Animal experiment

This study was part of a larger joint research project (Deutsche Forschungsgemeinschaft (DFG) project: KU 1956/3-1; HA 4372/6-1; SCHW 642/6-1) and was conducted with the approval of the Animal Care Committee of the Ministry of Nutrition, Agriculture, Forestry, and Fishery, Schwerin, State of Mecklenburg-Vorpommern, Germany (No. VI-522a-7221.31-1-002/99).

Cows and diet

Experiments were performed with 10 multiparous dried-off German Holstein cows (4 to 6 years old, mean body mass: 726±56 kg) born and raised at the farm of Griepentrog KG (Steinhagen, Germany), during week 4 antepartum (ap). Two of the cows (number 3 and 10) were halfsiblings having the same father. All cows had a milk yield of ⩾10 000 kg/305 days during the prior lactation and had been dried off at 7 weeks before expected calving.

Cows were fed a far-off total mixed ration (TMR) twice daily at ~0700 and 1500 h and had free access to water. The TMR was formulated to meet the nutrient recommendations of the German Society for Nutrition Physiology (2001), and its ingredients and chemical composition are given in Table 1.

Table 1 Ingredients and chemical composition of the total mixed ration

DM=dry matter.

¹ Concentrate MF 2000 (Vollkraft Mischfutterwerke GmbH, Güstrow, Germany): 33% extracted soy meal, 20% corn, 17% wheat gluten, 13% wheat, 8% extracted rapeseed meal, 5% sugar beet pulp, 2% sodium hydrogen carbonate, 1.3% calcium carbonate, 0.2% sodium chloride, 8.0 MJ of NE_L/kg of DM, 204 g of utilizable protein/kg of DM.

² Molassed sugar beet pulp (Arp; Thordsen, Rautenberg GmbH & Co. KG, Sollerupmühle, Germany): minerals, 7.3 MJ of NEL/kg of DM, 153 g of utilizable protein/kg of DM.

³ Rinderstolz 9235 far-off (Salvana Tiernahrung GmbH, Sparrieshoop, Germany): 75% crude ash, 4.5% calcium, 6% phosphorus, 10% sodium, 12% magnesium, vitamins.

Experimental design

During weeks −7 to −5 ap, cows were adapted to handling and to staying in respiration chambers (see the ‘Indirect calorimetry and behavioural data’ section) in which the experimental trials were performed. Habituation (criteria: eating, drinking, ruminating, lying down, BT) was performed at least three times and the duration of stay was increased from 1 h on day 1 to 3 to 4 h on day 4. No animal needs longer than 4 days to habituate. At the same time points cows were adapted to wear a fixing belt (criteria: scrubbing, licking, looking to the belt, restlessness), which was tied around the thorax behind the forelegs and is needed for HRV measurements.

The experimental trial was started one day after the cows were transferred to the respiration chambers. Heart rate and interbeat intervals (IBI) computed from the intervals between consecutive R-peaks were continuously measured for 48 h starting at 0630 h. In addition, O₂ consumption, CO₂ and CH₄ production, food intake, and physical activity including standing–lying behaviour were monitored. After 24 h of ad libitum feeding (period 1, P1), feed was removed for 10 h (period 2, P2) to challenge the energy metabolism of the cows. Thereafter, the cows were provided with food ad libitum for a 14-h (1630 to 0630 h) period of re-feeding (period 3, P3). The time course and the experimental periods (P1 to P3) of the trial are shown in Figure 1. The cows were weighed immediately before entering and after leaving the chambers on balances in front of the chambers. The continuous measurements were interrupted for 0.5 h (0630 to 0700 h) on day 2 to clean the chambers and to measure their BT. The latter was also measured after the second feeding (1500 h) during P1 and P3 and at 1630 h during P2.

Figure 1 Time schedule and experimental design. From one cow representative 48 h original recordings of heat production (HP) and of standing–lying behaviour are also shown. Standing periods (ST) are displayed by grey coloured columns and the right y-axis labelling gives the standing time per 6-min measuring interval in min; 0 min=lying position. The 20-min time periods selected for heart rate variability analysis have been encircled.

