Changes of Serum Calcium Concentration, Frequency of Ruminal Contraction and Feed Intake Soon after Parturition of Dairy Cows Fed Difructose Anhydride III

Article information

Asian-Australas J Anim Sci. 2015;28(1):58-68
1Research Center of Nippon Beet Sugar Mfg. Co., Ltd, Obihiro, Hokkaido 080-0831, Japan.
2Department of Life Science and Agriculture, Obihiro University of Agriculture and Veterinary Medicine, Obihiro, Hokkaido 080-8555, Japan.
*Corresponding Author: M. Hanada. Tel: +81-155-49-5482, Fax: +81-155-49-5489, E-mail: hanada@obihiro.ac.jp
United Graduate School of Agricultural Science, Iwate University, Morioka, Iwate 020-8550, Japan
Received 2014 June 05; Revised 2014 August 01; Accepted 2014 September 04.

Abstract

Requirements to control the large decrease in serum calcium (Ca) due to parturition and to increase the feed intake soon after parturition have been well accepted in dairy cows. This study was aimed to investigate the feed intake affected by serum Ca concentration with difructose anhydride (DFA) III supplement in dairy cows soon after parturition. Fourteen transition Holstein cows were divided into DFA and control (CONT) groups within 1 to 5 parity variations in each group. Measurement schedule for an individual cow was from 14 d before parturition to 7 d following parturition. The cows in DFA group were supplied 0.2 kg/head/d of DFA III feed containing 40 g of pure DFA III while the cows in CONT group received no DFA III. Other feeding procedures were the same for all cows in both groups. At parturition (d 0), serum Ca concentration sharply declined in both groups (p<0.05). Time interval for recovery from decreased serum Ca to its normal range (>9.0 mg/dL) tended to be faster in DFA group (12 h) than in the CONT group (48 h), but the differences were not significant. Active ruminal contraction was observed in DFA group at following parturition of d 1 (p<0.05), d 3 (p<0.05), and d 5 (p<0.01). Dry matter (DM) intake did not differ between the groups. However, positive correlations were observed between serum Ca concentration and ruminal contraction (p<0.001), and between ruminal contraction and DM intake (p<0.001) during following parturition. According to multiple regression analysis (R2 = 0.824, p<0.001), the DM intake was positively affected by serum Ca concentration and ruminal contraction. These results suggest that feed intake soon after parturition in dairy cows can be increased by improvement of serum Ca concentration and active ruminal contraction, but DFA III supplementation in this study did not improve the lower serum Ca concentration due to parturition.

INTRODUCTION

Physiological and metabolic changes at or soon after parturition in dairy cows have been reported by Goff and Horst (1997) and Drackley (1999). Consistent with these changes, the cow has to confront a lower Ca concentration in the blood and a feed intake lower than it requires. It might be impossible to avoid these changes (Goff, 2004; Grummer et al., 2004). Imbalances between lower feed intake and higher nutrient demand lead to negative energy related metabolic disorders and other infectious diseases (Herdt, 1988; Drackley et al., 2005), which can threaten the productive performances. To alleviate these problems, rapid increase of feed intake at or soon after parturition is desired. Several ways aimed to increase the feed intake in dairy cows have been suggested (Grant and Albright, 1995; Ingvartsen and Andersen, 2000; Hayirli et al., 2002), but methods remain elusive.

On the other hand, serum Ca decline at or soon after parturition might be an unavoidable mechanism in dairy cows, especially in aged cows (Horst et al., 1990; Goff et al., 1991) due to expeditious loss of Ca by milk synthesis, and less efficiency of Ca absorption by the intestinal transcellular pathway (Horst et al., 1990) and inactivation of bone Ca resorption pathway (Ramberg et al., 1970; Kamiya et al., 2005). Lower serum Ca concentration in the blood can induce the cow to develop the mineral related metabolic disorders involving hypocalcemia, milk fever, mastitis, retain placenta, displaced abomasum, uterine involution and delayed ovulation (Curtis et al., 1983; Borsberry and Dobson, 1989; Jonsson et al., 1999). Kimura et al. (2006) also reported that hypocalcemic cows had impaired immune cell responses and were susceptible to infectious diseases. To shut down these impediments, stopping the declined serum Ca by parturition is desired as fast as possible soon after parturition. Several ways aimed to prevent the decline serum Ca have been suggested in dairy cows (Jonsson and Pehrson, 1970; Goff and Horst, 1993; Horst et al., 1997), but a complete solution is still not declared.

Furthermore, serum Ca plays a unique role in muscular contractive activities (Johansson, 1987; Van Breemen and Saida, 1989). Passage rate of digesta through the gastrointestinal tract decreases with the decrease in serum Ca concentration in sheep and cow (Huber et al., 1981; Daniel, 1983) which can impact on feed intake and productive performances. Forbes (1995) reported that enhancement of reticulo-rumen motility could increase feed intake. According to these reports, improvement of feed intake soon after parturition in dairy cows might be impossible without active ruminal contraction and optimal concentration of serum Ca. It should be therefore considered that inhibition of the large decline of serum Ca by parturition is a fundamental approach not only for solving the Ca related disorders but also for activating the ruminal contraction and improving the feed intake soon after parturition in dairy cows.

