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Does the time of microencapsulated sodium butyrate supplementation have any effect on the growth performance and health of Holstein dairy calves?

Published online by Cambridge University Press:  25 November 2022

M. M. Eskandary
Affiliation:
Department of Animal Science, Faculty of Agriculture and Natural Resources, Arak University, 38156 Arak, Iran
M. Hossein Yazdi*
Affiliation:
Department of Animal Science, Faculty of Agriculture and Natural Resources, Arak University, 38156 Arak, Iran
E. Mahjoubi
Affiliation:
Department of Animal Science, University of Zanjan, 45371-38791 Zanjan, Iran
M. Kazemi-Bonchenari
Affiliation:
Department of Animal Science, Faculty of Agriculture and Natural Resources, Arak University, 38156 Arak, Iran
*
Author for correspondence: M. Hossein Yazdi, E-mail: m-hosseinyazdi@araku.ac.ir, mehdihoseinyazdi@yahoo.com
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Abstract

The optimal feeding time of microencapsulated sodium butyrate (SB) in whole milk (WM) and starter feed on growth performance and health in dairy calves was evaluated. Forty-eight newborn Holstein calves (body weight (BW) = 39.45 ± 2.48 kg) were randomly assigned to one of the four treatment groups (12 calves per treatment; seven females and five males) in a complete randomized block design and fed (1) WM without microencapsulated SB (CON) supplementation; (2) 4 g/day SB added to WM since days 4–32 (SB-4-32); (3) 4 g/day SB added to WM since days 61–74 and an equal amount was added to starter since days 75–88 (SB-61-88) and (4) 4 g/day SB added to WM since days 4–74 and an equal amount was added to starter since days 75–88 (SB-4-88). Total dry matter intake, starter intake, BW, average daily gain and gain-to-feed were similar between treatments. Calves fed SB-4-32, and SB-4-88 had lower faecal score during pre-weaning, and overall. In addition, calves in SB-4-32 and SB-4-88 groups had fewer numbers of days with scours during the pre-weaning period, and throughout the study. Calves fed SB-61-88 had greater serum total protein during post-weaning. Post-weaning and overall albumin concentrations were greater in SB-4-32 and SB-4-88 calves and tended to be greater in the pre-weaning period compared to control calves. In general, the time of SB addition had no remarkable effect on performance but better faecal score within the pre- and post-weaning periods.

Type
Animal Research Paper
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press

Introduction

Butyric acid, one of the short-chain fatty acids, is a natural substance present in the rumen of ruminants, colons of monogastric species, cow milk (0.16 g/l; Alais, Reference Alais1984; Guilloteau et al., Reference Guilloteau, Martin, Eeckhaut, Ducatelle, Zabielski and Van Immerseel2010a). It has been well-documented that butyrate is an important stimulator and regulator of ruminal epithelium growth as well as its function. It appears that the indirect effect of sodium butyrate (SB) on rumen development is clearer (Penner et al., Reference Penner, Steele, Aschenbach and McBride2011). In ruminants, the most important source of butyrate is the microbial fermentation of carbohydrates in the rumen (Bergman, Reference Bergman1990). Within the first 1–2 weeks of a calf's life, the amount of solid feed intake is very low and rumen microflora is not fully functioning; this leads to a very low butyrate concentration in the yet underdeveloped rumen until the regular solid feed intake starts and rumen microflora develops (Anderson et al., Reference Anderson, Nagaraja and Morrill1987; Flaga et al., Reference Flaga, Gorka, Zabielski and Kowalski2015). Thus, before the development of the rumen, milk butyrate is the main source of this molecule for the newborn calf. On the other hand, calves are fed mostly with whole milk (WM) or milk replacer (MR) before weaning and the abomasum and small intestine are the main sites of feed digestion. Therefore, the development of these gastrointestinal tract (GIT) compartments is crucial for nutrient absorption, performance and health of milk-fed calves. Because GIT development can have impact on the feed intake, the efficiency of digestion and resistance to gastrointestinal disorders and in this way animal growth and health, each method enhancing these processes are highly desirable. Thus, supplementing liquid or starter feed with butyrate may be a good strategy to improve rumen and intestinal development in calves (Gorka et al., Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak, Holst, Guilloteau and Zabielski2011a).