Heart rate variability measurement and analysis

Heart rate and R-R interval data were taken noninvasively by using the Polar Equine RS800CX monitor (Polar Electro Oy, Kempele, Finland), a newly developed fixing belt for large animals (FBN utility model, case number: DE 20 2012 100 735.5) and the equine belt with transmitters and two integrated electrodes (WearLink^® W.I.N.D.; Polar Electro Oy, Kempele, Finland). A few days before the experimental period, the electrode site, an area of about 10×15 cm localized directly behind the left shoulder of the cow, was shaved. To optimize conductivity, the electrodes were made moist before the measuring belt with integrated electrodes has placed on this region.

After measurement, the data were transferred from the monitor to a computer (Polar IrDA USB-Adapter W.I.N.D.; Polar Electro Oy), and relevant data sets from the three experimental periods (P1 to P3) were selected according to heat production (HP). Moreover, in order to minimize the additional effects of physical activity, only those data sets that were recorded during periods when the cows were lying down were taken into consideration. During P1, an interval after the last meal characterized by a stable maximum HP was chosen and compared with an interval with consistently low HP occurring at the end of P2. In P3, a rapid increase of HP was observed after re-submission of food. For data analysis an interval was selected were HP has stabilized. Figure 1 shows typical original traces of HP and standing–lying behaviour obtained from an individual cow. In addition, the periods chosen for HRV analysis are given.

Subsequently, by using the software ‘Polar ProTrainer 5 Equine Edition’ Version 5.35.161 (Polar Electro Oy), an automatic correction for artefacts was performed. Only data sets that were at least 20 min long and had a corrected fault rate of <10% for each 5-min interval were included in the analysis (Mohr et al., Reference Mohr, Langbein and Nürnberg2002).

Corrected 20-min data sets were converted into text files and saved, and HRV parameters in the time, frequency, and nonlinear domains were calculated (Table 2) from an adjacent 5-min window that moved over the data set by use of Kubios HRV software Version 2.0.

Table 2 Glossary for time domain, frequency domain and nonlinear domain measures of heart rate variability (Mohr et al., Reference Mohr, Langbein and Nürnberg2002; Borell von et al., Reference Borell von, Langbein, Despres, Hansen, Leterrier, Marchant-Forde, Marchant-Forde, Minero, Mohr, Prunier, Valance and Veissier2007)

HRV=heart rate variability; RMSSD=root-mean square differences of successive R-R intervals; SDNN=the mean of the standard deviations for all R-R intervals.

* Quantitative parameters derived from recurrence plots by nonlinear mathematical analysis of HRV (Recurrence Quantification Analysis)

The dissimilar respiratory frequencies in cattle and humans were taken into consideration by setting the limits of the high frequency (HF), low frequency (LF) and very low frequencies bands to 0.2 Hz (lower limit) and 0.58 Hz (upper limit), 0.0133 and 0.2 Hz, and 0.0033 and 0.0133 Hz, respectively (Borell von et al., Reference Borell von, Langbein, Despres, Hansen, Leterrier, Marchant-Forde, Marchant-Forde, Minero, Mohr, Prunier, Valance and Veissier2007). Recurrence quantification analysis (RQA) was used to calculate nonlinear parameters of HRV with the Kubios software Version 2.0. RQA was performed with an embedding dimension m=10, lag of 1, and a threshold distance (radius) r of $\sqrt m \,{\rm SD}$ , with SD as the standard deviation of the R-R time series.

Indirect calorimetry and behavioural data

Gas exchange of the cows was measured continuously at 6-min intervals in climate-controlled (15 °C, 70% humidity) open-circuit respiration chambers with a volume of 16 m³. All chambers (dimension 4×2×2 m) contained a stanchion allowing the individual animal to stand or lie down. Standing and lying times of the cows were registered by a photoelectric switch (SA1E; Idec Elektrotechnik GmbH, Hamburg, Germany). Other physical activity was detected by a modified IR-based motion detector (IS 120; STEINEL, Herzebrock-clarholz, Germany) converting movements of the animal into impulses.

Feed intake was assessed automatically by measuring feed disappearance from the chamber feed bin (maximum capacity: 40 kg organic substance) via a scale connected to an electronic registration device (PAARI, Erfurt, Germany).

Gas samples were passed through IR absorption based analysers (UNOR 610; MAIHAK AG, Hamburg, Germany) for the determination of CO₂ and CH₄ content and through a paramagnetic analyser (OXYGOR 610; MAIHAK) for measurement of O₂ content. Based on these data, HP was estimated according to Brouwer (Reference Brouwer1965): HP (KJ)=16.18 O₂ (l)+5.02 CO₂ (l)−2.17 CH₄ (l)−5.99 N (g).

