chromatography with ultraviolet detectionReference Milne and Botnen24Reference Pastor Ferrer, Codoceo Alquinta, Deulofeu Piquet, Dolacé Botias, Farré Guerrero and Fernández Calle26. Given that commercial quality control teams did not exist at the time samples were collected, blood bank donor samples were used as control and it was determined as a coefficient of variation. The coefficients of variation (CV) intra and inter-assay ranged from 6% to 9.9% for β-carotene, from 4.5% to 7.3% for retinol and from 3.5% to 8.4% for α-tocopherolReference Garcia Closas, Serra Majem, Pastor, Olmos, Roman and Ribas17.

Nutrition and Health 2002–03 survey

In the 2002–03 biochemical evaluation, blood samples were obtained between 9 and 11 a.m. in fasting conditions. Samples were labelled and processed in the laboratory of the health region that corresponded to the centre where extractions were realised. Upon reaching the laboratory they were centrifuged and separated into aliquots, labelled and frozen at −20°C and then transferred to the biochemical laboratory at the Germans Trías i Pujol Hospital in Badalona.

The methodology to analyse serum lipids and vitamins was the same as the one utilised in the ENCAT (Evaluation of Nutritional Status in Catalonia) 1992–93 study.

The cut-off points utilised to assess lipid concentrations were as follows27: TC: <5.18, 5.18–6.21 and ≥6.22 mmol l−1; LDL: <2.59, 2.59–3.36, 3.37–4.13 and ≥4.14 mmol l−1; HDL: <1.04, 1.04–1.55 and ≥1.56 mmol −1; TG: <1.67, 1.67–2.25 and ≥2.26 mmol l−1.

Values for the concentration of vitamins were standardised for serum lipid concentrations. Cut-off values applied to vitamin concentrations wereReference Gibson28, Reference Fidanza29 as follows: β-carotene: <0.4 μmol l−1 (deficit), retinol: <0.7 μmol l−1 (severe deficit) and α-tocopherol: <11.6 μmol l−1 (severe deficit), 11.6–23.1 (marginal deficit) and ≥23.2 μmol l−1 (normal).

The comparison of the mean values and the percentage of the distribution of the variables are shown.

Results

In 1992–93 the final sample included 880 individuals (393 males and 487 females) for the lipid analysis and 337 individuals (144 males and 193 females) for the vitamin analysis, aged 18 to 74 years. In 2002–03, 429 subjects (205 males and 224 females) aged 18 to 74 years participated in the lipid and vitamin evaluation.

Mean plasma concentrations of TC, LDL, HDL and TG are shown in Table 1. In the 1992–93 evaluation, mean value for TC was 5.26 mmol l−1 (203.5 mg dl−1) in males and 5.28 mmol l−1 (204.3 mg dl−1) in females. Women had higher TC levels, except for the age group of 35–49 years where men had higher values. In the 2002–03 analysis21 the mean value for TC was 5.1 mmol l−1 (197.3 mg dl−1) for males and females. In men, mean TC levels increased with age throughout middle age and then decreased, reaching a peak at ages 35–49 years. For women mean TC values increased in every age group, until ages 65–74 years. Mean TC levels decreased during the decade from 5.3 to 5.1 mmol l−1 (P < 0.005), with males showing a higher decrease over all age groups than females. By age groups, and gender, only females from 50 to 64 years old showed a significant decrease (from 5.8 to 5.5 mmol l−1). Individuals aged 18–34 and women aged 65–74 years maintained the same TC levels.

Table 1 Trends (1992–2003) in the mean serum cholesterol and triglycerides of the Catalan population

LDL – low-density lipoprotein; HDL – high-density lipoprotein; ns – non-significant.

Mean LDL values remained stable, 3.30 mmol l−1 (127.4 mg dl−1) in 1992–93 and 3.26 mmol l−1 (125.9 mg dl−1) in 2002–03, with higher values at older ages in both genders and both surveys. In 1992–93 women showed lower LDL values than males except for those from 50 to 64 years (3.71 mmol l−1), who had higher values than males of the same age group (3.59 mmol l−1). In 2002–03, the LDL values in females were lower than in males except for the age group of 50–64 years and 65–74 years. The mean LDL values decreased in the interval of the period analysed in all age groups, except for males and females from 18 to 34 where the values remained stable (2.9 mmol l−1 in males and 2.7 mmol l−1 in females) and females from 65 to 74 where an increase was observed (from 3.5 to 3.7 mmol l−1).

Mean HDL was 1.44 mmol l−1 (53.9 mg dl−1) in 1992–93 and 1.34 mmol l−1 (50.2 mg dl−1) in 2002–03 (P < 0.001), with women showing higher levels than men. The HDL values decreased in the period analysed from 1.29 to 1.20 mmol l−1 in males (P < 0.001) and from 1.57 to 1.48 in females (P < 0.005). Only males from 65 to 74 years and females from 35 to 49 years maintained the same HDL levels.