The effect of dietary butyrate supplementation could be modulated by butyrate protection from its release and utilization in the stomach (both forestomach and abomasum) in order to releasing in the distal sections of the intestine and increasing butyrate content in the large intestine (Mallo et al., Reference Mallo, Balfagon, Gracia, Honrubia and Puyalto2012). Embedding in the continuous lipid matrix often referred to as microencapsulation or fat coating, is commonly used for this purpose (Claus et al., Reference Claus, Gunthner and Letzgb2007; Gorka et al., Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak, Holst, Guilloteau and Zabielski2011a, Reference Gorka, Pietrzak, Kotunia, Zabielski and Kowalski2014; Moquet et al., Reference Moquet, Onrust, van Immerseel, Ducatelle, Hendriks and Kwakkel2016). Of potential advantage, protected butyrate is released slowly from the fat coat, providing the possibility for its more uniform distribution in the small and large intestines. Therefore, protected butyrate is more likely to affect the structure and function of the large intestine through butyrate delivery to the very last sections of the intestine. This seems to be especially beneficial taking into account the high susceptibility of newborn calves to diarrhoea (Gorka et al., Reference Gorka, Kowalski, Zabielski and Guilloteau2018).. It has been well demonstrated in numerous studies that butyrate supplementation through either un-protected or protected SB in MR and starter feed (Hill et al., Reference Hill, Aldrich, Schlotterbeck and Bateman2007; Guilloteau et al., Reference Guilloteau, Savary, Jaguelin-Peyrault, Rome, Le Normand and Zabielski2010b; Reference Gorka, Pietrzak, Kotunia, Zabielski and KowalskiGorka et al., Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak, Holst, Guilloteau and Zabielski2011a, Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak and Zabielski2011b, 2014; Roh et al., Reference Roh, Kimura, Sakamoto, Nishihara, Suzuki and Katoh2018; Koch et al., Reference Koch, Gerbert, Frieten, Dusel, Eder, Zitnan and Hammon2019; Wu et al., Reference Wu, Meng, Wang, Wang, Xu, Xiao and Xu2022), and acidified milk (Sun et al., Reference Sun, Li, Meng, Wu and Xu2019) have pronounced effects on growth performance, feed efficiency, GIT development and health of dairy calves through modulation of proliferation, differentiation, stimulated pancreatic secretions and function of the GIT tissues.

Even though butyrate is naturally found in cow's milk, it seems that adding extra SB to milk can improve dairy calves' performance because of its small amount. To our knowledge, there is limited study in neonatal calves in which SB (unprotected form) has been added to WM during the pre-weaning period (Mahjoubi et al., Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020); it has been indicated that SB (4 or 8 g/day) could improve calf performance. Davarmanesh et al. (Reference Davarmanesh, Fathi Nasiri, Kalantari Firouzabad and Montazer-Torbati2015) supplemented unprotected form of calcium butyrate salt to WM only for 23 days. On the other hand, only one study indicated the effect of protected butyrate supplementation in MR (Nazari et al., Reference Nazari, Karkoodi and Alizadeh2012). Also, Mahjoubi et al. (Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020) stated that the time of SB supplementation might have some impacts on calf performance. Due to the limited documents in this regard, we decided to investigate the different times of SB supplementation to address the above-mentioned concerns.

Based on the early mentioned considerations, we hypothesized that the addition of protected SB to WM and deliver it to the small intestine could improve calf growth performance and health status when it is added in the first month of life and/or in the transition period. Therefore, the aim of the current study was to (1) determine the optimum age for SB inclusion in WM and (2) investigate the effect of WM supplemented with protected SB on the incidence of diarrhoea and calf performance.

Materials and methods

The current experiment was performed from January to April 2021 in a commercial dairy farm (Avin Dasht, Qazvin, Iran) according to the guidelines of the Iranian Council of Animal Care (1995). This farm is located in a sub-tropical area (longitude 49°29′E and latitude 35°57′N).

