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Nutrición Hospitalaria

versión On-line ISSN 1699-5198versión impresa ISSN 0212-1611

Nutr. Hosp. vol.21 no.1 Madrid ene./feb. 2006

 

ORIGINAL

 

Effects of pork vs veal consumption on serum lipids in healthy subjects

Efecto del consumo de cerdo y de ternera sobre el perfil lipídico de sujetos sanos

 

 

J. A. Rubio*, M. A. Rubio**, L. Cabrerizo**, P. Burdaspal***, R. Carretero***, J. A. Gómez-Gerique****,
M. T. Montoya****, M. L. Maestro*****, M. T. Sanz***** y C Fernández******

*Department of Endocrinology and Nutrition. Príncipe de Asturias University Hospital. Alcalá de Henares. Madrid.
**Department of Endocrinology and Nutrition. San Carlos University Hospital. Madrid.
***Department of Bromatology. Carlos III Institute of Health. Madrid.
****Department of Biochemistry. Jiménez Díaz Foundation. Madrid.
*****Tumoral Biology Section. Department of Clinical Analysis. San Carlos University Hospital. Madrid.
******Department of Clinical Epidemiological Research. San Carlos University Hospital. Madrid. España.

Correspondencia

 

 


ABSTRACT

AIMS: To analyse the influence of lean pork (P) and veal (V) consumption on the lipid profile of healthy subjects within the framework of a healthy diet comprising low levels of total fat (TF), saturated fatty acids (SFA) and cholesterol.
DESIGN:
Double-crossover, randomized and controlled trial
SUBJECTS:
44 healthy individuals (22 male and 22 female), recruited voluntarily from the University Complutense of Madrid. The weight and lipid profiles of these volunteers were normal and their dietary patterns were typical for people in our area.
INTERVENTIONS: The study comprised 4 phases: stabilisation phase (5 weeks), the participants followed their normal diet; second phase (6 weeks), half of the subjects, were randomised to lean pork or veal consumption, 150 g per day, for their main meal of the day; washout period (5 weeks) and final phase, which was the second phase of intervention (6 weeks). During the intervention stages, only the main meal of the day was taken in the Hospital. The rest of the subjects' diets consisted of different fortnightly menus designed in accordance with the recommendations of the Spanish Society of Arteriosclerosis (SEA).
RESULTS: After both stages of intervention had been completed, there was a mean reduction of 5.5% in lowdensity lipoprotein cholesterol. However, after each intervention there were no significant differences between those who had consumed P, 2.62 (0.55) mmol/L and those who had consumed V, 2.71 (0.47) mmol/L. No differences were observed in any of the other parameters between those who had consumed P and those who had consumed V.
CONCLUSIONS: Lean pork and veal produces similar effects on the lipid profiles of healthy subjects. Its consumption, as part of the saturated fat and cholesterolcontrolled diet, could therefore be included in food guidelines, both for normal and therapeutic diets.

Palabras clave: Cerdo. Ternera. Buey. Carne roja. Lipoproteínas. Lípidos séricos.