A disaccharide crystal, difructose anhydride (DFA) III containing two fructose units, can be obtained from inulin of chicory root (Kikuchi et al., 2009). It has loosening effect on the tight junction of intestinal epithelial cells, allowing the inflow of Ca like nutrients via paracellular pathway (Ballard et al., 1995; Mineo et al., 2002). Enhancement of Ca uptake by DFA III supplement has been identified in rats and humans (Suzuki et al., 1998; Mineo et al., 2004; Shigematsu et al., 2004). Sato et al. (2007) proved the inhibitory effect of DFA III on serum Ca decline due to parturition in multiparous cows; however they did not mention its effect on feed intake. More recently, Sato et al. (2012) proved that DFA III has a positive effect on immunoglobulin G absorption in newborn calves. Reports of DFA III for dairy cows are few and additional information is required to confirm its effectiveness in dairy cows.

In our study, we hypothesized two positive effects in dairy cow: i) serum Ca concentration decreased by parturition could be improved by DFA III supplement; ii) feed intake soon after parturition could be increased by improvement of serum Ca concentration. This study was aimed to investigate the feed intake affected by serum Ca concentration with DFA III supplement in dairy cows soon after parturition.

MATERIALS AND METHODS

Animal measurements were conducted at Field Science Centre (FSC), Obihiro University of Agriculture and Veterinary Medicine, Obihiro, Hokkaido, Japan. Cows used in this study were cared for and maintained according to the regulations for animal experiments in Obihiro University of Agriculture and Veterinary Medicine, Obihiro, Hokkaido, Japan.

Animals and feeding procedures

Fourteen transition Holstein cows kept in FSC were allotted into two groups: DFA III supplied (DFA) group (n = 7; body weight [BW] = 755±29.6 kg; body condition score [BCS] = 3.3±0.07) and DFA III unsupplied or control (CONT) group (n = 7; BW = 757±31.0 kg; BCS = 3.4±0.09) while cow parity varied from 1 to 5 (1 head in parity 1, 2, 4, and 5; 3 heads in parity 3) for each group. Measurement schedule for individual cows in each group was from 14 d before parturition to 7 d following parturition. Before parturition period, cows were assigned in a free stall barn and allowed to access the offered diets from individual door feeders equipped with an electronic gate opening system (one cow per gate per feeder). Close to parturition (approximately ≤24 h before parturition), cows were moved into the maternal hospital pen and kept in individual stalls and, the diets were offered separately. Newborn calves were weighed and separated from their mothers within 1 h following parturition and kept in individual calf pens. Their dams were kept in the hospital pen until the end of measurement period.

The DFA III feed used as supplement in our study was manufactured by Nippon Beet Sugar Mfg. Co., Ltd (Obihiro, Japan) and it was composed of 80% beet pulp and 20% pure DFA III. Before feeding the other basal diets, the cows in DFA group were supplied 0.2 kg/head/d of DFA III feed (containing 40 g of pure DFA III) while the cows in CONT group were not supplied with any DFA III. Other offered diets and feeding procedures were same to all cows in both groups. Diets were offered twice a day (06:00 h and 17:30 h) throughout the measurement period. Ingredient and chemical compositions of the offered diets in this study are shown in Table 1.

Ingredient and chemical compositions of DFA III feed and other basal diets

Before parturition period (from before parturition 14 d to parturition time), 30.0 kg/head/d of total mixed ration (TMR, formulated to be forage and concentrate ratio [F:C] of 89:11) and 6.0 kg/head/d of grass hay were offered by restricted feeding. Following parturition period (from parturition time to 7 d following parturition), TMR formulated to be F:C of 76:24 was offered by ad-libitum feeding. In addition, 2.0 kg/head/d of concentrate C18 (Mo-dairy 18, Nippon Formula Feed Mfg. Co., Ltd, Kanagawa, Japan) and 0.1 kg/head/d calcium phosphate (Dibasic, Obanaya Cementex Co., Ltd, Aichi, Japan) were supplied as top-dressed on TMR following the parturition period. Drinking water and mineral block (KNZ salt licks, Akzo Nobel N.V, Hengelo, The Netherlands) were always available for all cows in both groups throughout the measurement period.

Sampling and measurement procedures

Offered diet samples were collected once a week. Residues from individual cows were weighed and 1% of residue was sampled daily. The DM, crude protein, ether extract and ash contents in the offered diets and in the residues were determined by methods described in AOAC (2003). Neutral detergent fiber, acid detergent fiber, and lignin were analyzed according to methods of Van Soest et al. (1991). Neutral detergent insoluble crude protein and acid detergent insoluble crude protein were analyzed according to the procedures of Coblentz et al. (2010). Non fibrous carbohydrate and net energy for lactation were calculated using NRC (2001) equations. Dietary calcium (Ca), phosphorus (P), magnesium (Mg) and potassium (K) were analyzed by inductively coupled plasma emission spectroscopy analysis method (ICPE-9000, Shimadzu Corporation, Tokyo, Japan). Individual feed intake was calculated on daily basis.

