Contents of conjugated linoleic acid isomers in commercial ruminant-derived foods

Data on the total (mg/g product) and specific (mg/g fat) CLA contents and its individual isomers (% of CLA isomers) in the most consumed Portuguese ruminant-derived foods are displayed in Table 2. The highest total CLA concentration was found in butter (2·64 mg/g product) and cheese (1·09 mg/g product) due to the high fat content present in these products. Lamb meat was the third richest product in total CLA (0·95 mg CLA/g meat). Yoghurt and intensively produced beef depicted residual CLA contents (0·06 mg/g product). CLA specific contents among meats ranged from 4·45 (intensively produced beef) to 11·29 mg/g fat (lamb meat). While milk showed a still remarkably high specific CLA content (7·22 mg CLA/g fat), the remaining products displayed considerably lower but similar concentrations, ranging from 4·00 to 4·97 mg/g fat. Lamb meat is usually originated from grass feeding systems and it is well known that the inclusion of grass in the diet improves CLA content in meatReference French, Stanton, Lawless, O'Riordan, Monahan, Caffrey and Moloney^28, Reference Alfaia, Castro, Martins, Portugal, Alves, Fontes, Bessa and Prates²⁹. Compared with available data, Chin et al. Reference Chin, Liu, Storkson, Ha and Pariza³⁰ encountered a concentration of 5·5 mg CLA/g fat in homogenised milk. The specific CLA contents in butter and yoghurt were similar to those reported by Ma et al. Reference Ma, Wierzbicki, Field and Clandinin¹⁴ (4·7 and 4·4 mg/g fat, for butter and yoghurt, respectively). For yoghurt, Chin et al. Reference Chin, Liu, Storkson, Ha and Pariza³⁰ reported 4·8 mg CLA/g fat, whereas Lin et al. Reference Lin, Boylston, Chang, Luedecke and Shultz³¹ found a concentration of 3·8 mg CLA/g fat. Regarding cheese, Shantha et al. Reference Shantha, Decker and Ustunol³² measured CLA contents varying from 3·2 to 8·9 mg/g fat, an interval that includes our calculated concentration of 4·86 mg CLA/g fat. Chin et al. Reference Chin, Liu, Storkson, Ha and Pariza³⁰ reported concentrations ranging from 2·7 mg CLA/g fat in veal to 4·3 mg CLA/g fat in fresh ground beef, this interval being close to the concentrations found in the present study for intensive and traditional meat samples. Also, Shantha et al. Reference Shantha, Crum and Decker³³ described variations in CLA contents in raw steaks (ribeye, round, t-bone and sirloin) varying from 3·1 to 8·5 mg/g fat. The differences reported on CLA content in ruminant fatty acid composition may be explained by the influence of dietary factors (production system) and, to a lesser extent, by genetic factorsReference De Smet, Raes and Demeyer³⁴. French et al. Reference French, Stanton, Lawless, O'Riordan, Monahan, Caffrey and Moloney²⁸ reported that meat fat from grazing steers displays higher CLA contents (10·8 mg/g fatty acids) than those obtained from animals fed concentrate (3·7 mg/g fatty acids). Additionally, discrepancies in the CLA content between different animal tissues, different breeds or upbringing, and even within the same breed, have already been reported and reviewed by Schmid et al. Reference Schmid, Collomb, Sieber and Bee³⁵. Regarding CLA in dairy products, Collomb et al. Reference Collomb, Sieber and Butikofer^7, Reference Collomb, Bütikofer, Sieber, Jeangros and Bosset³⁶ concluded that the quality of milk and ripened cheese is influenced by many factors, including the composition of fodder consumed and the altitude at which the cow grazes.

Table 2 Values of total (mg/g product) and specific (mg/g fat) conjugated linoleic acid (CLA) contents, and its isomeric distribution (% of CLA isomers), in the most consumed ruminant-derived milk, dairy products and meats by the Portuguese population

(Mean values and standard deviations)

n.d., Not detected.

* Values expressed in mg/ml product.

† Values of each isomer as percentage of the total CLA isomers identified in each product.