RESUMEN

OBJETIVO: Analizar la influencia del consumo de carne magra de cerdo (P) y de ternera (V) en el perfil lipídico de sujetos sanos, cuando se realiza dentro de un patrón de dieta saludable con bajo contenido en grasa total (TF), ácidos grasos saturados (SFA) y en colesterol.
DISEÑO: Ensayo cruzado doble, aleatorizado y controlado.
SUJETOS: 44 sujetos sanos (22 varones y 22 mujeres), reclutados de forma voluntaria de la Universidad Complutense de Madrid. Los pesos y los perfiles lipídicos de estos voluntarios y su patrón de alimentación eran típicos de las personas de nuestra área.
INTERVENCIONES: El estudio consta de 4 fases: fase de estabilización (5 semanas), los participantes seguían su dieta normal; segunda fase (6 semanas), la mitad de los sujetos se randomizaron para que consumieran carne magra de cerdo o de ternera, 150 g al día, durante la principal comida del día; periodo de lavado (5 semanas) y fase final, que era la segunda fase de intervención (6 semanas). Durante las fases de intervención, sólo la principal comida se realizaba en el hospital. El resto de las dietas de los sujetos estaba constituida por menús diferentes para 2 semanas que seguían las recomendaciones de la Sociedad Española de Arteriosclerosis (SEA).
RESULTADOS: Tras ambas intervenciones, hubo una reducción media de un 5,5% en el LDL colesterol. Sin embargo, después de cada intervención no encontramos diferencias significativas entre los que consumieron P, 2.62 (0.55) mmol/L y estos que consumieron V, 2.71 (0.47) mmol/L. No se observó diferencias en el resto de los parámetros analizados entre los que consumieron P y los que consumieron V.
CONCLUSIONES: El consumo de P y B produce efectos similares sobre el perfil lipídico de sujetos sanos. Su consumo, formando parte de dietas controladas en grasa saturada y colesterol, podrían incluirse en pautas alimentarias, tanto de dietas normales como terapéuticas.

Key words: Pork. Veal. Beef. Read meat. Lipoproteins. Serum lipids.


 

Introduction

Evidence that the mediterranean diet is associated with a low risk of cardiovascular disease, and the effects of each nutrient on lipid profiles, have led to the establish-ment of a dietary model whose basic aim is to reduce the consumption of total fat (TF) and saturated fatty acids (SFA). This model was outlined in a consensus document published by the Spanish Society of Arteriosclerosis1 which recommended a TF consumption< 35%, an SFA consumption < 10%, a polyunsaturated fat (PUFA) consumption < 7%, and a dietary cholesterol < 300 mg/day. These recommended levels are illustrated in a pyramid structure2, where many of the recommended foods are limited in both the normal diet of a healthy population and in therapeutic diets,so maintaining such a diet long-term maybe difficult.

In the last few years, it has been shown that the hyperlipaemic effect of meats is more due to the type of fat contained than to the protein source itself. Therefore, we would not expect lean cuts of meat to have a negative effect on the lipid profile of consumers who are following a fat- and cholesterol-controlled diet3,4. It has been shown both for normolipaemic subjects5-8 and for hyperlipaemic subjects9-11 that the lipid profiles of consumers of lean red meats (beef and pork) who are following a fat-controlled diet are similar to those of consumers of white meats (basically chicken and/or fish). However, not much is known about the effects of consuming lean pork as opposed to lean veal on serum lipid concentrations.

This is important in European diet. So, in Spain, where the consumption of meat of pork (13.3 kg per capita per year), is the second one after the meat of poultry (16.7 kg), and followed by the veal (9.02 kg)12. The consumption of processed pork (cooked and dry cured products), which has a long tradition, is also important (15.8 kg). Dietary recommendations for preventing hyperlipaemia usually restrict the overall consumption of both lean and processed pork.

This paper compares how lean pork consumption and lean veal consumption, as part of the fat- and cholesterol- controlled diet recommended by the Spanish Society of Arteriosclerosis, affect the lipid profiles of healthy subjects.

 

Patients and methods

Subject

One hundred and twenty-six healthy subjects responded to a public announcement by the Complutense University of Madrid inviting volunteers to participate in the study.

Sample size was calculated for an expected reduction in LDL cholesterol concentrations around 0.25 mm/L (8.3 %), considering a type I error probability of 0.05, statistical power of 90 % and a prediction of drop-outs in the follow-up up to of 30 %; so, the sample size calculated was 44 individuals.