Blood samples were withdrawn from the caudal vein of the cow into the sampling tube (VENOJECT II, Terumo Corporation, Tokyo, Japan) at d 14, 7, 5, 3, and 1 before parturition as well as at d 0, 0.25, 0.5, 1, 2, 3, 4, 5, and 7 following parturition, respectively. Sampling for before parturition (d 14, 7, 5, 3, and 1) and after parturition (d 4, 5, and 7) were almost completed at 05:30 h before morning feeding, but sampling for d 0, 0.25, 0.5, 1, 2, and 3 following parturition was performed counting from the parturition hour. Within 1 h after withdrawing, blood sample was centrifuged at 3,500 rpm for 10 min at room temperature (Hitachi Centrifuge 05P-21, Hitachi Koki Co., Ltd, Tokyo, Japan). Obtained serum was kept at −30°C (Biomedical Freezer, Sanyo Electric Co., Ltd, Osaka, Japan) until analysis. Serum Ca concentration was determined using Automatic Clinical Chemistry Analyzer (TBA-120FR, Toshiba Medical Systems Corporation, Tochigi, Japan).

Ruminal contraction was auscultated from upper left flank of the cow using stethoscope connected sound recorder (ICR-S340RM, Sanyo Electric Co., Ltd, Osaka, Japan). Recording was performed for 5 min in each auscultation at d 14, and 7 before parturition and at d 0, 0.25, 0.5, 1, 2, 3, 4, 5, and 7 following parturition. Recording before parturition (d 14 and 7) and after parturition (d 4, 5, and 7) were almost completed at 05:30 h before morning feeding (soon after blood sampling), but sampling for d 0, 0.25, 0.5, 1, 2, and 3 following parturition was performed counting from parturition hour. The number of ruminal contraction (time/min) was determined by dividing the number of contract frequencies within 5 min recording by 5 from both of direct auscultation and checking the sound waves processed by Sound it! 5.0 for windows (SIT50W, Internet Co., Ltd, Osaka, Japan) (Figure 1).

Figure 1

Sound waves of ruminal contractions processed by Sound it! 5.0 for windows (SIT50W, Internet Co., Ltd, Japan). Recording was performed for 5 min from upper left flank of the cow using stethoscope connected sound recorder (ICR-S340RM, Sanyo Electric Co., Ltd, Japan). Closed symbols (♦) indicate the time regions/ places in which ruminal contractions occurred.

The BW was measured twice a week. The values were an average of twice a week measurements. Before parturition, the cows were weighed before morning feeding. After parturition, the cows were weighed at a period between after morning milking and before morning feeding. Milking was performed twice a day by bucket milker in the hospital pen. Milk samples were collected from each milking and, the components (fat, lactose, protein) were analyzed by Automatic Milk Analyzer (Milko-Scan FT+, FOSS, Hillerød, Denmark), and the values were an average of each analysis.

Data analysis

Data were expressed as mean±standard error of the mean (SEM) for the measurements of cows in each group. Statistical differences between the mean of groups were assessed using t-test. Comparisons of time-point measurements within a group were examined by least significant difference of one-way analysis of variance. Chi-square test was used to compare the time interval for recovery from the decline in serum Ca concentration soon after parturition between the groups. Multiple regression analysis was performed using four variable factors of first 7 d following parturition (the average of serum Ca concentration, ruminal contraction, milk yield, and daily BW change) to predict their effects on DM intake during first 7 d following parturition. The standard partial regression coefficient (β) was determined for each variable factor to compare its effects on DM intake. Correlations between the parameters were determined by Pearson’s procedure. All the analyses were run by Statistical Package for the Social Sciences (SPSS) for windows, version 16.0 (SPSS Inc., Chicago, IL, US), and statistical differences were declared at p<0.05, p<0.01, and p<0.001, respectively.

RESULTS

Serum calcium concentration

The results of serum Ca concentration are shown in Table 2. Before parturition period, serum Ca concentrations were above 9.0 mg/dL in both groups, and they did not differ between the groups (p>0.05). At parturition (d 0), serum Ca concentrations dropped sharply (p<0.05) in both groups (8.1±0.4 mg/dL in DFA group and 7.9±0.5 mg/dL in CONT group) and the lowest serum Ca concentrations were observed at d 0.25 following parturition (8.0±0.4 mg/dL in DFA group and 7.8±0.6 mg/dL in CONT group). Thereafter the cows in both groups began to regain their serum Ca concentrations to normal ranges (above 9.0 mg/dL, NRC, 2001). With numerically higher concentration, the cows in DFA group almost restored the serum Ca to the normal range 12 h after parturition, but the cows in CONT group took 48 h to restore the normal range of serum Ca. Statistical differences in serum Ca concentration and time interval for recovery of serum Ca levels following parturition to their normal range were not significant between the groups (p>0.05).