Mean serum TG was 1.17 mmol l−1 (103.57 mg dl−1) in 1992–93 and 1.08 mmol l−1 (95.6 mg dl−1) in 2002–03 (P < 0.01). Men had higher TG levels than females except for women aged 65 to 74 years in the 2002–03 survey. In the period analysed, males showed a decrease in the TG levels, from 1.34 to 1.21 mmol l−1 (P < 0.01), and only individuals from 18 to 34 years showed an increase (from 1.03 mmol l−1 to 1.11 mmol l−1). Only females from 35 to 49 years showed a significant decrease in their TG levels (from 0.90 to 0.85 mmol l−1, P < 0.05).

Tables 25 show the distribution of the population according to the proposed cut-off points for TC, LDL, HDL and TG. The proportion of the population with high serum levels of TC (≥6.22 mmol l−1) decreased from 18% to 12% in males and from 20% to 18% in females during the 10-year interval. Only males from 50 to 64 years showed a significant decrease in the percentage of individuals with hypercholesterolaemia (from 23% to 10%, P < 0.05). In 2002–03, about 31% of the population had moderately high cholesterol values (5.18–6.21 mmol l−1), a proportion that increased to 47% of the population in the age group of 65–74 years old. Referring to LDL cholesterol, the percentage of males with high values decreased from 19% to 17%. In females and for all age groups in the period analysed, an increase in the percentage of individuals with the lowest as well as the highest LDL levels was shown. The percentage of population with high levels of HDL decreased from 35% to 27% (P < 0.001), in both males (from 20% to 11%, P < 0.01) and females (from 47% to 41%, P < 0.05) and for all age groups. The proportion of individuals with low levels of HDL increased (from 10% to 19%) in all age groups, especially in males from 35 to 49 years (from 17% to 37%). In the 2002–03 analysis, the percentage of population with high values for TG (≥2.26 mmol l−1) decreased (from 7% to 6%) although the change was not significant.

Table 2 Trends (1992–2003) in the distribution of the Catalan population according to proposed cut-off points for total cholesterol by gender and age group

ns – non-significant.

Table 3 Trends (1992–2003) in the distribution of the Catalan population according to proposed cut-off points for LDL cholesterol by gender and age group

LDL – low-density lipoprotein; ns – non-significant.

Table 4 Trends (1992–2003) in the distribution of the Catalan population according to proposed cut-off points for HDL cholesterol by gender and age group

HDL – high-density lipoprotein; ns – non-significant.

Table 5 Trends (1992–2003) in the distribution of the Catalan population according to proposed cut-off points for triglycerides by gender and age group

ns – non-significant.

Mean values for α-tocopherol, β-carotene and retinol are shown in Table 6. α-Tocopherol levels increased from 31.88 μmol l−1 in 1992 to 33.59 μmol l−1 in 2003 (P < 0.005). The mean concentrations of α-tocopherol increased in all age groups except for older females where the values decreased from 35.1 in 1992–93 to 34.2 μmol l−1 in 2002–03. Only females from 18 to 34 years showed a statistically significant increase (from 31.6 to 33.4, P < 0.05). Values were lower in males than in females except for the older men in the 2002–03 survey, which had higher values than females for the same age group (35.2 and 34.2 μmol l−1, respectively).

Table 6 Trends (1992–2003) in plasma concentration of α-tocopherol, β-carotene and retinol in the Catalan population by gender and age group

ns – non-significant.

Mean plasma levels for β-carotene was 0.42 μmol l−1 in the 1992–93 survey and 0.39 μmol l−1 in the 2002–03 analysis (P < 0.05). Women had higher carotenoid levels than men. In the 10-year interval, there was a decrease in the mean values of β-carotene for all age groups except for those males younger than 35 years (from 0.34 to 0.40 μmol l−1) and for women from 50 to 64 years, although not statistically significant.

Mean levels of retinol increased in the period of study, from 1.82 μmol l−1 in 1992–93 to 2.36 μmol l−1 in the 2002–03 survey (P < 0.001), both for males (from 1.99 to 2.44, P < 0.001) and for females (from 1.69 to 2.29, P < 0.001) and for all age groups. Men showed higher values of retinol concentrations (2.44 μmol l−1) than females (2.29 μmol l−1) except for females from 35 to 49 years in the 2002–03 (2.39 μmol l−1) analysis, which had higher values than males (2.28 μmol l−1).