Inclusion criteria comprised normal weight subjects (Body Mass Index between 18.5-25 kg/m2), both sexes, and without evidence of any systemic disease or taking any medication. Individuals with total cholesterol concentration ≥ 6.2 mmol/L or < 3.87 mmol/L, low-density lipoprotein (LDL) cholesterol ≥ 4.13 mmol/L or < 2.06 mmol/L, triglycerides ≥ 2.25 mmol/L or high-density lipoprotein (HDL) cholesterol< 0.9 mmol/L were excluded. Regular alcohol consumption> 20 g/day and /or tobacco consumption >10 cigarettes/day, as well as physical exercise > 4186 kJ per week or an evidence for energy consumption < 6279 kJ per day or < 30% of energy in TF were also excluded from the study to avoid a possible bias due to its influence on lipid metabolism.

Of the 126 subjects, 44 subjects (22 men and 22 women) met all inclusion criteria. Informed written consent was obtained from all subjects and the Protocol was approved by the Hospital Ethics Committee.

Study design

This was a double-crossover, randomised and controlled trial to compare the effects on LDL cholesterol concentrations, of consuming lean pork with the effects of consuming lean veal. The null hypothesis would be meet if the LDL cholesterol concentrations of subjects who consumed lean pork and subjects who consumed lean veal showed no significant differences.

During the subjects' first visit, we recorded their case histories, collected anthropometric data and blood samples were obtained in order to check the criteria for inclusion and exclusion. During the five-week stabilisation phase, the participants were asked to follow their normal diet. This diet was to be typical of the diet of the general population12. During the intervention phase, 22 subjects were randomly allocated to consume lean pork (P) and the other 22 were to consume lean veal (V) for their main meal of the day, which was prepared in the San Carlos University Hospital. Subjects received dietary counselling, which included a rotatory system of menus every fortnight and a food exchange list. These menus were designed in accordance with the main recommendations of the SEA1. Meat was only consumed during the main meal of the day. After this first phase of intervention, the subjects were asked to again follow their normal diet for 5 weeks. This was the washout phase. Finally, during the second phase of intervention, which lasted 6 weeks, the subjects who had consumed pork during the first phase of intervention now consumed veal, and viceversa. By means of this crossover system, each subject acted as his or her own control.

Analysis of diet, meats and menus

The meats used in the study were supplied by Vaquero Meat Industries. Bromatological analysis of these meats was carried out in triplicate. The type of cuts were leg of pork, pork loin, pork sirloin, veal sirloin and veal filet. These analysis were carried out at the Centro Nacional de Alimentación (National Food Centre) of the Carlos III Institute according to official methods of food analysis13,14.

These bromatological data were used to design the various diets. The menus were then prepared using the food composition tables of Wander-Novartis Health Consumer S.A.15. Energy estimates were made in accordance with data on calorie consumption obtained from the food records obtained at the subject-selection stage. These were then adjusted to match the energy estimates proposed by the WHO16. All food except the main meal of the day (lunch), which was prepared and eaten in the Hospital, was consumed at home (under free-living conditions) following the rotatory system of menus. In the lunch, lean read meats, pork or veal (150 g) was consumed. Subjects were allowed to make rational exchanges of the ingredients within each food group.

To make sure that the theoretical estimates matched those of our study, bromatological analysis of the menus prepared in the hospital kitchens was carried out in triplicate according to the same official procedure as that used to analyse the meats.

Compliance

Study compliance was determined using the records of assistance of the subjects to the programmed visits and to the main meal of the day in the Hospital. Diet compliance was realized by quantitative (computerized)analysis of seven-day diet records (by means a nutritional software: Wander-, Novartis Nutrition, Barcelona, Spain).

Blood analysis

After 12 hour overnight fast, blood samples were drawn to determine total cholesterol, triglycerides, HDL cholesterol and apolipoproteins (apo A-I and B) concentrations at the subject-recruitment phase, in the fifth weeks of the stabilisation and washout phases, and in the fifth and sixth weeks of both phases of intervention. Total choles-erol was determined by the CHOD-PAP enzymatic method of Boehringer, Mannheim, Germany17 and triglycerides were determined by the GPO-PAP enzymatic method of Boehringer, Mannheim, Germany18. HDL cholesterol was determined by precipitation of VLDL and LDL using phosphotungstic acid-Mg++ and quantification of the cholesterol concentration in the supernatant, Boehringer, Mannheim, Germany19. Inter-assay variation coefficients were < 3% for total cholesterol, triglycerides and HDL-cholesterol. LDL-cholesterol was estimated by the Friedewald formula20. Apo A-I and Apo B were determined by the nephelometric method21 and the interassay variation coefficients were 5%.