Changes in serum calcium concentration before and following parturition periods relative to cows in DFA and CONT groups1

Ruminal contracted frequency

The results of ruminal contraction are shown in Figure 2. Average ruminal contraction during 14 d before parturition in DFA group was 1.5±0.1 time/min, and that in CONT group was 1.4±0.1 time/min, and they did not differ between the groups (p>0.05). At parturition (d 0), ruminal contraction sharply decreased (p<0.05) in both groups (0.6±0.1 time/min in DFA group and 0.3±0.1 time/min in CONT group), and then began to recovery gradually. Following parturition, active ruminal contraction was observed in DFA group at d 1 (p<0.05), d 3 (p<0.05), and d 5 (p<0.01), respectively.

Figure 2

Ruminal contractions (time/min) during, before and following parturition. Symbols: (–●–) represents to the cows in difructose anhydride (DFA) group that received DFA III supplement, and (–○–) represents to the cows in CONT group that did not receive DFA III. The vertical bars on time-point measurements indicate the standard errors of the mean. * and ** indicate statistically differences between the groups at p<0.05 and p<0.01, respectively.

Feed intake

The results of feed intake are shown in Table 3. Average DM intake values during 14 d before parturition were 12.1±0.8 kg/d (1.6% BW) in DFA group and 12.0±0.9 kg/d (1.6% BW) in CONT group, and they did not differ between the groups (p>0.05). The lowest DM intake was observed at d 1 before parturition, and then DM intake began to increase gradually following parturition in both groups. During first 7 d following parturition, DM intake of DFA group increased from 14.8±2.8 kg/d (2.0% BW) to 19.6±2.1 kg/d (2.9% BW), and that of CONT group increased from 14.2±1.2 kg/d (1.9% BW) to 19.2±2.2 kg/d (2.7% BW), respectively. DM intake during first 7 d following parturition tended to be numerically higher in DFA group than CONT group, but significant differences were not observed between the groups (p>0.05).

Changes in dry matter and calcium intakes before and following parturition periods relative to cows in DFA and CONT groups1

Through the measurement period, Ca intakes were not different between the groups (p>0.05). Average Ca intakes, during 14 d before parturition were 42.1±2.8 g/d (DFA group) and 42.4±4.2 g/d (CONT group), and during first 7 d following parturition were 101.4±15.1 g/d (DFA group) and 94.6±14.3 g/d (CONT group), respectively.

Milk yield and body weight

The results of daily milk yield and weekly body weight are shown in Table 4. Numerically higher milk yield was observed in DFA group, but significant differences were not observed in milk yield and milk composition between the groups (p>0.05). Average milk fat, protein and lactose contents in DFA and CONT groups during first 7 d following parturition were 5.4% and 6.1%, 4.9% and 5.6%, and 4.0% and 4.1%, respectively.

Daily milk yield during first 7 d following parturition and weekly body weight changes before and following parturition periods relative to cows in DFA and CONT groups1

The BW changes were not different between the groups (p>0.05) throughout the measurement period. BW of cows in both groups declined at parturition and it continued following parturition. Daily BW changes in DFA and CONT groups during first 7 d following parturition were −4.6±0.5 kg/d and −3.8±0.7 kg/d, respectively.

DISCUSSION

Tight junction located on the luminal side of adjacent epithelial cells of the intestine is the gatekeeper of paracellular absorption pathway allowing the passage of nutrients including Ca (Ballard et al., 1995). An opening effect of DFA III on the tight junction channel has been identified by Mineo et al. (2002). Increased Ca uptake by DFA III supplement via paracellular pathway was demonstrated in rats (Suzuki et al., 1998; Mineo et al., 2004), and humans (Shigematsu et al., 2004). Sato et al. (2007) confirmed the positive effect of DFA III on serum Ca concentration at parturition and its inhibitory effect on hypocalcemia in dairy cows. However, significant effects of DFA III were not observed in our study.

With numerically higher concentration, the cows in DFA group of our study almost restored the decline in serum Ca due to parturition to their normal ranges (above 9.0 mg/dL, recommended level by NRC, 2001) at 12 h after parturition, but the cows in CONT group took 48 h to restore to the normal range (Table 2). Tendency for a shorter time interval for recovery of the decrease in Ca in DFA group might be due to the effect of DFA III supplement, but statistical differences were not observed between the groups (p>0.05). These results indicate that DFA III has limited effect and it cannot always improve serum Ca concentration in dairy cows. This ambiguous effect of DFA III in our study might be due to large variations in serum Ca concentration at different number of parities within the groups. It has been also reported that low parity cows have good efficiency in Ca absorption themselves due to active mechanisms of Ca homeostasis including both of transcellular and paracellular pathways and bone resorption pathway (Goff et al., 1991; Bronner, 1992; Kamiya et al., 2005), and they can maintain the serum Ca at a steady concentration without any treatments. On the other hand, multiparous or high parity cows have poor efficiency in Ca absorption due to inactivation of transcellular pathway (Horst et al., 1990; Goff et al., 1991) and interference of bone resorption pathway (Ramberg et al., 1970; Kamiya et al., 2005) due to aging. Therefore, they are dependent on the paracellular absorption pathway to maintain the serum Ca at a steady concentration. Romo et al. (1991) and Kume et al. (2003) also reported that high parity in cows had a negative effect on serum Ca concentration, and serum Ca decline due to parturition in dairy cows increased with the parity. It should be considered from these reports that the action of DFA III on Ca uptake via paracellular pathway will have a relatively greater effect in multiparous cows when compared to primiparous cows. All the cows used in the study of Sato et al. (2007) were multiparous cows (parity ≥2), and there was a significant effect of DFA III on serum Ca concentration. Sato et al. (2007) also showed that a significant effect of DFA III on serum Ca concentration at parturition was more evident in cows with parity ≥3, and there was no significant effect in cows with parity 2 in their study, and it was suggested that effect of DFA III was different on different parity cows. The cows used in our study were not only multiparous but also primiparous cows in each group (1 to 5 parity variation in each group), and a clear effect of DFA III could not be detected due to the large variations in serum Ca concentration by different parity of cows within the groups. Therefore, cow parity should be considered as a factor in identifying the affect of DFA III on serum Ca concentration, and large variations in serum Ca concentration by different parity of cows within the groups in our study is one of the possible reasons of an unclear effect of DFA III.