Table 7 shows the distribution of the Catalan population with concentrations of α-tocopherol and β-carotene below the threshold used to define deficiency or inadequate levels. There has been an increase in the population with a marginal deficit of α-tocopherol (from 5.8% in 1992–92 to 8.7% in 2002–03), especially so in males for whom 10.5% of the population were at marginal risk in the 2002–03 survey. For males under 35 years of age, there was an important increase in the percentage of individuals with values below 23.1 μmol l−1 (from 6.8% to 18.5%). Only individuals from 65 to 74 years showed a decrease in the percentage of marginal deficit (from 8.3% to 3.0%). In the 2002–03 survey, 1.6% of females from 35 to 49 years showed a severe deficit.

Table 7 Distribution of the Catalan population according to concentrations of α-tocopherol and β-carotene (1992–2003)

ns – non-significant.

An increase in the percentage of the population at risk for low β-carotene values was observed (from 58.9% in 1992–93 to 65.8% in 2002–03), except for males younger than 35 years and females from 65 to 74 years where a decrease was shown.

Discussion

The main finding of this study was that the Catalan population shows a slightly worsened lipid profile for the decade analysed, due to the decrease reported in the HDL levels of the population. On the other hand, a decrease in TC, LDL and TG levels, a trend that had already been previously reported for the 1980–1992 decadeReference Plans, Ruigómez, Pardell and Salleras30, counteracts the main findings seen. Certain European31Reference Marques Vidal, Ruidavets, Amouyel, Ducimetiere, Arveiler and Montaye34 countries and the USAReference Carroll, Lacher, Sorlie, Cleeman, Gordon and Wolz35 have shown similar trends, with a decrease in the serum lipid levels but of a different magnitude for each lipoprotein. The analysis of serum lipids conducted in the USA during the same time period also showed a decrease in the levels of TC and LDL and a decrease in the percentage of the population with hypercholesterolaemia, as shown in adults from Catalonia. The evolution of HDL and TG levels is of a different magnitude between both countries. In the USA, HDL levels increased in females, whereas levels in males remained stable. The TG levels increased in the entire population. In the Catalan population, a decrease in HDL levels is similar in both males and females. Referring to European countries, trend data from Germany31 showed an increase in the percentage of population with hypercholesterolaemia while trend data from the MONICAReference Vartiainen, Jousilahti, Alfthan, Sundvall, Pietinen and Puska32Reference Marques Vidal, Ruidavets, Amouyel, Ducimetiere, Arveiler and Montaye34 study have shown some stabilisation in HDL levels, but not a clear decrease in serum HDL cholesterol levels, which was the trend observed in the Catalan population. HDL trends have improved in certain countries such as in Finland, where a well-planned nutrition policy has been shown to have specific benefitsReference Vartiainen, Jousilahti, Alfthan, Sundvall, Pietinen and Puska32, Reference Kastarinen, Tuomilehto, Vartiainen, Jousilahti, Sundvall and Puska33. On the other hand, trend data from a Swiss region participating in the MONICA study also reported a decrease in the HDL levels of the populationReference Wietlisbach, Paccaud, Rickenbach and Gutzwiller36. Mean HDL levels in the Catalan population are lower than those reported in the Finnish populationReference Kastarinen, Tuomilehto, Vartiainen, Jousilahti, Sundvall and Puska33 or in FranceReference Marques Vidal, Ruidavets, Amouyel, Ducimetiere, Arveiler and Montaye34, but are still higher than those in the USA populationReference Arnett, Jacobs, Luepker, Blackburn, Armstrong and Claas37. It is difficult to pinpoint the reasons that might explain this decrease. A mixture of factors such as a modification in the dietary habits or physical activity patterns as well as the use of hypolipidemic medications in the population may explain the trend. According to trend data on food habits in the Catalan population, olive oil consumption has not decreased in the last decade and it is still the main oil consumed as ‘added table fats’. Referring to physical activity, a slight decrease in the sedentary habits of the population has been reported, although it is difficult to calculate the modification in the total daily energy expenditure that this may represent. On the other hand, hypolipidaemic medication use has not changed in the interval of time analysed.

The reduction in the percentage of population with high lipid levels (hypercholesterolaemia) concurs with a decrease in the mortality rates related to cardiovascular diseases in Catalonia. It is calculated that between 1990 and 2000 the mortality associated with CVD decreased 32.6% in CataloniaReference Tresserras, Castell and Pardell38. As the reduction in the trends of TC is due mainly to the reduction of HDL levels instead of LDL levels, other factors such as physical activity or dietary antioxidantsReference Marrugat and Sentí39, Reference Ferrieres40 are thought to have some protective effects on the cardiovascular health of individuals from Mediterranean countries such as Spain. As reported in other publications, although these countries have a high prevalence of cardiovascular risk factorsReference Medrano, Cerrato, Boix and Delgado-Rodríguez41, the morbidity and mortality related to cardiovascular diseases are lower than other European countriesReference Watson42. In Catalonia, as shown in other countries, TC increased with age groupReference Carroll, Lacher, Sorlie, Cleeman, Gordon and Wolz35, 43, Reference MacLean, Petrasovits, Connelly, Joffres, O’Connor and Little44 and females had better lipid profiles than malesReference MacLean, Petrasovits, Connelly, Joffres, O’Connor and Little44, Reference Olmedilla, Granado, Southon, Wright, Blanco and Gil-Martinez56.