‡ This CLA isomer co-eluted with minor amounts of the trans-8, cis-10 isomer.

The CLA isomeric profile of the analysed foods is presented in Table 2. In general, CLA distribution showed a clear predominance of the bioactive c9, t11 isomer (59·89–79·21 %), followed by the t7, c9 isomer (8·04–20·20 %), which co-eluted with minor amounts of the trans-8, cis-10 isomer. Similarly to total CLA content, diet is the major factor that affects the profile of CLA in ruminant fatsReference Dannenberger, Nuernberg, Nuernberg, Scollan, Steinhart and Ender^37, Reference De La Torre, Gruffat, Durand, Micol, Peyron, Scislowski and Bauchart³⁸. Moreover, many of the differences in CLA profile appear to be related to pasture v. concentrate feeding. In the present study, lamb meat (pasture fed) showed higher percentages of the trans-11, cis-13 (t11, c13), trans-11, trans-13 and trans-12, trans-14 isomers and lower of the t7, c9 isomer, when compared with intensively and traditionally produced beefs. These differences may be explained by distinct grass intake of the animals since it was shown that pasture feeding, compared with concentrate feeding, increases the proportion of the t11, c13, trans-11, trans-13 and trans-12, trans-14 isomers and decreases the percentage of the t7, c9 isomer in beef lipidsReference Dannenberger, Nuernberg, Nuernberg, Scollan, Steinhart and Ender³⁷. Based on these results, Dannenberger et al. Reference Dannenberger, Nuernberg, Nuernberg, Scollan, Steinhart and Ender³⁷ suggested that the t11, c13-, trans-12, trans-14- and trans-11, trans-13-CLA isomers are sensitive grass intake indicators. Breed and muscle type have also been reported as determinant of t11, c13 isomer percentage in beef lipidsReference Dannenberger, Nuernberg, Nuernberg, Scollan, Steinhart and Ender³⁷. Regarding the CLA profile of intensively produced beef, the most abundant isomer was the c9, t11 (59·89 %) followed, in decreasing order, by the trans-7, trans-9 isomer (15·03 %) and the t7, c9 isomer (12·09 %). The t7, c9 isomer is mentioned frequently as the second most prevalent CLA isomerReference Yurawecz, Roach, Sehat, Mossoba, Kramer, Fritsche and Steinhart³⁹ and, like the most abundant c9, t11 isomer, its content in milk and tissues mainly results from endogenous synthesis through the Δ9-desaturation of the rumen-derived trans-octadecenoate precursorReference Palmquist, St-Pierre and McClure⁶. With the exception of the c9, t11 and t7, c9 isomers, the origin of all other CLA isomers is the ruminal biohydrogenation of dietary unsaturated C18 fatty acids, although the metabolic pathways producing these compounds are not yet elucidatedReference Collomb, Sieber and Butikofer⁷. The t10, c12 isomer, which apparently affects lipid metabolismReference Pariza, Park and Cook¹⁰, was present in very small proportions (0·01–2·12 %), reaching the highest levels in beef, from either intensive or semi-extensive production systems. In the trans, trans region, the most abundant isomer was the trans-9, trans-11, ranging from 1·16 to 2·21 % of total CLA. The sums of trans, trans (5·65–8·01 %) and cis/trans (90·99–93·23 %) CLA isomers were similar in all analysed products, except for the intensively produced beef, which were 18·71 and 80·21 % for trans, trans and cis/trans, respectively. The sum of the cis, cis CLA isomers only showed residual contents for all analysed products ( <  1·42 %).