Calves, treatments and housing

Forty-eight Holstein dairy calves (28 females and 20 males, average body weight (BW) = 39.48 ± 2.48 kg) were randomly assigned to treatments (n = 12 calves per treatment; seven females and five males) in a complete randomized block design. After birth, all calves were separated from their dams immediately and placed in individual pens (1.5 × 2.0 m2) bedded with clean wheat straw. The calves were fed 4 litres of colostrum at the first 12 h of life (2.5 litres until 1 h after birth and 1.5 litres at 12 h after the first feeding). On days 2 and 3 of life, calves received transition milk (4 litres) in two meals of equal volume (at 8.00 and 20.00 h). After that, calves were randomly assigned into 1–4 experimental treatments from day 4 and were blocked by sex. Treatments were as follows: (1) control without microencapsulated SB (CON) supplementation; (2) 4 g/day SB (Novyrate®C) added to milk since days 4–32 (SB-4-32); (3) 4 g/day SB added to milk since days 61–74 and an equal amount was added to starter since days 75–88 (SB-61-88) and (4) 4 g/day SB added to milk since days 4–74 and an equal amount was added to starter since days 75–88 (SB-4-88). Pre-weaning (from days 4 to 74) the SB was incorporated into WM and mixed by a strew before calf drink and the post-weaning (from days 75 to 88) was top-dressed to starter feed to make sure each calf eats the SB. In order to make sure that each calf consumed the respective amount of SB, it was mixed with ~50–70 g of daily starter feed allowance and top-dressed. Novyrate®C is a coated butyrate product (containing 320 g SB as microencapsulated, 990 g/kg dry matter (DM), 610 g/kg crude fat, 64 g/kg sodium; Novyrate®C, Innovad Co, Essen, Belgium). Fat coating ensures that butyrate is primarily directed into the small and large intestines where pancreatic lipases gradually remove the fat coating. The gradual releasing pattern of protected SB product was verified by an in vitro assessment (https://issuu.com/innovad4/docs/novyratenovbroen28102016ldef). All calves were individually fed the same volumes of WM (35 g fat, 31.5 g crude protein (CP), 46.7 g lactose, 8 g ash and 121.2 g total solids per kg of milk, 3.4 ± 0.7 g/100 g fatty acids butyric acid) two times per day at 8.00 and 20.00 h with an accelerated nutritional plan, which is illustrated in Fig. 1 and weaned at day 74 of age. After weaning, all calves remained in individual stalls until day 88 of age to collect the post-weaning data. The calves had free access to fresh starter feed and water throughout the study (from day 4 until 88). The starter feed composed of 900 g/kg DM concentrate and 100 g/kg DM chopped alfalfa hay was fed as a total mixed ration every morning at 8.30 h. Diet was formulated using National Research Council (2001) software and the chemical composition of the starter feed is presented in Table 1. The starter feed formulation was constant across experimental treatment during the pre- and post-weaning periods.

Fig. 1. Schematic diagram represents the amounts of milk consumed (kg/day) by calves; 5 litres of milk/day from 4 to 16 days, 7 litres/day from 17 to 59 days, 6 litres/day from 60 to 63 days, 5 litres/day from 64 to 66 days, 4 litres/day from 67 to 69 days and 2 litres/day from 70 to 74 days of age.

Table 1. Starter diet ingredients and chemical composition

a Contained per kg of the supplement: 500 000 IU vitamin A, 130 000 IU vitamin D, 6000 IU vitamin E, 10 g Ca, 10 g P, 20 g Mg, 4100 mg Zn, 15 mg Co, 1000 mg Cu, 4000 mg Mn, 35 mg I, 5000 mg Fe and 30 mg Se, 2000 mg monensin.

b Calculated using the NRC (2001) model.

c Non-fibre carbohydrate was calculated as [DM − (NDF + CP + ether extract + ash)] (NRC, 2001).