The reported decrease in triglyceride levels contrasts with the notorious increase in the prevalence of overweight and obesity in the Catalan population, according to data from the same period47. On the contrary, in other countries such as the USAReference Carroll, Lacher, Sorlie, Cleeman, Gordon and Wolz35, JapanReference Arai, Yamamoto, Matsuzawa, Saito, Yamada and Oikawa46 and FinlandReference Juonala, Viikari, Hutri-Kahonen, Pietikainen, Jokinen and Taittonen48, data show that lipid levels of TG increased together with the prevalence of overweight and obesity. Moderation in alcoholic beverage consumption has been reported in Catalonia49.

It is noteworthy that the cohort of young adults had the worst profile than other age groups, data that coincide with other publicationsReference Arnett, Jacobs, Luepker, Blackburn, Armstrong and Claas37. TC, LDL and TG did not decrease in this age group, especially among males. This trend shows that improvements in the lifestyle of adults and older individuals are not affecting children and youth. Deterioration in their diet quality, as seen in observed decreases in fruit and vegetable consumption and increased fat intake, may explain these trends. In fact, the increase in obesity prevalence of the Catalan population is of a greater magnitude among children than adultsReference Aranceta, Perez Rodrigo, Serra Majem, Ribas Barba, Quiles Izquierdo and Vioque50. According to the enKid studyReference Serra-Majem, Aranceta Bartrina, Perez-Rodrigo, Ribas-Barba and Delgado-Rubio51, the prevalence of obesity among Catalan individuals aged 2–24 years was 9.5% in 1998–2000.

Nevertheless, the lipid profile of the Catalan population is still one of the healthiest among western societies. According to the European-based MONICA study, in the mid-1990s, Catalonia showed one of the lowest prevalences of hypercholesterolaemia among European countries53. However, should the tendency reported in this study continue, it may be that supposed protective factors that benefit Mediterraneans population’s health will no longer be sufficient to prevent the increase in the incidence of related chronic disease.

Although circulating concentrations of α-tocopherol increased in the Catalan population, a simultaneous increase in the percentage of population at risk for inadequate intakes was also observed. Available data on macro- and micronutrient intake in the 2002–03 Catalan Nutrition Survey showed that a high proportion of the population (33%) had vitamin E intakes below 2/3 of the recommended dietary intake for the Spanish population53. However, the values shown for α-tocopherol were higher than the values reported for populations in the USAReference Ford and Sowell54, France, Hungary, the UKReference Elmadfa, Weichselbaum, Konig, de Winter A-M, Trolle and Haapala55, Ireland and the NetherlandsReference Olmedilla, Granado, Southon, Wright, Blanco and Gil-Martinez56. Males in Catalonia showed higher concentrations of retinol and lower concentrations of β-carotene than females, a distribution that is in accordance with other population-based studiesReference Galan, Viteri, Bertrais, Czernichow, Faure and Arnaud57Reference Al-Delaimy, van Kappel, Ferrari, Slimani, Steghens and Bingham59. Some publications have shown differences between males and females in the plasma levels of α-tocopherolReference Ford and Sowell54, which were not observed in the Catalan population.

There has not been a clear modification in the profile of serum antioxidants in the Catalan population. A slight worsening in levels of α-tocopherol and β-carotene was reflected in an increase in the proportion of individuals with marginal deficits for these vitamins. This would mean that modifications in vitamin levels have not been homogeneous for the entire population and that certain groups of individuals have changed their nutritional habits, such as, for example, a decreased fruit and vegetable intake. The increase in the retinol levels for the entire population is considered as a positive trend.

Acknowledgements

Sources of funding: This work was made possible by financing from the General Division of Public Health of the Generalitat of Catalonia’s Department of Health, through a research agreement with the Fundación para la Investigación Nutricional (Nutrition Research Foundation).

Conflict of interest declaration: None of the authors had any conflicts of interest in connection with this study.

Authorship responsibilities: LSM was director of the study, was responsible for the interpretation of dietary data and the writing of the paper; MCPF was responsible for the laboratory analysis; CC participated in the study concept and design and revised the paper providing expert advice on data interpretation; LRB was responsible for the statistical analysis and revised the paper providing expert advice on data interpretation; BRV revised the paper providing expert advice on data interpretation and on the discussion of the paper; LFR provided advice on data interpretation; AP and LS revised the paper providing expert advice in the discussion of the paper.

Guarantor: Lluís Serra-Majem.

