The impact of seasonal calving systems with varying pasture allowance on Cheddar cheese composition, nutritional quality and ripening characteristics

The objective of this study was to examine the impact of stage of lactation (early, mid and late) and proportion of pasture in the cows diet (high: GRS, medium: PMR and no: TMR) on the composition and quality of Cheddar cheese. Triplicate trials were carried out in each stage of lactation, and milk protein and fat contents were standardized for Cheddar cheese manufacture at pilot scale. As cheese milks were standardized for milk fat and protein contents, gross composition did not differ as a result of diet. Fatty acid profiles of GRS cheese were significantly different from TMR, while PMR profiles were less distinct and more similar to both GRS and TMR profiles, as illustrated by partial least squares discriminatory analysis. Fatty acids including CLA C18:2 cis-9, trans-11, C22:1 n-9 and C18:3 n-3 were most influential in this separation of profiles. Fatty acid profiling revealed that GRS derived cheese contained higher proportions of nutrients considered beneficial for human health including higher proportions of unsaturated fatty acids and omega-3 fatty acids. A biomarker model utilizing the proportions of 5 fatty acids was constructed and was effective at distinguishing between cheese of GRS, TMR and PMR feeding systems. Proportions of ρ-κ-casein, αs2-casein and αs1-casein in cheese also differed between diets while proportions of ρ-κ-casein, αs1-casein and β-casein were lowest in late lactation cheese. The impact of diet was less influential compared with that of stage of lactation on the ripening characteristics of cheese. An index of primary proteolysis was highest in late lactation cheese. The peptides derived from the proteolysis of κ-casein and β-casein and levels of secondary proteolysis, in particular, the proportions of 12 free amino acids were most influenced by stage of lactation. Overall this study demonstrated the effects of increasing pasture allowance and stage of lactation on the nutritional quality and ripening properties of Cheddar cheese.

Influence of different systems for feeding supplements to grazing dairy cows on milk fatty acid composition

This study investigated the effects of different strategies for feeding supplements to grazing dairy cows on the proportions of fatty acids in milk. Two hundred and sixteen cows were fed supplementary grain and forage according to one of 3 different strategies; (1) Control: cows grazed perennial ryegrass pasture (14 kg dry matter/d) supplemented with milled barley grain fed in the milking parlour and pasture silage offered in the paddock; (2) Partial mixed ration 1 (PMR1): same pasture allotment and supplement as Control strategy, but the supplements presented as a mixed ration after each milking in feedpad, and; (3) Partial mixed ration 2 (PMR2): same pasture allotment, supplemented with a mixed ration of milled barley grain, alfalfa hay, corn silage and crushed corn grain fed in a feedpad. Within each strategy, cows were assigned to receive either 6, 8, 10 or 12 kg dry matter supplement/cow per d. Milk fatty acid proportions from cows fed Control and PMR1 strategies were similar and different from those fed PMR2, particularly at 10 to 12 kg dry matter supplement/cow per d. The reduction in milk fat yield and concentration in cows fed high amounts of supplement as Control and PMR1 was coincident with 4 × increase in 10t-18:1 proportion. The composition of the partial mixed ration (PMR) and the amount offered affected milk fatty acid proportions and milk fat content, however, the method of supplementation did not.

Milk production and composition of mid-lactation cows consuming perennial ryegrass-and chicory-based diets

Dry matter intakes (DMI), nutrient selection, and milk production responses of dairy cows grazing 3 herbage-based diets offered at 2 allowances were measured. The 2 allowances were 20 (low) and 30 (high) kg of dry matter (DM)/cow per day and these were applied to 3 herbage types: perennial ryegrass (PRG) and chicory (CHIC+) monocultures and a mixed sward of chicory and perennial ryegrass (MIX). The CHIC+ diet was supplemented with alfalfa hay (approximately 2 kg of DM/cow per day) to maintain dietary neutral detergent fiber (NDF) concentration and all diets were supplemented with energy-based pellets (6 kg of DM/cow per day). Holstein-Friesian dairy cows averaging 136 ± 30 d in milk were allocated to 4 replicates of the 6 treatments using stratified randomization procedures. Cows were adapted to their experimental diets over a 14-d period, with measurements of DMI, milk yield, and composition conducted over the following 10 d. Herbage DMI was lowest (12.8 vs. 14.0 kg of DM/d) for CHIC+ compared with the MIX and PRG, although total forage intake (grazed herbage plus hay) was similar (14.0 to 15.0 kg of DM/d) across the 3 treatments. Milk production, milk protein, and milk fat concentrations were not different between herbage types. Grazed herbage DMI increased with increasing herbage allowance and this was associated with increased milk protein concentration (3.23 to 3.34%) and total casein production (41.7 to 43.6 mg/g). Concentrations of polyunsaturated fatty acids in milk fat, particularly linoleic acid, were increased in milk from cows offered the CHIC+ or the MIX diets, indicating potential benefits of chicory herbage on milk fatty acid concentrations. Although feeding CHIC+ or MIX did not increase milk yield, these herbage types could be used as an alternative to perennial ryegrass pasture in spring.