Measurement of dry matter intake (DMI), BW and health

Throughout the study, offered and refused feed was weighed daily to determine the total starter intake for the individual calf. When the calves consumed more than 1 kg of starter feed for 3 consecutive days, the first day of age that each calf met the specific starter feed consumption target of 1 kg was recorded and used to evaluate the time to consume 1 kg of starter feed. Individual BW (using an electronic scale) and body skeletal growth including body length, withers height, heart girth and hip height were recorded on days 4, 32, 60, 74 and 88 before the morning feeding meal, and average daily gain (ADG) was calculated as the difference between two consecutive BW measurements divided by days. Gain-to-feed ratio was calculated as grams of ADG divided by grams of total DMI (liquid feed DMI + starter feed DMI). Samples of starter feed were collected throughout the study (n = 4, 20 day sampling intervals) for the determination of DM and chemical analyses. Samples of starter feeds were dried in a convection oven (60°C for 48 h). Subsamples of dried feeds were composited by treatment and ground in a mill (Ogaw Seiki Co., Ltd., Tokyo, Japan) to pass a 1-mm screen. Feed samples analysed for CP (AOAC, 2000; 984.13), ether extract (EE; AOAC, 2000; ID 920.39), ash (AOAC, 2000; ID 942.05), neutral detergent fibre (NDF; Van Soest et al., Reference Van Soest, Robertson and Lewis1991). The alpha-amylase and sodium sulphite were not used in the NDF assay. Milk composition was measured every 14 days from bulk tank samples. An aliquot of milk was frozen (−20°C) without preservatives for subsequent butyric acid analysis. Fatty acid methyl esters of the lipid in milk samples were prepared and then analysed under GC (6890 N, Agilent Technologies, Santa Clara, CA, USA) conditions described by Shingfield et al. (Reference Shingfield, Ahvenjärvi, Toivonen, Ärölä, Nurmela, Huhtanen and Griinari2003).

Health condition of calves was assessed daily according to Larson et al. (Reference Larson, Owen, Albright, Appleman, Lamb and Muller1977) and Heinrichs et al. (Reference Heinrichs, Jones, Van Roekel and Fowler2003). One of the authors performed the health scoring and each time was the same person. Faecal scoring was as follows: 1 = firm, 2 = soft, 3 = soft and running, 4 = watery. General appearance scoring was: 1 = normal and alert; 2 = ears drooped; 3 = head and ears drooped, dull eyes, slightly lethargic; 4 = head and ears drooped, dull eyes, lethargic and 5 = severely lethargic. For calves that need medical treatments, the farm's veterinarian administrated the proper drug, and the treatment was followed according to his recommendation; therefore, medical days, treatment bouts and the number of used drugs were recorded to be statistically analysed.

Blood sampling and analyses

Blood samples from each calf were collected from the jugular vein into 10 ml tubes 4 h after morning feeding on days 4, 32, 60, 74 and 88. Blood samples were placed on ice immediately after collection and centrifuged at 3000 g (Kubota Co., Bunkyo City, Tokyo, Japan) for 15 min at 4°C to obtain serum, and then serum samples were frozen at −20°C until future analyses. It took 1 h from blood sampling to storage. Serum subsamples were analysed to determine concentrations of glucose (mg/dl), albumin (g/dl) and total protein (TP, g/dl) using commercial kits (Pars Azmoon Co., Tehran, Iran). Serum concentrations of beta-hydroxybutyrate (BHB, mmol/l) were measured using a commercial kit (Ranbut, Randox Laboratories Limited, Crumlin, County Antrim, Randox, UK); the inter- and intra-assay coefficient of variation for the glucose assay were 2.34 and 2.72%, respectively, and for the BHB assay were 2.91 and 3.45%, severally.