Estimation of the daily intake of conjugated linoleic acid isomers

Table 1 reports an estimation of the contribution of ruminant-derived foods for the daily intake of Portuguese consumers, per individual, of total and individual CLA isomers. Usually dietary intake is assessed by 3 or 7 d dietary records, representing the diet of a medium-term period, or by food-frequency questionnaires, expected to reflect the regular dietReference Freudenheim⁴⁰. Additional to these methodologies, Ritzenthaler et al. Reference Ritzenthaler, McGuire, Falen, Shultz, Dasgupta and McGuire⁴¹ also conducted chemical analysis of food duplicates and concluded that daily CLA intake is underestimated by written dietary methods. In the present study, neither of these methodologies was applied. The calculation was done, as described earlier, by attending to the CLA contents determined in ruminant-derived products commercially available in Portugal (see Table 2) and the consumption data (per individual and d) of each product, according to the most recent national statistics²⁷. The average daily intake of total CLA was estimated as being 73·70 mg/individual. This value may be slightly underestimated since non-ruminant-derived products (for example, meat, fish, plant crisps, chocolates, cakes and pastries) may have, as stated earlier, minor CLA contentsReference Jahreis and Kraft^15, Reference Fritsche and Steinhart¹⁶. The major food sources contributing to this value were cheese and milk (40·10 and 24·38 %, respectively), followed, in decreasing order, by butter (15·66 %) and lamb meat (11·07 %). Traditionally produced beef contributed only 0·12 % to the total CLA intake. Reflecting the food isomeric distribution, c9, t11 (76·10 %) and t7, c9 (12·56 %) were the main isomers present in the diet, as illustrated in Fig. 1. The third most important isomer was t11, c13, contributing 2·22 % to the daily intake. The trans-11, trans-13-, trans-9, trans-11- and t7, t9-CLA isomers were the most relevant in the trans, trans isomers region.

Fig. 1 Conjugated linoleic acid (CLA) isomeric distribution of the estimated daily CLA intake for the Portuguese population.

Depending on the country, the estimation of average CLA or c9, t11 consumption ranges between 15 and 1000 mg (Table 3). Even if the major food sources of CLA remain constant, their relative contributions to dietary intake may vary with food availability and eating preferencesReference Schmid, Collomb, Sieber and Bee³⁵. Based on milk consumption data, Wolff & PrechtReference Wolff and Precht⁴² estimated the c9, t11 ingestion in fifteen European countries, obtaining higher intake values in North Europe and lower in Mediterranean countries. According to these authors, France and Italy showed consumption values close to the European Union average and similar daily ingestions were observed for Spain (140 mg), Greece (150 mg) and Portugal (150 mg). The difference from our values for Portugal might be explained by the distinct estimation methods and statistics sources used. In Germany, the overall estimated c9, t11 consumption reported by Fritsche & SteinhartReference Fritsche and Steinhart¹⁶ was relatively high (350 and 430 mg/d for women and men, respectively), by 1-week dietary records. Based on the same method, an assessment of c9, t11 intake in a small group of young Canadians determined an average ingestion of 94·9 mg/d, ranging between 15 and 174 mg/dReference Ens, Ma, Cole, Field and Clandinin⁴³, which is not very far from our determination for this particular isomer (see Table 1). Ritzenthaler et al. Reference Ritzenthaler, McGuire, Falen, Shultz, Dasgupta and McGuire⁴¹ reported that young men and women living in the USA consumed about 151–212 and 140–193 mg/d for total CLA and c9, t11, respectively, by 3 d food duplicates. In agreement with that study, Herbel et al. Reference Herbel, McGuire, McGuire and Shultz⁴⁴ reported, for the same country and by using the same methodology, the daily intake of 127 mg CLA. McGuire et al. Reference McGuire, McGuire, Ritzenthaler, Shultz, Yurawecz, Mossoba, Kramer, Pariza and Nelson⁴⁵ advanced two possible reasons for the higher CLA intake for Germany compared with those for USA: more fat consumption in Germany and vast food nutrient database used. In Table 3, Australia shows the highest CLA consumption, 500–1000 mg/dReference Parodi⁴⁶, although the estimation method applied is unknown. Nutritional habits are also dependent on sex, although the lack of consumption statistics per woman and man did not allow taking this variable into account in the present study. Additionally, the present study differs from its counterparts presented in Table 3 since CLA concentration in food was determined by Ag⁺-HPLC, in contrast to GC.

Table 3 Average conjugated linoleic acid (CLA) intake (mg/d) estimated for several countries

DR, dietary records; FD, food duplicates; FFQ, food-frequency questionnaires.