Moreover, 50 g of DFA III (97% purity) were supplied to the cows in the study of Sato et al. (2007) from 21 d before parturition to parturition, and thereafter 180 g of that DFA III were supplied within 0.25 d after parturition. In our study, 40 g of DFA III were supplied from 14 d before parturition to 7 d following parturition in a uniform feeding procedure. It is not clear that the failure to detect a significant difference in serum Ca concentration in our study might be due to different feeding procedures and feeding different amounts of DFA III. There is no additional research work in transition dairy cows to predict whether different feeding procedures and different amounts of DFA III has any different effects on serum Ca concentration at or soon after parturition. However, it should be considered as one of the possible reasons for the ambiguous effect of DFA III in our study. In addition, it might be impossible to neglect the influence of nutrient composition of the offered diets on the Ca homeostasis mechanism; especially Ca like mineral contents should be considered as an influencing factor. The decline of serum Ca concentration at parturition is affected by the level of Ca content in the offered diets before parturition. According to the recommendation of NRC (2001), the optimal range of dietary Ca content before parturition is 0.44% to 0.48%. Ca content of basal diet (hay) used for before parturition period in the study of Sato et al. (2007) was 0.21% to 0.30%, and that in our study was 0.45% Ca in hay and 0.40% Ca in TMR (Table 1). The cows in DFA and CONT groups of our study received the optimal level of dietary Ca content before parturition when compared to the study of Sato et al. (2007). In the study of Sato et al. (2007), the decreased serum Ca concentration at d 0 in the cows supplied DFA III was 8.0±0.2 mg/dL, and that in the cows without DFA III was 6.6±0.3 mg/dL, then significant differences occurred between the groups (p<0.01), but in our study, the declined serum Ca at d 0 in DFA group was 8.1±0.4 mg/dL and that in CONT group was 7.9±0.5 mg/dL, and significant differences were not observed between the groups (p>0.05), due to higher serum Ca value of CONT group in our study. This higher serum Ca value of CONT group might be due to receiving of the optimal level of dietary Ca content before parturition when compared to the study of Sato et al. (2007). No further decline in serum Ca at d 0 of CONT group might result in the ambiguous effect of DFA III on serum Ca concentration following parturition in our study. Anyway, further studies should be carried out to identify which factors are restricting improvement of serum Ca concentration soon after parturition by DFA III supplement.

Furthermore, it has been reported that serum Ca has unique role in muscular contractive activity (Johansson, 1987; Van Breemen and Saida, 1989). Huber et al. (1981) reported that rumen contraction of sheep gradually decreased according to a decreased in serum Ca concentration. Daniel (1983) also reported for sheep and cow that there were positive correlations between serum Ca concentration and contraction rate of the rumen in the ranges of serum Ca 4.0 to 12.0 mg/dL. In our study, ruminal contraction sharply declined at parturition (p<0.05) and, then began to recover gradually following parturition which was similar to changes of serum Ca. Active frequency of ruminal contraction was observed in the cows supplied DFA III at following parturition of d 1, 3, and 5 (Figure 2), though there were no significant differences in serum Ca concentration between the groups. The reason for this is still unclear. However, a positive correlation was observed in our study, as the studies of Huber et al. (1981) and Daniel (1983), between serum Ca concentration and ruminal contraction (r = 0.856, p<0.001) (Figure 3a) when serum Ca concentration ranged from 7.5 to 10.5 mg/dL. This result suggests that inactive ruminal contraction might be due to lower serum Ca concentration, and its weaken contraction soon after parturition could be recovered by improvement of serum Ca when it was below the normal range by parturition.

Figure 3

Correlations (a) between average serum calcium (Ca) concentration (mg/dL) and average ruminal contraction (time/min) (r = 0.856, p<0.001), (b) between average serum Ca concentration (mg/dL) and average dry matter (DM) intake (kg/d) (r = 0.776, p<0.001), and (c) between average ruminal contraction (time/min) and average DM intake (kg/d) (r = 0.773, p<0.001), during first 7 d following parturition. Symbols: (●) represents to the cows in difructose anhydride (DFA) group that received DFA III supplement, and (○) represents to the cows in CONT group that did not receive any DFA III.