The genotype of the apo E obtained from total blood was also determined by the standard Quiagen_ method (Izasa, Madrid, Spain) and PCR using allele-specific oligonucleotide probes to detect the cysteine-arginine interchanges at residues 112 and 158 that distinguish the three common isoforms of apo E: E2, E3 and E422.

Statistical analysis

We compared the means of the variables at the beginning and at the end of both phases of intervention using the paired Student t-test. Multivariate variance was analysed for repeated measurements with one or two factors (type of meat assigned, time and gender). The level of significance was p < 0.05.

All results are expressed as percentage and mean (standard deviation). Statistical analysis was carried out using SPSS for Windows, version 9.0.

 

Results

Subjects

The two groups of subjects were well matched with regard to baseline characteristics (table I). The subjects' weights did not change during the various phases of the study: men +0.1 (1.17) kg (p = 0.625); women +0.1 (1.03) kg, (p = 1). Subject participation was high: 100 % in programmed visits, blood analyses and nutritional records. Ninety seven of percentage came along at the hospital for the main meal. All the subjects completed the study.


Analysis of meats and menus

Table II shows that the fat contents of the lean cuts of pork and lean cuts of veal were low and that there were no differences between the two types of meat. However the content of oleic acid was significantlyhigher in pork than in veal (51.1% as opposed to 40.7%; p = 0.036), though there was no significant differences in total MUFA content between pork and veal. Neither bromatologic analysis of menus revealed significant differences in nutrients between both types of meats (table III).


Analysis of the nutritional records (table IV) showed a reduction in total energy consumption, TF, SFA, PUFA and cholesterol, and an increase in carbohydrate and dietary fibre consumption during intervention. However, there were no differences in macronutrient intake between the pork and the veal interventions, except for a slightly higher consumption of SFA during the veal phase of intervention (8.9% of energy consumed compared to 8.0 %; p <0.01) and slightly higher consumption of PUFA during the pork intervention (4% versus 2.9%; p < 0.01).

Serum lipids and lipoproteins

Lipid and lipoprotein concentrations are shown intable V, which shows the changes in lipid concentrations after each intervention, where we found no significant differences between pork consumption or veal consumption.

If there were significant differences in the total cholesterol and LDL cholesterol after both pork consumption (-5.2% and -6.5%, respectively) and veal consumption (-4.3% and -4.1%, respectively). The reduction in triglycerides was significant only after veal consumption. There were also significant decrease in the concentrations of apo A-I after both pork consumption (-8.48%) and veal consumption (-10.2%). (table V)

Multivariate analysis revealed no differences between changes to lipid concentrations after each intervention (i.e. after the first or second phase of intervention) or according to gender.

Genotype of the apo

E Thirty-four subjects (77.2%) in the study had genotype E3/E3, 8 subjects (18.2%) had genotype E4/E3, and 2 subjects (4.6%) had genotype E2/E3. When we analysed the concentrations of lipids according to genotype (see table VI), we found that the subjects with genotype E3/E3 had higher concentrations of triglycerides and LDL cholesterol than subjects with genotype E4/E3 at the baseline, but the changes observed after both interventions (pork and veal consumption) were similar for both of these genotypes.

 

Discussion

In this study, we evaluated lipid changes in healthy normolipaemic subjects after a six-week dietary intervention consisting the intake of lean cuts of pork or lean cuts of veal in the setting of a healthy diet as scientific societies recommended1,23. We found no differences between these different diets.