All measured variables (gas concentrations for O₂, CO₂ and CH₄, air flow rate, feed disappearance from the feed bin, temperature and relative humidity in and behind the chamber, standing and lying time, activity counts, air pressure) were sent to an acquisition system (Simatic; Siemens, München, Germany) and collected by purpose-adapted software (WinCC, Version 5.1, SP 2; Siemens). DELPHI-based (Delphi 2007, San Francisco, CA, USA) software was programmed in our group (Copyright H. Scholze, FBN) to allow for the automatic calculation of HP and collection of all measured data in EXCEL files.

To obtain accurate information on the cows energy status and rumen fermentation activity, the energy balance (EB) and fermentative CO₂ (CO₂(ferm)) for P1, P2 and P3 were calculated from the measured data by using the following equations: EB (KJ)=ME Intake (KJ)−HP (KJ) and CO₂(ferm) (l)=1.7×CH₄ production (l).

Blood sampling and analysis

Cows were equipped with indwelling jugular catheters the day before the trial starts. Extension tubing was used to take blood samples from outside the respiration chambers into Fe-Fluoride monovettes (Sarstedt, Nümbrecht, Germany) and immediately put on ice. Blood samples were centrifuged (2700 r.p.m. (4000×g), 4°C) for 20 min and the supernatants were stored at −80°C until analysis for NEFA, BHBA, total ghrelin and cortisol. Plasma concentrations of NEFA and BHBA were measured by routine analysis (Cobas Mira, Clinic for Cattle, Stiftung Tierärztliche Hochschule Hannover, Hannover, Germany) using kits from Wako Chemicals (Neuss, Germany) (NEFA kit 434–91795) and Randox Laboratories (Wülfrath, Germany) (BHBA kit RB 998), respectively. Total ghrelin (acyl+desacyl ghrelin) was determined in 400-µl freeze-dried plasma samples by using the RIA method described previously by ThidarMyint et al. (Reference ThidarMyint, Yoshida, Ito and Kuwayama2006). Plasma cortisol concentrations were determined by radioimmunoassay at the Veterinary Physiology, Vetsuisse Faculty, University of Bern as described previously by Thun et al. (Reference Thun, Eggenberger, Zerobin, Luscher and Vetter1981).

Statistical analysis

The statistical analyses were carried out by using SAS software, Version 9.4 for Windows (Copyright; SAS Institute Inc., Cary, NC, USA).

Differences of the HRV variables (Table 3) and of parameters related to the energy, nutrient and activity status (Table 4) between various periods (P1, P2 and P3) were analysed by one way repeated measurement ANOVA. With the exception of BT, all parameters from Table 4 were evaluated as 24 h-means for the ad libitum feeding period (P1: 240 data sets) and as means for the fasting period (P2: 0630 to 1630 h, 99 data sets) and for the ad libitum re-feeding period (P3: 1630 to 0630 h, 140 data sets). Data obtained in P2 and P3 were converted into 24-h values.

Table 3 Heart rate variability indices determined for cows under control conditions (P1=ad libitum feeding) and during fasting (P2) or re-feeding (P3=food ad libitum)

LSM=least square means; Min=minimum value; Max=maximum value; HR, heart rate; HRV=heart rate variability; LF=low frequency; HF=high frequency; ShanEn=Shannon Entropy.

Data are given as LSM ± SE; n=10.

^a,b Significant differences between periods (P<0.05).

* LF/HF has been calculated from the non-normalized values of HF and LF (not shown). P1=control (ad libitum feeding), P2=fasting, and P3=re-feeding (food ad libitum).

Table 4 Response of parameters related to the energy, nutrient and activity status to a 10-h fasting (P2) and 14 h re-feeding (P3) period

P1=control (ad libitum feeding), P2=fasting; P3=re-feeding (food ad libitum); LSM=least square means; Min.=minimum value; Max=maximum value; BT=body temperature; HP=heat production; EB=energy balance; DMI=dry matter intake; WI=water intake; NEFA=non-esterified fatty acids; BHBA=β-hydroxybutyrate.

Data are given as LSM ± SE; n=10.

^a,b,cSignificant differences between periods (P<0.05).