Average DM intake during 14 d before parturition in our study was 1.6% BW in both groups which is in agreement with the studies reported by Bertics et al. (1992) and Hayirli et al. (1999), however, DM intake is not a constant value (Hayirli et al., 2002), and the DM intake decreases before parturition and increases following parturition is huge in dairy cows (Vandehaar et al., 1999). Generally, the lowest DM intake was observed at parturition day (Ingvartsen and Andersen, 2000), but in our study, the lowest DM intake was observed at d 1 prior to parturition and, DM intake started to increase on parturition day. This might be due to changes of feeding diets (from TMR formulated by F:C of 89:11 to TMR formulated by F:C of 76:24) and changes of feeding procedures (from TMR and hay restricted feeding to TMR ad-libitum feeding+concentrate supplement) on that parturition day. Following parturition, the cows supplied DFA III in our study tended to have a numerically higher feed intake than the cows not supplied DFA III (Table 3), but there were no statistical differences between the groups (p>0.05). This was due to large variations in DM intake within the groups as in case of serum Ca concentration. However, positive correlations were observed in our study between serum Ca concentration and DM intake (r = 0.776, p<0.001) (Figure 3b), and between ruminal contraction and DM intake (r = 0.773, p<0.001) (Figure 3c). These correlations obtained from our study (Figures 3a, b, and c) indicate that serum Ca concentration, ruminal contraction and DM intake are closely related to each other, and improvement of feed intake soon after parturition might be reflected by either active ruminal contraction or specific higher concentration of serum Ca or both. It is certain that serum Ca concentration is the physiologically active fraction for muscular contraction including the smooth muscle of gastrointestinal tract (Johansson, 1987; Van Breemen and Saida, 1989). Depression of ruminal motility was due to lower level of serum Ca concentration, and it has already been identified for cows by Daniel (1983). Goff (2004) also reported that cow with lower level of serum Ca concentration typically developed inactive digestive tract motility. It means that improvement to an optimal concentration of serum Ca may cause the activation of ruminal contraction. Consequently, an active frequency of ruminal contractions may promote the passage rate of digesta through the gastrointestinal tract, which may reduce the degree of ruminal fill and increase the cows’ appetite, resulting in an increase of feed intake (Forbes, 1995). In fact, if the low serum Ca concentration by parturition could not be improved soon after parturition, it might be impossible to increase DM intake following parturition because of weaken ruminal contractions. Overall, findings from these reports indicate that a rapid recovery of serum Ca soon after parturition is practical solution not only to increase the frequency of ruminal contractions but also to improve DM intake in dairy cows.

DM intake is complicated in dairy cows. There are numerous factors restricting DM intake of dairy cows as reported by Grant and Albright (1995), Ingvartsen and Andersen (2000), NRC (2001), and Hayirli et al. (2002). According to the multiple regression equation obtained from our study (R2 = 0.824, p<0.001) (Table 5), average daily DM intake during first 7 d following parturition was positively influenced by the average of serum Ca concentration, ruminal contraction, milk yield and daily BW change during that period. The standardized partial regression coefficient of the equation was the highest for milk yield (1.257), and second highest for serum Ca concentration (0.526), and third highest for ruminal contraction (0.248). This regression suggests the importance of serum Ca concentration and ruminal contraction for improving DM intake, and DM intake soon after parturition in dairy cows could be increased by increasing serum Ca concentration or the frequency of ruminal contraction. Though factors affecting feed intake of dairy cows after parturition are numerous and complex (Grant and Albright, 1995; Ingvartsen and Andersen, 2000; NRC, 2001), serum Ca concentration and ruminal contractions should be considered as the key factors restricting feed intake.

Multiple regression analysis for average DM intake during first 7 d following parturition (kg/d, R2 = 0.824, p<0.001)

CONCLUSION

A clear effect of DFA III on serum Ca concentration was not obtained in our study, and first hypothesis was rejected. More data is required to prove the detail effectiveness of DFA III. On the other hand, second hypothesis was proved in our study. There was a significant positive effect of serum Ca concentration on DM intake, and serum Ca concentration should be considered as a factor playing on feed intake of dairy cows soon after parturition.

ACKNOWLEDGMENTS

Special thanks are due to staff of Field Science Center (Obihiro University, Japan) for the use of their facilities and their generous help in necessaries. We are highly appreciative to Professor Dr. Kida Katsuya’s Laboratory (Obihiro University, Japan) for their kindly analysis of the serum components.

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Article information Continued

Figure 1

Sound waves of ruminal contractions processed by Sound it! 5.0 for windows (SIT50W, Internet Co., Ltd, Japan). Recording was performed for 5 min from upper left flank of the cow using stethoscope connected sound recorder (ICR-S340RM, Sanyo Electric Co., Ltd, Japan). Closed symbols (♦) indicate the time regions/ places in which ruminal contractions occurred.

Figure 2

Ruminal contractions (time/min) during, before and following parturition. Symbols: (–●–) represents to the cows in difructose anhydride (DFA) group that received DFA III supplement, and (–○–) represents to the cows in CONT group that did not receive DFA III. The vertical bars on time-point measurements indicate the standard errors of the mean. * and ** indicate statistically differences between the groups at p<0.05 and p<0.01, respectively.