We had a great control over the variables that could affect the results of the study. The meats used in the study contained low levels of fat (4.5% for pork; 5.5% for veal). The same analysis showed that the cuts of pork contained slightly greater contents of PUFA and MUFA than the cuts of veal, but the only significant differences involved the greater content of oleic acid in the pork. These results are widely documented in the literature24. The pig crossbreed used in this study was a Landrace-Large White pig, which was fed a mixture of barley, wheat, corn and soy meal. This meat, which is marketed under the brand name Porcidiet (TM) and commercialized by Vaquero Meat Industries has a low intramuscular fat content (<3 %) and low cholesterol (46 mg/100g)25.

However, these differences in fatty acids profile disappeared when we analysed the nutrients and fat contents of the diets designed for the study and the nutritional composition of the menus prepared in the Hospital kitchens. We can therefore state that on a macronutrient point of view, the two types of intervention (pork and veal consumption) were similar except for the protein origin of the meats themselves.

When we analysed the subjects' nutritional records, we found that during both phases of intervention there was a decrease in energy consumption, however it was not associated with loss of weight, so energy balance was maintained. The reductions in the consumption of TF, SFA and cholesterol were similar for both phases of intervention. Studies comparing changes in serum lipid concentrations after the consumption of red meat, white meat and fish have varied greatly in the degree of control they have exercised over the variables involved. Most of these studies only controlled intake through foods records. Few of them analysed the nutritional composition of the meats6,7,10,26 or menus10,27 used.

The compliance at different level of participation in our study was practically 100%, so we can state with a fair degree of certainty what percentage of subjects complied with the dietary intervention designed for the study. In most studies we have checked, the meats were prepared at home by the subjects themselves. This introduces variability factors, such as menu preparation by the subjects and the real percentage of consumption, which depend on the subjects themselves.

Our findings show that there were no changes to serum lipid concentrations after the consumption of pork and veal, by what the null hypothesis was fulfilled. These results are similar to those of other authors who compared the consumption of red meats (beef and pork) and the consumption of fish and/or white meat (chicken) in healthy normolipaemic subjects5-8,27. Only one study (29) found a greater decrease in LDL cholesterol concentrations in subjects who had consumed fat fish than in subjects who had consumed red meat. However, during the period of study (six weeks), they found that the intake of SFA of those who had consumed red meat increased, while that of those who had consumed fat fish decreased. The beneficial effect of consuming fish as opposed to red meat is therefore probably due to a reduction in SFA intake. None of the above studies analysed the effects on serum lipids after the consumption of veal or pork; though the study by Flynn et al.7, found that the concentrations of LDL cholesterol after pork consumption and after beef consumption were similar. However, this study has some methodological bias, like the absence of controlling fat intake and the lack of a washout period between the phases of intervention.

Similar results have been found with regard to hyperlipaemic subjects in studies comparing the consumption of red meat and the consumption of white meat (chicken or fish)9-11,30, where the overall reductions in total cholesterol and LDL cholesterol after both interventions (4-6%) is attributable to the intake reduction of TF, SFA and dietary cholesterol31,32 and non by the consumption of meat. Our results are agreed in the same direction that these studies.

The reductions we found in the concentrations of apo A-I after the consumption of pork (-8.5%) and veal (-10.2%) were not different and were as expected following the reduction in total cholesterol and LDL cholesterol due to dietary intervention. The reduction in apo A-I was similar to those reported in studies involving changes from a normal diet to a diet rich in MUFA33.

Analysis of serum lipids according to the most common genotypes of apo E (E3/E3 and E4/E3) showed that the concentrations of triglycerides and LDL cholesterol were greater for the E3/E3 genotype than for the E4/E3 genotype. This result did not agree with previous reports34 , which found high cholesterol concentrations for E4 allele, intermediate concentrations for E3 and low concentrations for E2. This was probably due to the small sample of genotype E4/E3 (n = 8) used in our study. Changes to serum lipid concentrations according to the genotype of apo E, which were similar to those of the two genotypes analysed, also did not agree with the results of other authors35,36, who found that the reduction in lipids was greater with E4 allele. However, this result has mainly been found in hyperlipaemic subjects37 rather than in normolipaemic subjects such as those in our study.