Acknowledgement: Special acknowledgement is madeto all those persons who were interviewed, and whose collaboration made the realisation of these surveys possible.

Research Group on the Evaluation and monitoring of the Nutritional Status in the Catalan Population: Lluís Serra-Majem, Director (University of Las Palmas de Gran Canaria); Lourdes Ribas-Barba, Coordinator (FIN-Nutrition Research Foundation-, Barcelona Science Park); Gemma Salvador (Generalitat of Catalonia); Conxa Castell (Generalitat of Catalonia); Blanca Román-Viñas (FIN, Barcelona Science Park); Jaume Serra (Generalitat of Catalonia); Lluís Jover (University of Barcelona); Ricard Tresserras (Generalitat of Catalonia); Blanca Raidó (FIN, Barcelona Science Park); Andreu Farran (CESNID, University of Barcelona); Joy Ngo (FIN, Barcelona Science Park); Mari Cruz Pastor (Hospital Germans Trias i Pujol, Badalona); Lluís Salleras (University of Barcelona); and Carmen Cabezas, Josep Lluís Taberner, Salvi Juncà, Josep Maria Aragay, Eulàlia Roure, Gonçal Lloveras Vallès (†2003), Antoni Plasencia (Generalitat of Catalonia).

References

1Boix, R, Medrano, MJ, Almazán, J. Actualización de la mortalidad por enfermedades cardiovasculares arterioscleróticas: enfermedad cerebrovascualr y enfermedad isquémica del corazón. Boletín Epidemiológico Semanal 2000; 8: 7780.Google Scholar
2 Instituto Nacional de Estadística. Morbilidad hospitalaria por enfermedades cardiovasculares. España 1977–2002. Available at http://193.146.50.130/htdocs/cardiov/isquemica/isquemica.htm (Accessed 6 November 2006).Google Scholar
3Levi, F, Lucchini, F, Negri, E, La Vecchia, C. Trends in mortality from cardiovascular and cerebrovascular diseases in Europe and other areas of the world. Heart 2002; 88 (2): 119124.CrossRefGoogle ScholarPubMed
4Sarti, C, Rastenyte, D, Cepaitis, Z, Tuomilehto, J. International trends in mortality from stroke, 1968 to 1994. Stroke 2000; 31 (7): 15881601.CrossRefGoogle ScholarPubMed
5Cerrato Crespán, E, Boix Martínez, R, Medrano Albero, MJ. Riesgo cardiovascular en España. Boletin Epidemiológico Semanal 2004; 12: 5356.Google Scholar
6De Waart, FG, Schouten, EG, Stalenhoef, AF, Kok, FJ. Serum carotenoids, alpha-tocopherol and mortality risk in a prospective study among Dutch elderly. International Journal of Epidemiology 2001; 30 (1): 136143.CrossRefGoogle Scholar
7Buijsse, B, Feskens, EJ, Schlettwein-Gsell, D, Ferry, M, Kok, FJ, Kromhout, D, de Groot, LC. Plasma carotene and alpha-tocopherol in relation to 10-y all-cause and cause-specific mortality in European elderly: the Survey in Europe on Nutrition and the Elderly, a Concerted Action (SENECA). American Journal of Clinical Nutrition 2005; 82 (4): 879886.CrossRefGoogle ScholarPubMed
8Voutilainen, S, Nurmi, T, Mursu, J, Rissanen, T. Carotenoids and cardiovascular health. American Journal of Clinical Nutrition 2006; 83: 12651271.CrossRefGoogle ScholarPubMed
9Hak, AE, Ma, J, Powell, CB, Campos, H, Gaziano, JM, Willett, WC, et al. . Prospective study of plasma carotenoids and tocopherols in relation to risk of ischemic stroke. Stroke 2004; 35 (7): 15841588.CrossRefGoogle ScholarPubMed
10Jenab, M, Riboli, E, Ferrari, P, Friesen, M, Sabate, J, Norat, T, et al. . Plasma and dietary carotenoid, retinol and tocopherol levels and the risk of gastric adenocarcinomas in the European prospective investigation into cancer and nutrition. British Journal of Cancer 2006; 95 (3): 406415.CrossRefGoogle ScholarPubMed
11Ziegler, RG. Vegetables, fruits, and carotenoids and the risk of cancer. American Journal of Clinical Nutrition 1991; 53 (Suppl. 1): 251S259S.CrossRefGoogle ScholarPubMed
12Coyne, T, Ibiebele, TI, Baade, PD, Dobson, A, McClintock, C, Dunn, S, et al. . Diabetes mellitus and serum carotenoids: findings of a population-based study in Queensland, Australia. American Journal of Clinical Nutrition 2005; 82 (3): 685693.CrossRefGoogle ScholarPubMed
13Hallfrisch, J, Muller, DC, Singh, VN. Vitamin A and E intakes and plasma concentrations of retinol, beta-carotene, and alpha-tocopherol in men and women of Baltimore Longitudinal Study of Aging. American Journal of Clinical Nutrition 1994; 60 (2): 176182.CrossRefGoogle Scholar
