Pasture feeding improves the nutritional, textural and techno-functional characteristics of butter

Abstract

There is an increasing consumer desire for pasture-derived dairy products, as outdoor pasture-based feeding systems are perceived as a natural environment for animals. Despite this, the number of grazing animals globally has declined as a result of the higher milk yields achieved by indoor, total mixed ration feeding systems, in addition to the changing climatic conditions and lower grazing knowledge and infrastructure. This has led to the development of pasture-fed standards, stipulating the necessity of pasture and its minimum requirements as the primary feed source for products advertising such claims, with various requirements depending on region for which it was produced. This work investigates the differences in the composition and techno-functional properties of butters produced from high, medium and no pasture allowance diets during early, mid and late lactation. Butters were produced using milks collected from 3 feeding systems: outdoor pasture grazing (GRS; high pasture allowance); indoor total mixed ration (TMR; no pasture allowance); and a partial mixed ration (PMR; medium pasture allowance) system, which involved outdoor pasture grazing during the day and indoor TMR feeding at night. Butters were manufactured during early, mid and late lactation. Creams derived from TMR feeding systems exhibited the highest milk fat globule size. The fatty acid profiles of butters also differed significantly as a function of diet, and could be readily discriminated by partial least squares analysis. The most important fatty acids in such analysis, as indicated by their highest variable importance projection scores, were CLA C18:2 cis-9 trans-11 (rumenic acid), C16:1 n-7 trans (trans-palmitoleic acid), C18:1 trans (elaidic acid), C18:3 n-3 (α-linolenic acid) and C18:2 n-6 (linoleic acid). Increasing pasture allowances resulted in reduced crystallization temperatures and hardness of butters, while concurrently increasing the 'yellow' b* color. Yellow color was strongly correlated with Raman peaks commonly associated with carotenoids. The milk fat globule size of cream decreased with advancing stage of lactation and churning time of cream was lowest in early lactation. Differences in the fatty acid and triglyceride contents of butter as a result of lactation and dietary effects demonstrated significant correlations with the hardness, rheological, melting and crystallization profiles of the butters. This work highlighted the improved nutritional profile and functional properties of butter with increasing dietary pasture allowance, primarily as a result of increasing proportions of unsaturated fatty acids. Biomarkers of pasture feeding (response in milk proportionate to the pasture allowance) associated with the pasture-fed status of butters were also identified as a result of the significant changes in the fatty acid profile with increasing pasture allowance. This was achieved through the use of 3 authentic feeding systems with varying pasture allowances, commonly operated by farmers around the world and conducted across 3 stages of lactation.