* The methods for CLA intake estimation were based on either the estimation of milk intake (milk intake), DR, FD or FFQ.

The importance of CLA in human nutrition is related to its anticarcinogenic activityReference Yamasaki, Miyazaki, Yamada, Yurawecz, Kramer, Gudmundsen, Pariza and Banni⁹. Levels of CLA as low as 0·1 % in the diet have been seen as sufficient to produce a significant decrease in mammary tumour yield in rats challenged with a low dose of 7,12-dimethylbenz[a]anthraceneReference Ip, Scimeca and Thompson⁴⁷. The daily CLA intake in Portugal is 0·0038 % (intake of 1916·9 g food/d based on Portuguese statistics from Instituto Nacional de Estatística⁴⁸), which only represents 3·8 % of the above recommended value. Moreover, at a 0·1 % dosage of CLA, a 300 g rat will consume approximately 0·015 g CLA/d. Extrapolating directly to a 70 kg man or woman, CLA consumption per d has to equal 3 g to confer a similar health benefitReference Ip, Scimeca and Thompson⁴⁷. However, differences in metabolic rate (particularly, in lipid metabolism) between these two species require a more suitable extrapolation from a rat model to man, using the metabolic weightReference Terpstra⁴⁹. Such extrapolation indicates that 0·8 g CLA/d would be protective in man. Therefore, on the basis of the anticancer effects of CLA in rats, as experimental models, a daily consumption of 0·8–3·0 g CLA might provide a significant human health benefitReference Parish, Wiegand, Beitz, Ahn, Du, Trenkle, Sébédio, Christie and Adlof⁵⁰. One of the few epidemiological studies relating the incidence of breast cancer in postmenopausal Netherlands women and levels of CLA intake showed a positive, although weak, correlation (P for trend = 0·02) between 200 mg CLA intake per d and this cancer occurrenceReference Voorrips, Brants, Kardinaal, Hiddink, van den Brandt and Goldbohm⁵¹. Another study associated high fat consumption, including CLA, with colorectal cancer incidence in Swedish women (P for trend = 0·002) aged 40–76 yearsReference Larsson, Bergkvist and Wolk⁵². These authors concluded that high intakes of high-fat dairy foods, containing at least 127·8 mg CLA/d, may reduce the risk of colorectal cancer. Actually, in several countries, levels as high as the above-mentioned are consumed (see Table 3). However, it is well known that cancer is a multifactorial disease and, therefore, many other factors besides diet components still determine its occurrence. As being so, facing the relatively low ingestion value for Portugal presented in the present study (73·70 mg CLA/d), no preventive carcinogenic effects of CLA are expected to be found for the Portuguese population. A possible solution in order to reach beneficial values of CLA in the diet is through supplementation. Of note, dietary supplements have a different CLA isomeric profile compared with foodstuffs. The main difference concerns the high percentage of t10, c12 in supplements and some studies have recently demonstrated adverse effects of this isomer on human healthReference Risérus, Basu, Jovinge, Fredrikson, Arnlov and Vessby¹¹.

Several authors have used indirect methodologies to estimate both typical and extreme intakes of CLA in a limited number of populations. However, in the present study we present an unparalleled and detailed overview of CLA isomeric profile in dairy and meat products, which allowed the direct estimation of daily CLA intake for the Portuguese population. In human trials, synthetic CLA supplements are usually used and these do not reflect the natural isomeric composition in foodstuffs. Whether natural CLA sources (meat, milk and its derivatives from ruminant animals) have a similar impact on human health warrants further research (for a review, see Schmid et al. Reference Schmid, Collomb, Sieber and Bee³⁵). Essentially, examination of the relationships among dietary intake of CLA isomers, their contents in adipose tissue and plasma and risk of various chronic degenerative diseases (for example, cancer, diabetes, and atherosclerosis) is essential for scientists and public health officials to draw conclusions concerning the importance of dietary CLA (and its isomers) to human health. Studies are actually in progress to clarify these questions. Therefore, enhancing our knowledge concerning CLA isomeric profile in various populations must remain a primary focus for research in this area.