Dam management and dietary treatments

The experiment was conducted from July 2016 through October 2016, at a commercial dairy farm (Zarin Khoshe Dairy Farm). All experimental procedures were conducted according to The Care and Use of Agricultural Animals in Research and Teaching⁽²³⁾ guidelines. The Animal Experiment Committee at Tehran University, Karaj, Iran, approved all procedures and guidelines involving animals. The present study was part of a large research project, with a portion of the results (prepartum and postpartum performance of calves’ dams) reported elsewhere^{(Reference Jolazadeh, Mohammadabadi and Dehghan-banadaky11)}. Briefly, pregnant nulliparous (n 42) and previously parous (n 78) Holstein cattle were blocked by parity and enrolled in the study starting at 3 week before their calculated parturition date. The basal prepartum diet was formulated to have low concentrations of total FA (1·87 % of DM), linoleic acid (0·84 % of DM) and α-linolenic acid (0·36 % of DM). Prepartum cattle were fed one of the following three diets: (1) no fat supplement (CON), (2) 1·15 % of dietary DM as CSO (140 g/cattle per d) supplement (Persiafat; Kimiya Danesh Alvand Co.) or (3) 1·15 % of dietary DM as CFO (140 g/cattle per d) supplement (Persiafat; Kimiya Danesh Alvand Co.). The CSO and SFO diets were isoenergetic but had different FA profiles (linoleic acid: 1·30 and 0·87 %; EPA and DHA: 0 and 0·15 % for CSO and SFO, respectively). All diets were isonitrogenous. Ingredient and chemical composition of the prepartum diets and specific details on prepartum feeding and management were reported previously^{(Reference Jolazadeh, Mohammadabadi and Dehghan-banadaky11)}.

Calving management and colostrum, milk and starter feeding

Calves were born in a sod-based pen. All dams were monitored for signs of calving initiation every 30 min between 05.30 and 15.30 hours and then every 2 h between 15.30 and 05.30 hours. Within 2 h of birth, calves were weighed and ear-tagged, and the umbilical cord was disinfected with 10 % Betadine solution (Purdue Frederick Co.). Calves were housed temporarily in individual pens (1 × 1 m) equipped with a heat lamp before moving to individual wired pens (1 × 1·5 m) bedded with sand between 6 and 16 h of age. Cows were milked with a cow-side vacuum pump within 1 h after calving. Colostrum from each cow (4 litres) was fed to their corresponding calf, regardless of IgG concentration. Remnant colostrum (>1 litre and >50 g of IgG/l) was stored at –20°C to fed calves born from dams fed the same dietary treatment but producing low amounts of colostrum. Calves were considered to have adequate passive transfer if the plasma concentration of total IgG was ≥10 g/l after 24 h of colostrum feeding^{(Reference Tyler, Hancock and Parish24)}. Whole colostrum samples were collected and frozen (−20°C) for later analyses of IgG concentration and FA profile, and results were reported elsewhere^{(Reference Jolazadeh, Mohammadabadi and Dehghan-banadaky11)}. Briefly, the FA profile of colostrum resembled that of the prepartum diets fed to dams during late gestation^{(Reference Jolazadeh, Mohammadabadi and Dehghan-banadaky11)}. Furthermore, given that an extensive body of research has confirmed that the FA profile of tissues and body fluids resembles that of the supplemented diets, coupled with budgetary restrictions, we did not measure the FA profile of tissues or body fluids of calves in the present study. Plasma samples of newborn calves (at birth and 24 h after colostrum feeding) were measured for bovine total IgG concentration using radioimmunodiffusion^{(Reference Garcia, Greco and Favoreto10)}. Intake of IgG was calculated using the concentration of colostrum IgG reported previously^{(Reference Jolazadeh, Mohammadabadi and Dehghan-banadaky11)}. The apparent efficiency of IgG absorption (AEA, %) was calculated according to Quigley et al.^{(Reference Quigley, Drewry and Martin25)} using the following equation: IgG concentration in plasma at 24 h of life (g/l) × (0·099 × body weight (BW) (kg) at birth)/IgG intake (g). Plasma volume was estimated at 9·9 % of birth weight^{(Reference Quigley, Drewry and Martin25)}. Eighty-four Holstein calves were used in the present study (n 14 calves per factorial treatment, ten males and four females) in a completely randomised design, with dietary treatments in a 3 × 2 factorial arrangement (three dam diets (DD) and two CS; n 6). Calves were fed warm (38°C) pasteurised tank milk twice per d (08.00 and 17.00 hours) using steel buckets, starting at 3 d of age, and always drank all their offered milk. Volumes of milk fed decreased with age: 4 litres from day 4 to 7, and then 5, 6, 7, 6·5, 5·5, 4 and 2 litres during weeks 2 to 8, respectively. The average nutritional composition of milk was 11·50 % DM, 2·98 % crude protein (CP), 3·35 % fat and 4·51 % lactose. Calves had ad libitum access to one of two CS: (1) no fat supplement (FC-0) or (2) supplemented with 2 % fat Ca-salt rich in unsaturated FA, primarily oleic and linoleic acids (FC-2; Persiafat, Kimiya Danesh Alvand Co.; Table 1). All calves were weaned at 56 d but the experimental CS were fed until 77 d of age. CS were isonitrogenous, and the ingredients and composition are shown in Table 2. All calves had free access to clean and freshwater at all times. The offered starter was adjusted daily to achieve 5–10 % refusals (i.e. the portion of the starter not consumed over a 24-h period); and refusals were collected and weighed daily at 08.00 hours. Chopped high-quality alfalfa hay (5 % of CS) was included in the starter diets once calves were 30 d of age. The starter diets (CS or CS + alfalfa hay) were offered once daily at 09.00 hours.