Statistical analysis

Before data analysis, all data were evaluated for normality using the UNIVARIATE procedure of SAS (version 9.4; SAS Institute Inc., Cary, NC). A pre-study power analysis for sample size assessment was carried out for the primary response variables, including weight gain, ADG, body skeletal growth and blood metabolites according to recent published literature (Sun et al., Reference Sun, Li, Meng, Wu and Xu2019; Mahjoubi et al., Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020; Liu et al., Reference Liu, La Teng Zhu La, Evans, Gao, Yu, Bu and Ma2021; Wu et al., Reference Wu, Meng, Wang, Wang, Xu, Xiao and Xu2022). The predicted sample size was 12 calves per treatment group for variables related to growth performance and blood metabolites (α = 0.05 and power = 0.85). Therefore, 48 animals (12 calves per treatment) were considered sufficient to get a significant result with adequate power in performance among the treatment groups. Total DMI, starter feed intake, faecal scores, general appearance scores and blood metabolite data were subjected to analysis of variance (ANOVA) using the MIXED procedure of SAS with time as repeated measures during the overall experiment. The model consisted of treatment, sex, time and their interactions were included as the fixed effects, and calf within treatment was included as a random effect. Sex was not significant and thus removed from the original model. Initial BW, initial skeletal growth parameters and blood data were considered as a covariate for the BW, skeletal growth and blood metabolites analysis but were removed from the final models because no differences due to these factors were found (P > 0.20). BW, gain-to-feed ratio, body skeletal growth data and days experiencing a health criterion were not analysed as repeated measures and they were analysed by the generalized linear model. Three variance–covariance structures (autoregressive order 1, unstructured or compound symmetry) were tested and the autoregressive order 1 covariance structure yielded the smallest Schwarz's Bayesian information criterion. In addition to the overall F test, differences among treatments were assessed using orthogonal contrast (CON v. SB-4-32, SB-61-88 and SB-4-88). The POLYANOVA model was considered for performance and blood data. Linear and quadratic contrasts were reported from this statistical analysis during each period. The statistical model used for analysis was:singledollarY_{ijk} = \mu + {\rm Treatmen}{\rm t}_i + {\rm Tim}{\rm e}_j + \lpar {{\rm Treatment} \times {\rm time}} \rpar _{ij} + {\rm cal}{\rm f}_k + \beta \lpar {Xi-X} \rpar + e_{ijk}singledollarwhere Yijk is the dependent variable, μ is the overall mean, Treatmenti is the fixed effect of treatment, Timej is the fixed effect of time, (Treatment × Time)ij is the fixed effect of interaction between treatment and time, calfk is the random effect of calf, β (XiX) is the covariate variable and eijk is the residual error.

The number of days with diarrhoea was categorized with a faecal score ≥2 and the general appearance score (1–5) was categorized as the number of days with a general appearance score ≥2 (Jahani-Moghadam et al. Reference Jahani-Moghadam, Mahjoubi, Hossein Yazdi, Cardoso and Drackley2015). Because the variance of the number of days with faecal and general appearance score ≥2 was not uniformly distributed, these variables were square-root transformed for better homogeneity of the distribution of residuals (means shown in Table 5 for these variables are back-transformed). The same was carried out for medical days, treatment bouts and the number of used drugs. The least-squares means for treatment effects was separated by the use of the PDIFF statement. Significance was declared at P ≤ 0.05 and tendencies at P ≤ 0.10.

Results

Feed intake and growth performance

The results of DMI, starter intake, BW, ADG and gain-to-feed ratio are given in Tables 2 and 3. In general, daily DMI and starter intake did not differ among experimental treatments at any stage (P > 0.05). Supplementation with SB did not have impact on BW, ADG (Fig. 2) and gain-to-feed ratio (P > 0.05).

Fig. 2. ADG of calves supplemented with SB to WM. (♦) Control (CON) without microencapsulated SB supplementation; (■) with 4 g/day SB added to milk since days 4–32 (SB-4-32); (▴) with 4 g/day SB added to milk since days 61–74 and added to starter since days 75–88 (SB-61-88) and (×) with 4 g/day SB added to milk (since days 4–74) and the starter (since days 75–88) for the total experiment (SB-4-88).

Table 2. Effects of SB supplementation to WM on feed intake of Holstein calves (n = 12 calves per treatment)

a Treatments were: (1) without SB supplement (CON); (2) SB supplement added to milk from 4 to 32 days (SB-4-32); (3) SB supplement added to milk from 61 to 74 days and added to starter from 75 to 88 days (SB-61-88) and (4) SB supplement added to milk (since days 4–74) and the starter (since days 75–88) for the total experiment (SB-4-88).

b Standard error of the mean.

c Days 4–74.

d Days 61–88.

e Days 75–88.