Ultrasound effects on the assembly of casein micelles in reconstituted skim milk

Reconstituted skim milks (10 % w/w total solids, pH 6·7-8·0) were ultrasonicated (20, 400 or 1600 kHz at a specific energy input of 286 kJ/kg) at a bulk milk temperature of <30 °C. Application of ultrasound to milk at different pH altered the assembly of the casein micelle in milk, with greater effects at higher pH and lower frequency. Low frequency ultrasound caused greater disruption of casein micelles causing release of protein from the micellar to the serum phase than high frequency. The released protein re-associated to form aggregates of smaller size but with surface charge similar to the casein micelles in the original milk. Ultrasound may be used as a physical intervention to alter the size of the micelles and the partitioning of caseins between the micellar and serum phases in milk. The altered protein equilibria induced by ultrasound treatment may have potential for the development of milk with novel functionality.

Variation in nutritionally relevant components in retail Jersey and Guernsey whole milk

This study investigates the quality of retail milk labelled as Jersey & Guernsey (JG) when compared with milk without breed specifications (NS) and repeatability of differences over seasons and years. 16 different brands of milk (4 Jersey & Guernsey, 12 non specified breed) were sampled over 2 years on 4 occasions. JG milk was associated with both favourable traits for human health, such as the higher total protein, total casein, α-casein, β-casein, κ-casein and α-tocopherol contents, and unfavourable traits, such as the higher concentrations of saturated fat, C12:0, C14:0 and lower concentrations of monounsaturated fatty acids. In summer, JG milk had a higher omega-3:omega-6 ratio than had NS milk. Also, the relative increase in omega-3 fatty acids and α-tocopherol, from winter to summer, was greater in JG milk. The latter characteristic could be of use in breeding schemes and farming systems producing niche dairy products. Seasonality had a more marked impact on the fatty acid composition of JG milk than had NS milk, while the opposite was found for protein composition. Potential implication for the findings in human health, producers, industry and consumers are considered.

Seasonal and stage of lactation effects on milk fat composition in northern Victoria

Effect of herd nutrition, time of year and season of calving on milk fat composition and physical properties were examined on irrigated commercial dairy farms in northern Victoria that made use of split-calving and a diverse range of feeding systems. Twenty-four farms were included in the study, and from each farm, morning and evening milk samples were collected from 16 cows that calved in autumn and 16 cows that calved in spring. There were no significant effects of season of calving on the concentration of fatty acids or phospholipids in milk fat, but there were interactions between season of calving and time of year (P < 0.001). These differences could be attributed to changes in energy balance and body condition with stage of lactation. The phospholipids comprising mainly phosphotidylcholine (PC), phosphtidylethanolamine (PE) and sphingomyelin (SP) also varied, with PC and PE being highest in late lactation and SP lowest during peak and mid lactation for both calving groups. Milk fat colour and the concentrations of free fatty acids were more influenced by factors associated with time of year rather than stage of lactation. Milk fat colour in particular showed strong seasonal variation being distinctly lighter in summer–early autumn when compared with rest of the year. Increasing the amount of concentrates fed was associated with decreases in short-chain fatty acid concentration and increases in the solid fat content of milk fat. Variations in nutritional management practices had only small (non-significant) effects on fat composition.