Table 1. Fatty acid (FA) profile (g/100 g of total FA) of calf starters and fat supplement used

FC, fat Ca-salts; FC-0, calf starter with no fat supplement; FC-2, calf starter supplemented with 2 % fat Ca-salt; UFA, unsaturated FA.

* Fat Ca-salt rich in unsaturated FA (Persiafat, Kimiya Danesh Alvand Co.).

Table 2. Ingredients and nutrient composition (g/kg DM unless otherwise noted) of calf starters

FC-0, calf starter with no fat supplement; FC-2, calf starter supplemented with 2 % fat Ca-salt; CP, crude protein; NDF, neutral-detergent fibre; ADF, acid-detergent fibre; NFC, non-fibre carbohydrates; ME, metabolisable energy, NEm, net energy for maintenance; NEg, net energy for gain.

* Fat Ca-salts, Persiafat, Kimiya Danesh Alvand Co., contained 85 % fat and 9 % Ca (1 % C14.0, 28 % C16 : 0; 3 % C16 : 1; 5 % C18 : 0, 26 % C18 : 1, 30 % C18 : 2; 3 % C18 : 3, 4 % other).

† Vitamin–mineral premix contained per kg: Ca 160 g; Mg 40 g; Na 30 g; Fe 3 g; Cu 3 g; Zn 7 g; Mn 4 g; I 0·08 g; Co 0·05 g; Se 0·06 g; vitamin A 800 000 IU; vitamin D 150 000 IU; vitamin E 2000 IU.

‡ Calculated as DM – (NDF + CP + ether extract + ash) (National Research Council, 2001).

§ Estimated using National Research Council (2001) equations.

Data collection and sampling

All calves (n 84) were weighed at birth, 56 d and 77 d of age to measure changes in BW and calculate ADG. In addition, all calves were weighed once a week to observe weekly growth patterns. Body measurements of all calves were taken at 3 d of age, weaning (d 56) and the end of the study (d 77), in the morning and before feeding according to Lesmeister & Heinrichs^{(Reference Lesmeister and Heinrichs26)}. Body measurements included heart girth (circumference of the chest), hip width (distance between the points of hook bones), body length (distance between the points of shoulder and rump), body barrel (circumference of the belly before feeding), wither height (distance from the base of the front feet to wither) and hip height (distance from the base of the rear feet to the hook bones).