Table 3. Effects of SB supplementation to WM on growth performance of Holstein calves (n = 12 calves per treatment)

aTreatments were: (1) without SB supplement (CON); (2) SB supplement added to milk from 4 to 32 days (SB-4-32); (3) SB supplement added to milk from 61 to 74 days and added to starter from 75 to 88 days (SB-61-88) and (4) SB supplement added to milk (since days 4–74) and the starter (since days 75–88) for the total experiment (SB-4-88).

bStandard error of the mean.

cDays 4–74.

dDays 61–88.

eDays 75–88.

fg daily gain/g daily dry matter intake.

The results of the structural growth indices are given in Table 4. There was no effect of treatments on structural growth indices on different days of the trial (P > 0.05).

Table 4. Effects of SB supplementation to WM on structural growth indices of Holstein calves (n = 12 calves per treatment)

a Treatments were: (1) without SB supplement (CON); (2) SB supplement added to milk from 4 to 32 days (SB-4-32); (3) SB supplement added to milk from 61 to 74 days and added to starter from 75 to 88 days (SB-61-88) and (4) SB supplement added to milk (since days 4–74) and the starter (since days 75–88) for the total experiment (SB-4-88).

b Standard error of the mean.

Health criteria

Faecal scores and general appearance scores are presented in Table 5. Compared to CON and SB-61-88, encapsulated SB inclusion in SB-4-32 and SB-4-88 groups decreased the faecal score during the pre-weaning (P = 0.043), and throughout the experiment (P = 0.034). However, the general appearance score did not differ among treatments at any stage (P > 0.05).

Table 5. Mean values for health criteria and days experiencing a health criterion of Holstein calves supplemented with SB (n = 12 calves per treatment)

a Treatments were: (1) without SB supplement (CON); (2) SB supplement added to milk from 4 to 32 days (SB-4-32); (3) SB supplement added to milk from 61 to 74 days and added to starter from 75 to 88 days (SB-61-88) and (4) SB supplement added to milk (since days 4–74) and the starter (since days 75–88) for the total experiment (SB-4-88).

b Standard error of the mean.

c 1 = firm, 2 = soft, 3 = soft and running and 4 = watery.

d Days 4–74.

e Days 61–88.

f Days with faecal score ≥2; faecal score was square-root transformed and back-transformed values are presented in the table.

g 1 = normal and alert; 2 = ears drooped; 3 = head and ears drooped, dull eyes, slightly lethargic; 4 = head and ears drooped, dull eyes, lethargic and 5 = severely lethargic.

h Days with general appearance score ≥2; general appearance was square-root transformed and back-transformed values are presented in the table.

i Treatment was carried out under on-farm protocol and according to the farm's veterinarian.

a,b Means within a row with different superscripts differ (P < 0.05).

The number of days with loose faecal score (≥2) were lower (P = 0.035 and P = 0.025; respectively) for calves fed on SB-4-32 and SB-4-88 diets compared to CON and SB-61-88 groups during the pre-weaning period and throughout the experiment; while, did not differ between treatments in the first month of life and the transition period (Table 5). In general, supplementation of the encapsulated SB in WM significantly decreased (P = 0.039) the number of days with loose faecal score compared with the control group during the pre-weaning period. With respect the entire period of the study, calves fed SB also tended (P = 0.066) to decrease the number of days with loose faecal score compared with the control group. Days with altered general appearance score, medical days, treatment bouts and the number of used drugs did not differ among treatments (P > 0.05; Table 5).