Figure 3

Correlations (a) between average serum calcium (Ca) concentration (mg/dL) and average ruminal contraction (time/min) (r = 0.856, p<0.001), (b) between average serum Ca concentration (mg/dL) and average dry matter (DM) intake (kg/d) (r = 0.776, p<0.001), and (c) between average ruminal contraction (time/min) and average DM intake (kg/d) (r = 0.773, p<0.001), during first 7 d following parturition. Symbols: (●) represents to the cows in difructose anhydride (DFA) group that received DFA III supplement, and (○) represents to the cows in CONT group that did not receive any DFA III.

Table 1

Ingredient and chemical compositions of DFA III feed and other basal diets

DFA III feed1 Before parturition Following parturition


H TMR2 Top-dressed3 TMR
Ingredient compositions4 --------------------------------------------------- % of fresh weight --------------------------------------------
 Grass hay - 100.00 - - -
 Grass silage - - 30.83 - 42.91
 Corn silage - - 57.80 - 33.44
 Steamed flaked corn - - - - 10.69
 Concentrate C17 - - 7.71 - -
 Concentrate C18 - - - 95.24 7.01
 Soybean meal - - 2.89 - 3.62
 Beet pulp 80.00 - - - 1.96
 Magnesium oxide - - - - 0.04
 Calcium phosphate - - - 4.76 0.10
 Calcium carbonate - - - - 0.20
 Vitamin (premixed) - - 0.77 - 0.03
 DFA III 20.00 - - - -
Chemical compositions5
---------------------------------------------------- % of fresh matter -----------------------------------------------
 DM 90.41 86.92 54.21 86.44 38.54
---------------------------------------------------- % of dry matter -------------------------------------------------
 CP 7.50 12.85 13.42 22.90 15.81
 ADICP 0.50 2.10 1.40 1.22 1.12
 NDICP 2.69 7.10 3.65 3.42 2.62
 ADF 12.50 40.12 30.52 11.2 25.20
 NDF 23.32 63.50 49.81 22.85 42.21
 NFC 65.53 18.87 28.9 46.65 32.88
 EE 0.80 2.30 2.89 3.72 3.83
 Ash 4.20 9.20 8.01 6.34 7.21
 Lignin 3.41 6.56 4.42 2.81 3.21
 Ca 0.38 0.45 0.40 1.10 0.71
 P 0.05 0.25 0.21 0.60 0.43
 Mg 0.11 0.20 0.21 0.30 0.30
 K 0.54 1.86 2.01 0.92 1.71
-------------------------------------------------- Mcal/kg of dry matter -------------------------------------------
 NEL 1.57 1.27 1.44 1.78 1.58

DFA, difructose anhydride; H, grass hay; TMR, total mixed ration; DM, dry matter; CP, crude protein; ADICP, acid detergent insoluble crude protein; NDICP, neutral detergent insoluble crude protein; ADF, acid detergent fiber; NDF, neutral detergent fiber; NFC, non-fibrous carbohydrate; EE, ether extract; Ca, calcium; P, phosphorus; Mg, magnesium; K, potassium; NEL, net energy for lactation; -, no ingredient.

1

DFA III feed (Miracle oligosaccharide, Nippon Beet Sugar Mfg. Co., Ltd, Japan) supplemented to cows in DFA group.

2

TMR offered to cows in DFA and CONT groups.

3

Values in chemical composition of the top-dressed are only by concentrate C18.

4

Commercial products: concentrate C17 (Dry-base 17, Hokuren Cooperative Feed Mills Co., Ltd, Japan); concentrate C18 (Mo-dairy 18, Nippon Formula Feed Mfg. Co., Ltd, Japan); soybean meal (Daizu meal, J-Oil Mills, INC, Japan); beet pulp (Beet pulp pellet, Nippon Beet Sugar Mfg. Co., Ltd, Japan); magnesium oxide (Magumaito, Yushiseihin Co., Ltd, Japan); calcium phosphate (Dibasic, Obanaya Cementex Co., Ltd, Japan); calcium carbonate (Nittetsukou Tancal, Nittetsu Mining Co., Ltd, Japan); premixed vitamins (Yoka vita-M-mash, Snow Brand Seed Co., Ltd, Japan).

5

Values are average of weekly analysis.

Table 2

Changes in serum calcium concentration before and following parturition periods relative to cows in DFA and CONT groups1

Day DFA group CONT group p-value
Before parturition
 14 9.8±0.1a 9.9±0.2a 0.478
 7 9.7±0.1a 9.8±0.1a 0.519
 5 9.8±0.1a 9.6±0.1a 0.252
 3 9.6±0.1a 9.8±0.1a 0.217
 1 9.3±0.4a 9.9±0.3a 0.258
Following parturition
 0 8.1±0.4b 7.9±0.5b 0.827
 0.25 8.0±0.4b 7.8±0.6b 0.742
 0.5 9.6±0.5a 8.9±0.5ab 0.375
 1 9.3±0.4a 8.9±0.9ab 0.515
 2 9.9±0.3a 9.4±0.3a 0.200
 3 10.0±0.3a 9.7±0.3a 0.555
 4 10.0±0.2a 9.5±0.3a 0.150
 5 9.6±0.2a 10.1±0.3a 0.163
 7 9.5±0.1a 9.8±0.2a 0.177

DFA, difructose anhydride.