Amount of starter diets offered and refused per calf were recorded daily throughout the experiment. Feed samples were collected weekly and stored at –20°C for chemical analyses. Subsamples of feeds and refusals were mixed thoroughly, dried at 55°C for 48 h and ground to pass through a 1 mm screen in a hammer mill (Arthur Hill Thomas Co.) before chemical analyses for DM (method 934.01), CP (method 988.05) and ether extract (method 920.39)⁽²⁷⁾. The neutral-detergent fibre contents were analysed according to Van Soest et al.^{(Reference Van Soest, Robertson and Lewis28)}, assayed with sodium sulphite, without α-amylase, and were expressed with residual ash. Eight representative samples of milk were collected throughout the study and analysed for DM, fat, CP and lactose content by infrared spectroscopy (Foss Electric). FE (kg of BW gain/kg of total DM intake (DMI)) was calculated for the preweaning period, days 57–77 and for the extent of the study. Total DMI corresponds to the amount of DMI contributed by the starter diets (CS and alfalfa hay) and by the fixed amounts of milk provided to each calf.

Total tract apparent digestibility of DM, organic matter, CP, neutral-detergent fibre, acid-detergent fibre and ether extract were determined using acid-insoluble ash as an internal marker^{(Reference Van-Keulen and Young29)}. Faecal samples were obtained from each calf twice per d (in the morning and afternoon) during four consecutive days (from days 74 to 77). Faecal samples were dried at 55°C in a forced air oven, ground to pass a 1-mm screen in a Wiley mill (Arthur Hill Thomas Co.) and then mixed thoroughly.

Samples of ruminal fluid (approximately 150 ml) were collected from each calf on days 30 and 70, about 3 h after the morning feeding, using a stomach tube attached to an Erlenmeyer flask and vacuum pump; the first 50 ml were discarded to avoid possible saliva contamination. The ruminal fluid was filtered through four layers of cheesecloth, and pH was determined immediately using a portable pH meter (Sentron, model A102-003). Approximately 25 ml of filtrate were then preserved by adding 5 ml of 25 % metaphosphoric acid solution for later determination of volatile FA (VFA), and approximately 20 ml of filtrate were combined with 20 ml 0·2 M HCl for later measurement of NH₃-N concentration. The prepared samples were stored at –20°C and then thawed for analysis of respective compounds. Stored samples were centrifuged at 1200 g for 10 min, and the supernatant fluid was analysed for VFA by GC (model 5890; Hewlett-Packard). Ruminal NH₃-N concentration was determined according to the procedures described by Crooke & Simpson^{(Reference Crooke and Simpson30)}. Blood samples were collected from each calf immediately after birth, 24 h after colostrum feeding and then 3 h after the morning meal on days 28, 56 and 77 of age. Blood was taken from the jugular vein by evacuated tubes containing K2 EDTA (10·5 mg, Monoject; Sherwood Medical). Samples were immediately chilled and then plasma was obtained by centrifugation at 3000 g for 15 min and stored at –20°C. Plasma concentrations of glucose, total protein, albumin, alkaline phosphatase (ALP), cholesterol and TAG were determined using an automatic microplate Reader (EON-BIOTEK) and commercial kits (Pars Azmoon). Enzymatic assays were used for analyses of plasma insulin (DRG), blood urea N (Pars Azmoon) and NEFA (Randox Laboratories Ltd.) in an automatic spectrophotometer (Clima Plus; RAL) following the manufacturer’s instructions. Behavioural data (eating, ruminating, standing, lying and non-nutritive oral behaviour) were monitored by direct observations of each calf in the time (minutes) devoted to each monitored behaviour, once at the last week of the preweaning period (35–42 d) and once at the last week of the postweaning period (70–77 d)^{(Reference Castells, Bach and Araujo31)}. Behavioural data were monitored for 8 consecutive hours following the morning milk feeding (at 08.00 hours) and the CS (09.00 hours) during the last week of the pre- and postweaning periods, respectively.