14Willett, WC. Nutritional Epidemiology. Oxford: Oxford University Press, 1998.CrossRefGoogle Scholar
15Serra Majem, L, Ribas Barba, L, García Closas, R, Ramon, JM, Salvador, G, Farran, A, et al. . Llibre Blanc: Avaluació de l’estat nutricional de la població catalana (1992–93). Barcelona: Departament de Sanitat i Seguretat Social, Generalitat de Catalunya, 1996.Google Scholar
16Garcia Closas, R, Serra Majem, L, Chacón, P, Olmos, M, Ribas, L, Salleras, L, et al. . Distribución de la concentración de lípidos séricos en una muestra representativa de la población adulta de Cataluña. Medicina Clinica (Barcelona) 1999; 113: 612.Google Scholar
17Garcia Closas, R, Serra Majem, L, Pastor, C, Olmos, M, Roman, B, Ribas, L, et al. . Distribución de la concentración sérica de β-caroteno, retinol y α-tocoferol en una muestra representativa de la población adulta de Cataluña. Medicina Clinica (Barcelona) 2002; 118 (7): 256261.CrossRefGoogle Scholar
18Puska, P, ed. Comprehensive cardiovascular community control programmes in Europe. WHO Euro Reports and Study 106. Copenhague: WHO, 1988.Google Scholar
19Generalitat de Catalunya, Departament de Sanitat i Seguretat Social. Document marc per a la elaboració del Pla de Salut de Catalunya. Barcelona: Departament de Sanitat i Seguretat Social, 1991.Google Scholar
20Serra Majem, L, Ribas Barba, L, Salvador Castell, G, Castell Abat, C, Román Viñas, B, Serra, J, et al. . Avaluació de l’estat nutricional de la població catalana 2002–2003. Evolució dels hàbits alimentaris i dels consum d’aliments i nutrients a Catalunya (1992–2003). Barcelona: Departament de Salut, Generalitat de Catalunya, 2006.Google Scholar
21 Generalitat de Catalunya, Departament de Salut. Examen de salud a la població de Catalunya de 18 a 74 anys. Barcelona: Departament de Salut, 2004. Available at http://www.gencat.net/salut/depsan/units/sanitat/pdf/exsalcat.pdfGoogle Scholar
22Assmann, G, Schriewer, H, Schmitz, G, Hagele, EO. Quantification of high-density-lipoprotein cholesterol by precipitation with phosphotungstic acid/MgCl2. Clinical Chemistry 1983; 29: 20262030.CrossRefGoogle ScholarPubMed
23Friedewald, WT, Levy, RI, Fredrickson, DS. Estimation of the concentration of low-density lipoprotein cholesterol in plasma, without use of the preparative ultracentrifuge. Clinical Chemistry 1972; 18: 499502.CrossRefGoogle ScholarPubMed
24Milne, DB, Botnen, J. Retinol, alpha-tocopherol, lycopene, and alpha- and beta-carotene simultaneously determined in plasma by isocratic liquid chromatography. Clinical Chemistry 1986; 32: 874876.CrossRefGoogle ScholarPubMed
25Pastor Ferrer, MC, Codoceo Alquinta, R, Deulofeu Piquet, R, Dolacé Botias, M, Farré Guerrero, V, Fernández Calle, P, et al. . Procedimiento recomendado para la determinación de alfa-tocoferol en suero. Química Clínica 1996; 15: 445449.Google Scholar
26Pastor Ferrer, MC, Codoceo Alquinta, R, Deulofeu Piquet, R, Dolacé Botias, M, Farré Guerrero, V, Fernández Calle, P, et al. . Evaluación de las condiciones preanalíticas y de la fase de extracción para la determinación de retinol y alfa-tocoferol en suero por cromatografía líquida de alta resolución. Química Clínica 1996; 15: 190196.Google Scholar
27Summary of the second report of the National Cholesterol Education Program (NCEP) Expert Panel on Detection. Evaluation, and Treatment of High Blood Cholesterol in Adults (Adult Treatment Panel II). Journal of the American Medical Association 1993; 269: 30153023.CrossRefGoogle Scholar
28Gibson, RS. Principles of nutritional assessment. Oxford: Oxford University Press, 1990.Google Scholar
29Fidanza, F. Nutritional status assessment. A manual for population studies. London: Chapman & Hall, 1991.CrossRefGoogle Scholar
30Plans, P, Ruigómez, J, Pardell, H, Salleras, L. Distribución de lípidos en la población adulta de Cataluña. Revista Clinica Española 1993; 193: 3542.Google Scholar
31 Peterson S, Peto V, Rayner M. European cardiovascular disease statistics: 2005 edition. Available at http://www.ehnheart.org/files/statistics%2005-092711A.pdf (Accessed 12 December 2006).Google Scholar