Seasonal variation in the concentrations of conjugated linoleic and trans fatty acids in milk fat from commercial dairy farms is associated with pasture and grazing management and supplementary feeding practices

A study of irrigated pasture-based dairy farms that used split calving (autumn and spring) was undertaken in northern Victoria, Australia, to examine associations between nutrition, time of year and season of calving on the concentrations of isomers of trans 18  :  1 fatty acids and conjugated linoleic acids (CLA) in milk fat. Factors associated with time of year explained most of the variation, with the highest concentrations observed in spring and summer when pasture intake by herds was high. However, there was substantial variation observed between herds and time of year. The mean total CLA concentration was 9.1 mg/g milk fatty acids (range 1.1–35.4 mg/g) with the cis,trans-9,11 accounting for ~84% of the total CLA. The mean total trans 18 : 1 concentration was 60.5 mg/g milk fatty acids (range 13.6–267 mg/g) with vaccenic acid (trans-11 18 : 1) accounting for ~53% of total trans 18 : 1 fatty acids. Total CLA and vaccenic acid were highest in August–September (southern hemisphere spring) (15.1 and 76.3 mg/g milk fat) and lowest in November–March (5.6 mg/g milk fat) and May–July (9.53 mg/g milk fat), respectively. There was no association between season of calving and milk CLA or trans 18 : 1 fatty acid concentrations. Trans-10 and -11 18 : 1 fatty acids and trans/trans-CLA were negatively correlated with milk fat concentrations. Management strategies designed to increase the concentration of CLA and trans 18 : 1 fatty acids in milk fat would not need to consider the effects of season of calving or stage of lactation, but should focus on pasture availability and quality.

Evaluating options for irrigated dairy farm systems in northern Victoria when irrigation water availability decreases and price increases

A case study and spreadsheet modelling approach was used to examine options for two dairy farms in northern Victoria that would enable them to maintain profit, or ameliorate a decline in profit, under changes in irrigation water availability and price. Farm 1 obtained 43% of estimated metabolisable energy requirements for the milking herd from supplements, had a predominantly spring-calving herd, and used mainly owner/operator labour. Farm 2 obtained 54% of estimated metabolisable energy requirements for the milking herd from supplementary feeds, had a split-calving herd, and used owner/operator and employed labour. When long-term allocation of irrigation water declined from 160% to 100% water right (WR), the ‘base farm’ system for both farms was maintained by purchasing temporary water. At a water price of $35/ML and allocation of 160% WR, the operating profit of Farms 1 and 2 was AU$52 000 and $315 000, respectively. This declined to $30 000 and $253 000 at a water availability of 100% WR. In response to changes in water availability and/or price, Farm 1 could purchase more supplements (a mix of grain and fodder) or replace some irrigated perennial pasture with irrigated annual pasture. Purchasing more supplements was not as profitable as buying irrigation water on the temporary market in the long term. At an irrigation water allocation of 130% WR, a water price of $35/ML and assumed response to extra supplement of 1.4 L milk/kg, operating profit was $24 000 compared with $44 000 when the base farm system was maintained by purchasing temporary water. At an allocation of 100% WR, increased supplement use was not profitable as a long-term option, unless exceptionally high responses in milk production to extra supplement were achieved. For this farm, converting an area of perennial pasture to annual pasture slightly increased operating profit compared with maintaining the base farm system when water availability decreased or price increased. The options analysed for Farm 2 involved converting some of the irrigated annual pasture to perennial pasture and, associated with this, additional options of reducing the area of maize grown or reducing the amount of nitrogen fertiliser applied to perennial pasture. Farm 2 had already implemented significant farm system changes to deal with reduced irrigation water availability in recent years, including increased supplementary feeding and growing annual pastures and maize. Hence, the options analysed for Farm 2 focused more on whether less significant changes would be more profitable. Converting 16 ha of annual pasture to perennial pasture, and growing 2.2 ha less maize appeared to be marginally more profitable than both the base farm system and the option of reducing nitrogen fertiliser use on the perennial pasture (operating profit $295 000 v. $291 000 or $292 000 at a water allocation of 130% WR and price of $35/ML). Reductions in irrigation water availability or increases in water price would need to be substantial to make the option of growing more perennial pasture and less maize unattractive. While the maize and annual pasture dry matter yield per megalitre of water were higher than for perennial pasture, the costs associated with harvesting, storing and feeding maize and annual pasture meant they were unlikely to be more profitable than a productive perennial pasture.