1

DFA group, cows group that received DFA III supplement; CONT group, cows group that did not receive any DFA III.

Values are expressed as mean±standard error of the mean.

a,b

Different superscripts within a group are statistically different at p<0.05.

Table 3

Changes in dry matter and calcium intakes before and following parturition periods relative to cows in DFA and CONT groups1

Day DM intake (kg/d, % BW) Ca intake (g/d)


DFA group1 CONT group1 p-value DFA group CONT group p-value
Before parturition
 14 12.2±0.8a (1.6) 12.1±1.0a (1.6) 0.945 39.8±3.0a 41.8±4.3a 0.713
 7 12.8±0.8a (1.6) 12.2±0.7a (1.6) 0.596 45.8±3.4a 44.3±4.0a 0.786
 5 12.5±0.8a (1.6) 12.8±1.0a (1.6) 0.804 44.2±2.5a 48.2±4.3a 0.885
 3 12.6±0.6a (1.6) 12.0±0.7a (1.6) 0.573 45.7±2.3a 44.5±5.3a 0.808
 1 11.8±1.0a (1.6) 10.9±1.1a (1.5) 0.531 44.0±4.3a 39.2±1.9a 0.170
Following parturition
 0 14.8±2.8ab (2.0) 14.2±1.2ab (1.9) 0.848 91.8±17.3b 73.7±12.4ab 0.413
 1 17.2±1.3bc (2.4) 15.5±1.8abc (2.0) 0.466 104.5±13.7b 86.8±13.9bc 0.383
 2 17.3±1.0bc (2.5) 16.6±1.9bc (2.2) 0.743 97.3±13.4b 99.8±11.6bc 0.890
 3 17.9±1.0bc (2.6) 16.9±1.5bc (2.3) 0.565 97.6±16.1b 102.2±11.4bc 0.817
 4 17.8±1.6bc (2.6) 16.3±1.0abc (2.2) 0.433 109.3±12.1b 97.5±07.9bc 0.431
 5 17.7±1.2bc (2.6) 16.3±1.7abc (2.3) 0.508 105.3±11.8b 99.0±14.2bc 0.737
 6 18.2±2.5bc (2.7) 16.0±2.2bc (2.2) 0.524 99.5±16.7b 88.9±21.8bc 0.704
 7 19.6±2.1c (2.9) 19.2±2.2c (2.7) 0.891 105.6±20.0b 108.7±21.8bc 0.919

DFA, difructose anhydride; DM, dry matter; BW, body weight.

1

DFA group, cows group that received DFA III supplement; CONT group, cows group that did not receive any DFA III.

Values are expressed as mean±standard error of the mean.

a,b,c

Different superscripts within a group are statistically different at p<0.05.

Table 4

Daily milk yield during first 7 d following parturition and weekly body weight changes before and following parturition periods relative to cows in DFA and CONT groups1

Day Milk yield (kg/d) Body weight (kg)


DFA group1 CONT group1 p-value DFA group CONT group p-value
Before parturition
 14 - - - 757±28.5ab 760±28.9ab 0.946
 7 - - - 770±28.8a 768±29.9a 0.960
Following parturition
 0 18.7±4.3a 16.4±4.0a 0.709 708±30.4ab 700±30.4ab 0.871
 1 27.8±3.3b 25.3±3.0b 0.588 - - -
 2 33.2±2.6bc 31.1±2.8bc 0.586 - - -
 3 36.1±2.5c 32.2±3.2bc 0.366 - - -
 4 36.2±3.2c 32.9±2.5bc 0.418 - - -
 5 39.6±2.2c 36.2±2.9c 0.360 - - -
 6 39.1±2.3c 37.9±3.2c 0.773 - - -
 7 41.6±1.7c 39.7±2.7c 0.779 676±30.6b 674±30.6b 0.973

DFA, difructose anhydride; -, no measured.

1

DFA group, cows group that received DFA III supplement; CONT group, cows group that did not receive any DFA III.

Values are expressed as mean±standard error of the mean.

a,b,c

Different superscripts within a group are statistically different at p<0.05.

Table 5

Multiple regression analysis for average DM intake during first 7 d following parturition (kg/d, R2 = 0.824, p<0.001)

Variables, during first 7 d following parturition r1 Partial regression coefficient p-value2 β3
Average serum Ca concentration (mg/dL) 0.776 1.119 <0.001 0.526
Average ruminal contraction (time/min) 0.773 0.989 <0.001 0.248
Average milk yield (kg/d) 0.890 0.253 <0.001 1.257
Daily body weight change (kg/d) 0.493 0.015 0.037 0.159
Intercept 18.361 <0.001

DM, dry matter.

1

r, single correlation between dependent variable and each explanatory variable.

2

p-value is for partial regression coefficient of multiple regression analysis.

3

β, the standardized partial regression coefficient of multiple regression analysis.