Our study has important practical considerations, especially if we bear in mind that pork is recognised as an important part of the European diet. So, Spain is one of the countries with the highest meat consumption across Europe, achieving a 15% of daily energy intake38. In recent years, however, consumers' perceptions of pork have not been so good because they believe it contains a high amount of visible fat with a high content of saturated fatty acids. Modern techniques of pig breeding and feeding are producing a leaner meat whose lipids contain a greater proportion of unsaturated fatty acids. Actually, fatty acid composition mainly depends on genetic origin, age, weight at slaughter, feed composition and the husbandry system.

Our results show that, since both lean pork and lean veal have very little or no effect on LDL cholesterol levels, they can form part of a healthy diet that can be recommended for the general population. These findings support the general guidelines of the III NCEP23, which allow the regular consumption of lean meats of any origin (pork, veal or chicken) provided they are part of a balanced diet whose other ingredients are controlled. In conclusion, our study shows that the consumption of lean pork or veal has similar effects on the lipid profile of healthy subjects. Both types of meat can, therefore, be included in dietary guidelines for controlling SFA and dietary cholesterol.

 

Acknowledgements

This work was supported by grant FIS 98/0679 and the Vaquero Foundation.

 

References

1. Mata P, De Oya M, Pérez Jiménez, Ros E: Dieta y enfermedades cardiovasculares. Recomendaciones de la Sociedad Española de Arteriosclerosis. Clin Invest Arterioscler 1994; 6: 43-61.        [ Links ]

2. Willet WC, Sacks F, Trichopoulou A, Drescher G, Ferro-Lucci A, Helsing E et al (1995): Mediterranean diet pyramid: a cultural model for health eating. Am J Clin Nutr 1995; 61 (suppl): 1402S-6S.        [ Links ]

3. Denke M: Role of beef talow, and an enriched source of stearic acid, in a cholesterol-lowering diet. Am J Clin Nutr 1994; 60(suppl):1044S-1049S.        [ Links ]

4. Morgan S, Sinclair A, O'Dea K: Effect on serum lipids of addition of safflower oil or olive oil to very-low-fat diets rich in lean beef. J Am Diet Assoc 1993; 93:644-648.        [ Links ]

5. O'Brien BC, Reiser R: Human plasma lipid responses to red meat, poultry, fish, and eggs. Am J Clin Nutr 1980; 33: 2573- 80.        [ Links ]

6. Flynn MA, Heine B, Nolph GB, Naumann HD, Parisi E, Ball D et al.: Serum lipids in humans fed diets containing beef or fish and poultry. Am J Clin Nutr 1981; 34: 2734-41.        [ Links ]

7. Flynn MA, Naumann HD, Nolph GB, Krause G, Ellersieck M: Dietary "meats" and serum lipids. Am J Clin Nutr 1982; 35: 935-42.         [ Links ]

8. Jacques H, Noreau, Mooorjani S: Effects on plasma lipoproteins and exogenous sex hormones of substituting lean white fish for other animal-protein sources in diet of postmenopausal women. Am J Clin Nutr 1992; 55:896-901.        [ Links ]

9. Watts GF, Ahmed W, Quiney J, Houlston R, Jackson P, Iles C et al.: Effective lipid lowering diets including lean meat. BMJ 1988; 296: 235-7.        [ Links ]

10. Scott LW, Dunn JK, Pownall HJ, Brauchi DJ, McMann MC, Herd A et al.: Effects of beef and chicken consumption on plasma lipid levels in hypercholesterolemic men. Arch Intern Med 1994; 154:1261-7.        [ Links ]