The response of HF (an indicator of parasympathetic activity) to fasting (HF_P1−HF_P2=ΔHF_P1−P2) was evaluated for individual cows allowing for separation of two groups (HF+(increase of HF in response to fasting) and HF− (decrease of HF in response to fasting) c.f. Figure 2). Then HRV data were analysed by two-way repeated measurement ANOVA with the MIXED procedure of SAS/STAT software. The ANOVA model contained the fixed effects Group (levels: HF+ and HF−) and period (levels: P1, P2, P3) and the interaction Group×Period. Repeated measurements on the same animal were taken into account by the repeated statement of the MIXED procedure by using an unstructured residual covariance matrix.

Figure 2 Response of the high frequency domain (HF) of heart rate variability to fasting. It mainly reflects the activity of the parasympathetic branch of the autonomic nervous system. The response of HF to fasting (HF during ad libitum feeding (P1) minus HF during fasting (P2)=ΔHF_P1−P2) is shown for individual cows. Note the increase in vagal tone (ΔHF_P1−P2 increase) in five out of 10 cows (defined as group HF+) and an impaired vagal activation (ΔHF_P1−P2 decrease) in another five cows (assigned to group HF−).

In a further analysis the relationship between ΔHF_P1−P2 and HR, R-R interval, and L _MAX at P1 was investigated by linear regression using the REG procedure of SAS/STAT software with the aim to select possible biomarker(s) that predict the sensitivity of individual cows for metabolic stress, and to define a threshold for such biomarker. Of the investigated HRV parameters only L _MAX fulfilled the criteria for a possible biomarker and two groups (<L _MAX (L _MAX lower than threshold in P1: control conditions with feed ad libitum) and >L _MAX (L _MAX higher than threshold in P1: control conditions with feed ad libitum) c.f. Figure 3a) were defined. After grouping the cows according to the L _MAX threshold one way ANOVAs were done for the variables BT, HP, EB, CO₂(ferm), dry matter intake (DMI) and water intake, plasma concentrations of NEFA, BHBA, glucose, cortisol, ghrelin (total) and insulin, standing time, activity and milk parameters (energy corrected milk (ECM), milk fat, milk protein, milk lactose and fat/protein quotient) to test the group effect (test for biomarker).

Figure 3 Prediction of group differences in autonomic control by the nonlinear domain heart rate variability (HRV) component Maxline (L _MAX). (a) Regression analysis was performed with ΔHF_P1−P2 as dependent, and L _MAX as independent variable. The obtained regression model (R ²=0.76) allows for calculation of a threshold value (TS=258) for L _MAX and assignment of cows to groups having L _MAX values above (>L _MAX) or below (<L _MAX) the TS. (b) Under control conditions (P1: ad libitum feeding) cows of the >L _MAX (n=7) and <L _MAX (n=3) groups differ in L _MAX (*P<0.001), high-frequency (HF, *P<0.002), and low-frequency (LF, *P<0.002) components of HRV.

The first ANOVA model contained the fixed effects Group (levels: <L _MAX and >L _MAX) and Day (levels: day 1=P1 and day 2=P2+P3 ap, day 3=P1 and day 4=P2+P3 postpartum) and the interaction Group×Day (Table 5). The second ANOVA model contained the fixed effects Group (levels: <L _MAX and >L_MAX) and Week (levels: weeks −5 to −2 antepartum and weeks +2 to +5 postpartum) and the interaction Group×Week (Table 6). Repeated measurements on the same animal were taken into account by the repeated statement of the MIXED procedure by using an unstructured residual covariance.

Table 5 Prepartal and postpartal <L _max und >L _max group differences in parameters related to metabolic status and stress level

Day 1/3 (P1)=control (ad libitum feeding) antepartum/postpartum, Day 2/4 (P2+P3)=fasting and re-feeding (food ad libitum) antepartum/postpartum; LSM=least square means; BT=body temperature; Ns=not significant; HP=heat production; EB=energy balance; ECM=energy corrected milk.

Data are given as LSM ± SE, n=16. Significant differences between <L _max and >L _max groups (P<0.05).

Table 6 Prepartal and postpartal <L _max und >L _max group differences in cows kept under normal housing conditions

LSM=least square means; ap=weeks −5 to −2 antepartum; pp=weeks +5 to +2 postpartum; DMI=dry matter intake; ECM=energy corrected milk.

n=16.

Least square means and their SE were calculated and pairwise tested for each effect in each model by using the Tukey–Kramer procedure for pairwise multiple comparisons. Effects and differences were considered significant if P<0.05.