Calf scoring for health assessment and incidence of health disorders

Attitude, faecal consistency and nasal discharge were scored daily for each calf after the first daily feeding of CS by a single observer using a scale from 0 to 3 (http://www.vetmed.wisc.edu/dms/fapm/fapmtools/8calf/calf_health_scoring_chart.pdf). Attitude scores recorded were (0) responsive, (1) non-active, (2) depressed or (3) moribund. Faecal consistency scores recorded were (0) firm, no diarrhoea; (1) moderate, soft no diarrhoea; (2) runny faeces, mild diarrhoea; or (3) watery faeces, diarrhoea. Nasal score scale of calves was also scored on a 0–3 scale, with 0 being normal serous discharge, 1 being a small amount of unilateral cloudy discharge, 2 being bilateral cloudy or excessive mucus discharge and 3 being copious bilateral mucopurulent discharge. Calves given a faecal score >1 were considered to have diarrhoea, and those with a score of 3 were considered to have severe diarrhoea. Calves given a score > 0 for other criteria were considered as having the disorder. Weekly averages of each score were calculated for statistical analysis. Incidences of health disorders were recorded daily for individual calves. Respiration rate (RR) was measured at 14.00 hours on days 30, 45 and 70 by visual observation for three 1-min periods (not consecutive), according to the methods described by Yari et al.^{(Reference Yari, Nikkhah and Alikhani32)}. Rectal temperature (RT) was measured weekly before morning meals using a rectal thermometer (Yasa Teb Co.), and calves with RT over 39·5°C were categorised as febrile. Calves were vaccinated according to the herd vaccination protocol. Calves with digestive and respiratory problems were treated by farm personnel according to protocols established by the herd veterinarian. All calves remained healthy and exhibited no signs of illness during the experiment.

Statistical analyses

Statistical analyses were conducted for four periods: the first day of life (passive immunity parameters), preweaning (days 0–56), postweaning (days 57–77) and the entire experimental period (days 0–77). Except for starter intake and measures of structural growth, the first measure was performed on day 3 of life. The study was a complete randomised design, with dietary treatments in a factorial arrangement 3 × 2 (3 DD and 2 CS; n 6 treatments). The mixed model equation for passive immune variables was defined as Yijk = μ + α _i + β _j + (αβ)_ij + e _ijk, where Yijk is the dependent variable, μ is the population mean, α _i is the treatment effect, β _j is the fixed effect of parity, (αβ)_ij is the interaction effect of treatment and parity and e _ijk is the residual error. The passive immunity variables were analysed using the PROC MIXED procedure of SAS⁽³³⁾. Contrasts testing the effects of DD were: (1) FAT: control v. CFO + SFO and (2) SFO: CSO v. CFO, (3) effect of parity (primiparous v. multiparous), and the contrasts testing the interactions of DD and parity (4) FAT × parity (contrasts 1 and 3) and (5) SFO × parity (contrasts 2 and 3).

For other continuous variables (rumen fermentation parameters, plasma metabolites, BW, skeletal growth, behaviour data, RT, respiratory rate and apparent nutrient digestibility), the data were analysed using the PROC MIXED procedure of SAS⁽³³⁾. Faecal and health scores were analysed using a multivariable logistic mixed model (GLIMMIX procedure of SAS). The following model was used for variables with repeated-measures, for those with non-repeated-measures the effect of time and its interaction were omitted:

$${Y_{ijklm}} = \mu + {D_i} + {C_j} + {T_k} + D{C_{ij}} + D{T_{ik}} + C{W_{jk}} + DC{T_{ijk}}{\rm{ }} + {\varepsilon _{ijk}},$$

where Y _ijklm is the observation; μ is overall mean; D _i is the fixed effect of DD (CON, CSO or CFO); C _j is the fixed effect of CS (FC-0 or FC-2); T _k is the effect of time; DC _ij is the interaction of DD × CS; Dt _ik is the effect of the interaction between DD and week; Ct _jk is the effect of the interaction between CS and week; DCt _ijk is the three-way interaction of DD, CS and time; and ε _ijk is the residual error. Five orthogonal contrasts of DD, CS and interactions were tested for variables measured after initiation of starter feeding. Contrast testing the effects of DD were (1) FAT: control v. CFO + SFO, (2) SFO: CSO v. CFO, contrast for the effect of CS, (3) FC-0 v. FC-2, and the contrast testing the interactions of DD and CS, (4) FAT × CS (contrasts 1 and 3) and (5) SFO × CS (contrasts 2 and 3).

The denominator df were computed using the approximation described by Kenward & Roger^{(Reference Kenward and Roger34)}. Significance was declared at P ≤ 0·05 and trends at 0·05 < P < 0·10. Tukey’s adjustment was used for multiple comparison tests.