11. Davidson MH, Hunninghake D, Maki KC, Kwiterovich PO, Kafonek S: Comparison of the effects of lean red meat vs lean white meat on serum lipid levels among free-living persons with hypercholesterolemia: a long-term, randomized clinical trial. Arch Inter Med 1999; 159:1331-8.        [ Links ]

12. Ministerio de Agricultura, Pesca y Alimentación. La alimentación en España 2001. Madrid: Ministerio de Agricultura, Pesca y Alimentación, 2001.        [ Links ]

13. Association of Official Analytical Chemists. In Official Methods of analysis. 14th ed. Arlington,Va: Association of Official Analytical Chemists, 1984.        [ Links ]

14. Prosky L, Asp NG, Scweizer TF, DeVries JW, Furda I: Determination of insoluble, soluble, and total dietary fiber in foods and food products: interlaboratory study. J Assoc off Anal Chem 1988; 71:1017-1023.        [ Links ]

15. Jimenez A, Cervera P, Bacardi M: Tablas de composición de los alimentos. Barcelona: Novartis Nutrition; 1997.         [ Links ]

16. Alpers DH, Stenson WF, Bier DM: Protein and Calories: requirements, intake, and assessment. In: Manual of nutritional therapeutics, 3rd ed. Alpers DH, Clouse RE, Stenson WF, 1995: 73-114.        [ Links ]

17. Allain CC, Poons LS, Chang CS, Richmond W, Fu PC: Enzymatic determination of total serum cholesterol. Clin Chem 1974; 20:470-475.        [ Links ]

18. Buccolo G, David H: Quantitative determination of serum tryglycerides by use of enzymes. Clin Chem 1973; 19: 476- 482.        [ Links ]

19. Assmann G, Shrlewer H, Schmitz G: Quantification of high density lipoprotein cholesterol by precipitation with fosfotungstic acid/MgCl2. Clin. Chem 1983; 29: 2026-2030.        [ Links ]

20. Friedewald WT, Levy IR, Fredrickson DS: Estimation of the concentration of low density lipoprotein cholesterol in plasma without use of the preparative ultracentrifuge. Clin Chem 1972; 18 :499-502.        [ Links ]

21. Marcovina SM, Albers JJ, Henserson O, Hannon WH: International Federation of Clinical Chemistry Standardization Project for Measurements of Apolipoproteins A-I and B III. Comparability of Apolipoprotein A-I Values by Use of International Reference Material. Clin Chem 1993; 39: 773-781.        [ Links ]

22. Green EK, Bain SC, Day PJ, Barnett AH, Charleson F, Jones AF et al.: Detection of human apolipoprotein E3, E2, and E4 genotypes by an allele-specific oligonucleotide-primed polymerase chain reaction assay: development and validation. Clin Chem 1991; 37:1263-1268.        [ Links ]

23. National Cholesterol Education Program (NCEP) Expert Panel on Detection, Evaluation, and Treatment of High Blood Cholesterol in Adults (Adult Treatment Panel III). Third Report of the National Cholesterol Education Program (NCEP) Expert Panel on Detection, Evaluation, and Treatment of High Blood Cholesterol in Adults (Adult Treatment Panel III) final report. Circulation 2002; 106(25):3143-421.        [ Links ]

24. Enser M, Hallett K, Hewitt B, Fursey AJ, Wood JD: Fatty acid content and composition of english beef, Lamb and pork at retail. Meat Science 1996; 42:443-456.        [ Links ]

25. Toldrá F, Rubio MA, Navarro JL, Cabrerizo L: Quality aspects of pork meat and its nutritional impact. In: Quality of fresh and processed foods. Advances in Experimental Medicine and Biology. Shahidi F, Spanier AM, Ho CT, Braggins T, ed. New York, Kluwer Academic/Plenum Publishers, 2004; 542:25-31.        [ Links ]