32Vartiainen, E, Jousilahti, P, Alfthan, G, Sundvall, J, Pietinen, P, Puska, P. Cardiovascular risk factor changes in Finland, 1972–1997. International Journal of Epidemiology 2000; 29 (1): 4956.CrossRefGoogle ScholarPubMed
33Kastarinen, M, Tuomilehto, J, Vartiainen, E, Jousilahti, P, Sundvall, J, Puska, P, et al. . Trends in lipid levels and hypercholesterolemia in hypertensive and normotensive Finnish adults from 1982 to 1997. Journal of Internal Medicine 2000; 247 (1): 5362.CrossRefGoogle ScholarPubMed
34Marques Vidal, P, Ruidavets, JB, Amouyel, P, Ducimetiere, P, Arveiler, D, Montaye, M, et al. . Change in cardiovascular risk factors in France, 1985–1997. European Journal of Epidemiology 2004; 19 (1): 2532.CrossRefGoogle ScholarPubMed
35Carroll, MD, Lacher, DA, Sorlie, PD, Cleeman, JI, Gordon, DJ, Wolz, M, et al. . Trends in serum lipids and lipoproteins of adults, 1960–2002. Journal of the American Medical Association 2005; 294 (14): 17731781.CrossRefGoogle ScholarPubMed
36Wietlisbach, V, Paccaud, F, Rickenbach, M, Gutzwiller, F. Trends in cardiovascular risk factors (1984–1993) in a Swiss region: results of three population surveys. Preventive Medicine 1997; 26: 523533.CrossRefGoogle Scholar
37Arnett, DK, JrJacobs, DR, Luepker, RV, Blackburn, H, Armstrong, C, Claas, SA. Twenty-year trends in serum cholesterol, hypercholesterolemia, and cholesterol medication use: the Minnesota Heart Survey, 1980–1982 to 2000–2002. Circulation 2005; 112 (25): 38843891.CrossRefGoogle ScholarPubMed
38Tresserras, R, Castell, C, Pardell, H. Enfermedades cardiovasculares. Evaluación de los objetivos del Plan de Salud de Cataluña para el año 2000. Medicina Clinica (Barcelona) 2003; 121 (Suppl. 1): 2025.Google Scholar
39Marrugat, J, Sentí, M. Why mortality from heart disease is low in France. High cholesterol may not have same effect on cardiovascular risk in southern Europe as elsewhere. British Medical Journal 2000; 320 (7229): 250.Google Scholar
40Ferrieres, J. The French paradox: lessons for other countries. Heart 2004; 90 (1): 107111.CrossRefGoogle ScholarPubMed
41Medrano, MJ, Cerrato, E, Boix, R, Delgado-Rodríguez, M. Factores de riesgo cardiovascular en la población española: metaanálisis de estudios transversales. Medicina Clinica (Barcelona) 2005; 124 (16): 606612.CrossRefGoogle Scholar
42Watson, R. Circulatory diseases are Europe’s biggest killer. British Medical Journal 2006; 333 (7561): 218.Google ScholarPubMed
43Research Committee on Serum Lipid Level Survey 1990 in Japan. Current state of and recent trends in serum lipid levels in the general Japanese population. Journal of Arteriosclerosis and thrombosis 1996; 2 (2): 122132.CrossRefGoogle Scholar
44MacLean, DR, Petrasovits, A, Connelly, PW, Joffres, M, O’Connor, B, Little, JA. Plasma lipids and lipoprotein reference values, and the prevalence of dyslipoproteinemia in Canadian adults. Canadian Heart Health Surveys Research Group. The Canadian Journal of Cardiology 1999; 15 (4): 434444.Google ScholarPubMed
45Panagiotakos, DB, Pitsavos, C, Chrysohoou, C, Skoumas, J, Stefanadis, C. Status and management of blood lipids in Greek adults and their relation to socio-demographic, lifestyle and dietary factors: the ATTICA Study. Blood lipids distribution in Greece. Atherosclerosis 2004; 173 (2): 353361.CrossRefGoogle ScholarPubMed
46Arai, H, Yamamoto, A, Matsuzawa, Y, Saito, Y, Yamada, N, Oikawa, S, et al. . Serum lipid survey and its recent trend in the general Japanese population in 2000. Journal of Atherosclerosis and Thrombosis 2005; 12 (2): 98106.CrossRefGoogle ScholarPubMed
47 Direcció General de Salut Pública. Avaluació dels objectius per a l’any 2000 del Pla de Salut de Catalunya. Departament de Sanitat i Seguretat Social, Generalitat de Catalunya. Barcelona, 2003.Google Scholar
48Juonala, M, Viikari, JS, Hutri-Kahonen, N, Pietikainen, M, Jokinen, E, Taittonen, L, et al. . The 21-year follow-up of the Cardiovascular Risk in Young Finns Study: risk factor levels, secular trends and east-west difference. Data from trends on prevalence of overweight and obesity and blood lipid levels. Journal of Internal Medicine 2004; 255 (4): 457468.CrossRefGoogle Scholar
