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Individual cow variation on milk polyunsaturated fatty acids

Published online by Cambridge University Press:  13 May 2013

S. Stergiadis ,
C. Leifert ,
C. J. Seal ,
M. D. Eyre  and
G. Butler
S. Stergiadis
Affiliation:
Nafferton Ecological Farming Group, School of Agriculture Food and Rural Development, Newcastle University, Nafferton Farm, Stocksfield, Northumberland, NE43 7XD, UK
C. Leifert
Affiliation:
Nafferton Ecological Farming Group, School of Agriculture Food and Rural Development, Newcastle University, Nafferton Farm, Stocksfield, Northumberland, NE43 7XD, UK
C. J. Seal
Affiliation:
Human Nutrition Research Centre, School of Agriculture, Food & Rural Development Newcastle University, Newcastle upon Tyne, NE1 7RU, UK.
M. D. Eyre
Affiliation:
Nafferton Ecological Farming Group, School of Agriculture Food and Rural Development, Newcastle University, Nafferton Farm, Stocksfield, Northumberland, NE43 7XD, UK
G. Butler
Affiliation:
Nafferton Ecological Farming Group, School of Agriculture Food and Rural Development, Newcastle University, Nafferton Farm, Stocksfield, Northumberland, NE43 7XD, UK
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Abstract

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Proceedings of the Nutrition Society , Volume 72 , Issue OCE2: Scottish Section Meeting, 18–19 March 2013, Polyunsaturated fatty acid mediators: implications for human health , 2013 , E109
Copyright
Copyright © The Authors 2013 

Milk fat composition is influenced by dairy feeding with grazing and oilseed supplementation recognised as means of elevating polyunsaturated fatty acids (PUFA) concentration in milk. Differences in PUFA content of milk have been reported between farming systems( Reference Stergiadis, Seal and Leifert 1 ), dairy ‘brand’ as well as season and year of production( Reference Butler, Stergiadis and Seal 2 )). However, such studies using milk bulked from a number of cows or farms give no indication of variation between individual cows and hence the scope for selective breeding to increase milk PUFA content is reduced.

Milk collected during two feeding trials was used to assess individual variation in cows' response to feeding practices aimed at increasing the PUFA content of winter milk. Rapeseed and two levels of linseed supplementation were compared with control diets, against the background of both organic and conventional management. Milk fatty acid (FA) profiles of individual milk samples were determined by gas chromatography( Reference Butler, Stergiadis and Seal 2 )).

Fig. 1. Variation (max and min values & interquartile range; bar=median) for PUFA.

Fig. 2. omega-6 FA (n-6).

Fig. 3. conjugated c9t11 C18:2 (c9t11 CLA).

Fig. 4. α-linolenic (ALA), and long chain omega-3 FA (LC n-3).

Fig. 5. in milk (Con; conventional, Org; organic), where control diets (Ctr) were supplemented with linseed (Lin1;1.5 kg/cow per day, Lin2; 2.0 kg/cow per day) or rapeseed (Rape; 1.2 kg/cow per day).

Comparing the range between 1st and 3rd quartile relative to median concentrations, n-6 and PUFA were more consistent across treatments than c9t11 CLA and n-3, although, due to their higher levels, the ranges were actually greater in absolute terms.

Generally, diets expected to increase milk PUFA concentrations (organic production or oilseed feeding) did result in a wider range of n-3 and c9t11 CLA concentrations, suggesting some cows showed a better response to this opportunity. The unexplained exception to this statement relates to cows on the high linseed diet, showing depressed and more uniform milk LC n-3 concentrations.

Results suggest challenging cows with elevated dietary PUFA allows the opportunity for some to express their superior ability to transfer n-3 and CLA into milk, although care might be needed to interpret LC n-3 results.

We are grateful for funding from the EU (Quality Low Input Food and Low Input Breeds projects), Greek State's Scholarship Foundation and Yorkshire Agricultural Society.

References

1. Stergiadis, S, Seal, C, Leifert, C et al. (2012) J. Agric. Food Chem. 60, 72707281.Google Scholar
2. Butler, G, Stergiadis, S, Seal, C et al. (2011) J. Dairy Sci. 94, 2436.Google Scholar
Figure 0

Fig. 1. Variation (max and min values & interquartile range; bar=median) for PUFA.

Figure 1

Fig. 2. omega-6 FA (n-6).

Figure 2

Fig. 3. conjugated c9t11 C18:2 (c9t11 CLA).

Figure 3

Fig. 4. α-linolenic (ALA), and long chain omega-3 FA (LC n-3).

Figure 4

Fig. 5. in milk (Con; conventional, Org; organic), where control diets (Ctr) were supplemented with linseed (Lin1;1.5 kg/cow per day, Lin2; 2.0 kg/cow per day) or rapeseed (Rape; 1.2 kg/cow per day).