26. O'Dea K, Traianedes K, Chisholm K, Leyden H, Sinclair AJ: Cholesterol-lowering effect of a low-fat diet containing lean beef is reversed by the addition of beef fat. Am J Clin Nutr 1990; 52: 491-4.        [ Links ]

27. Marckmann P, Jespersen J, Leth T, Sandström B: Effect of fish diet versus meat diet on blood lipids, coagulation and fibrinolysis in healthy young men. J Inter Med 1991; 229:317-323.        [ Links ]

28. Gascon A, Jacques H, Moorjani S, Deshaies Y, Brun L-D, Julien P: Plasma lipoprotein and lipolytic activities in response to the substitution of lean white fish for other animal protein sources in premenopausal women. Am J Clin Nutr 1996; 63:315-321.        [ Links ]

29. Wolmarans P, Benadé AJS, Kotze TJW, Daubitzer AK, Marais MP, Laubscher R: Plasma lipoprotein response to substituting fish for read meat in the diet. Am J Clin Nutr 1991; 53: 1171-6.        [ Links ]

30. Beauchesne-Rondeau E, Gascon A, Jacques H: Plasma lipids and lipoporteins in hypercholesterolemic men fed a lipid-lowering diet containing lean beef, lean fish, or poultry. Am J Clin Nutr 2003; 77:587-593.        [ Links ]

31. Howell WH, McNamara DJ, Tosca MA, Smith BT, Gaines JA: Plasma lipid and lipoprotein responses to dietary fat and cholesterol: a meta-analysis. Am J Clin Nutr 1997; 65:1747-64.        [ Links ]

32. Tang JL, Armitage JM, Lancaster T, Silagy CA, Fowler GH, Neil HAW: Sytematic review of dietary intervention trials to lower blood total cholesterol in free-living subjects. BMJ 1998; 316:1213-1220.        [ Links ]

33. Mata P, Garrido JA, Ordovas JM, Blazquez E, Alvarez-Sala L, Rubio MJ et al.: Effect of dietary monounsaturated fatty acids on plasma lipoproteins and apolipoproteins in women. Am J Clin Nutr 1992; 56:77-83.        [ Links ]

34. Sing CF, Davignon J: Role of the apolipoprotein E polymorphism in determining normal plasma lipid and lipoprotein variation. Am J Hum Genet 1985; 37:268-285.        [ Links ]

35. Tikkanen MJ, Huttunen JK, Enholm C, Pietinen P: Apolipoprotein E4 homozygosity predisposes to serum cholesterol elevation during high fat diet. Arteriosclerosis 1990; 10: 285- 288.        [ Links ]

36. Manttari M, Kosninen P, Enholm C, Huttunen JK, Manninen V: Apolipoprotein E polymorphism influences the serum cholesterol response to dietary intervention. Metabolism 1991; 40:217-221.        [ Links ]

37. Zambón D, Ros E, Casals E, Sanllehy C, Bertomeu A, Campero I: Effect of apolipoprotein E polymorphism on the serum lipid response to a hypolipidemic diet rich in monounsaturated fatty acids in patients with hypercholesterolemia and combined hyperlipidemia. Am J Clin Nutr 1995; 61:141-148.        [ Links ]

38. Linseisen J, Kesse E, Slimani N, Bueno-de-Mesquita HB, Ocké MC, Skeie G et al.: Meat consumption in the European Prospective Investigation into Cancer and Nutrition (EPIC) cohorts: results from 24-hour dietary recalls. Public Health Nutr 2002; 5 (6B): 1243-1258.        [ Links ]

 

 

Correspondencia:
J. A Rubio
Department of Endocrinology and Nutrition.
Hospital Universitario Príncipe de Asturias.
Carretera Alcalá Meco s/n. Alcalá de Henares.
Madrid 28800. Spain.
E-mail: josearubio@terra.es

Recibido: 0-IV-2005.
Aceptado: 06-VI-2005.

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