49 Ribas Barba L, Serra Majem L, Salvador G, Castell C, Cabezas C, Salleras L, Plasencia A. Trends in dietary habits and food consumption in Catalonia, Spain (1992–2003). Public Health Nutrition 2007; 10 (11A): 13401353.CrossRefGoogle Scholar
50Aranceta, J, Perez Rodrigo, C, Serra Majem, L, Ribas Barba, L, Quiles Izquierdo, J, Vioque, J, et al. . Prevalence of obesity in Spain: results of the SEEDO 2000 study. Medicina Clinica (Barcelona) 2003; 120 (16): 608612.CrossRefGoogle ScholarPubMed
51Serra-Majem, L, Aranceta Bartrina, J, Perez-Rodrigo, C, Ribas-Barba, L, Delgado-Rubio, A. Prevalence and determinants of obesity in Spanish children and young people. British Journal of Nutrition 2006; 96 (Suppl. 1): S6772.CrossRefGoogle Scholar
52Tolonen, H, Keil, U, Ferrario, M, Evans, A. Prevalence, awareness and treatment of hypercolesterolaemia in 32 populations: results from the MONICA Project. International Journal of Epidemiology 2005; 34 (1): 181192.CrossRefGoogle Scholar
53 Serra Majem L, Ribas Barba L, Salvador G, Jover L, Raido B, Ngo J, Plasencia A. Trends in energy and nutrient intake and risk of inadequate intakes in Catalonia, Spain (1992–2003). Public Health Nutrition 2007; 10 (11A): 13541367.CrossRefGoogle Scholar
54Ford, ES, Sowell, A. Serum alpha-tocoferol status in the United States population: findings from the Third National Health and Nutrition Examination Survey. American Journal of Epidemiology 1999; 150 (3): 290300.CrossRefGoogle Scholar
55Elmadfa, I, Weichselbaum, E, Konig, J, de Winter A-M, R, Trolle, E, Haapala, I, et al. . European nutrition and health report 2004. Forum of Nutrition 2005; 58: 1220.CrossRefGoogle Scholar
56Olmedilla, B, Granado, F, Southon, S, Wright, AJ, Blanco, I, Gil-Martinez, E, et al. . Serum concentrations of carotenoids and vitamins A, E, and C in control subjects from five European countries. British Journal of Nutrition 2001; 85: 227238.CrossRefGoogle Scholar
57Galan, P, Viteri, FE, Bertrais, S, Czernichow, S, Faure, H, Arnaud, J, et al. . Serum concentrations of beta-carotene, vitamins C and E, zinc and selenium are influenced by sex, age, diet, smoking status, alcohol consumption and corpulence in a general French adult population. European Journal of Clinical Nutrition 2005; 59 (10): 11811190.CrossRefGoogle Scholar
58Ortega, RM, Mena, MC, Faci, M, Santana, JF, Serra-Majem, L. Vitamin status in different groups of the Spanish population: a meta-analysis of national studies performed between 1990 and 1999. Public Health Nutrition 2001; 4 (6A): 13251329.CrossRefGoogle ScholarPubMed
59Al-Delaimy, WK, van Kappel, AL, Ferrari, P, Slimani, N, Steghens, JP, Bingham, S, et al. . Plasma levels of six carotenoids in nine European countries: report from the European Prospective Investigation into Cancer and Nutrition (EPIC). Public Health Nutrition 2004; 7 (6): 713722.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Trends (1992–2003) in the mean serum cholesterol and triglycerides of the Catalan population

Figure 1

Table 2 Trends (1992–2003) in the distribution of the Catalan population according to proposed cut-off points for total cholesterol by gender and age group

Figure 2

Table 3 Trends (1992–2003) in the distribution of the Catalan population according to proposed cut-off points for LDL cholesterol by gender and age group

Figure 3

Table 4 Trends (1992–2003) in the distribution of the Catalan population according to proposed cut-off points for HDL cholesterol by gender and age group

Figure 4

Table 5 Trends (1992–2003) in the distribution of the Catalan population according to proposed cut-off points for triglycerides by gender and age group

Figure 5

Table 6 Trends (1992–2003) in plasma concentration of α-tocopherol, β-carotene and retinol in the Catalan population by gender and age group

Figure 6

Table 7 Distribution of the Catalan population according to concentrations of α-tocopherol and β-carotene (1992–2003)