Blood metabolites

The results of the blood metabolites are presented in Table 6. The levels of serum glucose were not different among treatments at any stage (P > 0.05); however, the glucose concentration was reduced in calves fed SB-61-88 compared with CON and SB-4-88 calves on day 74 (P < 0.001). Serum BHB levels were not influenced among experimental treatments during the pre- and post-weaning (day 88) period (P > 0.05), but there was a significant effect of the interaction of treatment by time (P = 0.045) throughout the study. Serum BHB increased with the advancement in the study, but there was a tendency for SB-4-32 calves to have greater (P = 0.086) BHB level than CON and SB-61-88 calves on day 74. There was also a difference at day 88 for SB-61-88 and SB-4-88 calves to have higher (P < 0.001) BHB level than CON and SB-4-32 calves. Post-weaning TP concentration was higher (P < 0.001) for the SB-61-88 group than for other groups. Serum TP level in the post-weaning period also was significantly more elevated (P = 0.025) for encapsulated SB-fed calves than for CON calves. Furthermore, calves fed SB tended (P = 0.078) to have higher TP levels compared to CON calves throughout the study. Within the post-weaning and whole period, serum albumin level was higher (P = 0.010) in SB-4-32 and SB-4-88 groups than in the CON group. Moreover, calves fed encapsulated SB had higher serum albumin concentrations during the pre-weaning, the post-weaning and overall periods (P = 0.032 and P < 0.001; respectively) in comparison with calves without SB supplement. In addition, albumin concentration tended to be increased in calves fed SB compared with CON calves on day 60 (P = 0.067).

Table 6. Effects of SB supplementation to WM on serum metabolites of Holstein calves (n = 12 calves per treatment)

a Treatments were: (1) without SB supplement (CON); (2) SB supplement added to milk from 4 to 32 days (SB-4-32); (3) SB supplement added to milk from 61 to 74 days and added to starter from 75 to 88 days (SB-61-88) and (4) SB supplement added to milk (since days 4–74) and the starter (since days 75–88) for the total experiment (SB-4-88).

b Standard error of the mean.

a,b Means within a row with different superscripts differ (P < 0.05).

Discussion

Because they are more stable, generally odourless and easier to handle in the feed manufacturing processes, butyrate salts ( SB or calcium butyrate) or butyrins (esters of butyrate and glycerol) are often used instead of butyric acid itself in animal studies and in practice (Guilloteau et al., Reference Guilloteau, Martin, Eeckhaut, Ducatelle, Zabielski and Van Immerseel2010a). The SB, the most often used source of dietary butyrate because of its high availability and modest price, dissolves easily in water and rapidly dissociates in water solutions (Mallo et al., Reference Mallo, Balfagon, Gracia, Honrubia and Puyalto2012).

Feed intake and growth performance

Most research has been conducted on calves in the pre-weaning period by supplementation of butyric acid to formula or solid feeds. The effect of adding butyric acid to MR on starter consumption has been contradictory (Niwińska et al., Reference Niwińska, Hanczakowska, Arciszewski and Klebaniuk2017). In agreement with previous studies (Hill et al., Reference Hill, Aldrich, Schlotterbeck and Bateman2007; Gorka et al., Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak, Holst, Guilloteau and Zabielski2011a, Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak and Zabielski2011b; Kato et al., Reference Kato, Sato, Chida, Roh, Ohwada, Sato, Guilloteau and Kazuo2011; Davarmanesh et al., Reference Davarmanesh, Fathi Nasiri, Kalantari Firouzabad and Montazer-Torbati2015; Frieten et al., Reference Frieten, Gerbert, Koch, Dusel, Eder, Kanitz, Weitzel and Hammon2017, Reference Frieten, Gerbert, Koch, Dusel, Eder, Hoeflich, Mielenz and Hammon2018; Roh et al., Reference Roh, Kimura, Sakamoto, Nishihara, Suzuki and Katoh2018; Ghaffari et al., Reference Ghaffari, Hammon, Frieten, Gerbert, Georg Dusel and Koch2021), the addition of SB to WM and MR did not affect DMI and starter intake. Starter consumption is very critical in young calves because it determines their growth and health after weaning (Greenwood et al., Reference Greenwood, Morrill, Titgemeyer and Kennedy1997). Despite the positive effect of butyric acid in MR on weight gain, Hill et al. (Reference Hill, Aldrich, Schlotterbeck and Bateman2007) found no effect on starter intake, probably because the composition of MR was changed by the addition of butyric acid and the share of whey in replacer powder was reduced. In addition, some studies observed a reduction in starter intake when SB was supplemented with acidified milk and MR (Wanat et al., Reference Wanat, Górka and Kowalski2015; Sun et al., Reference Sun, Li, Meng, Wu and Xu2019). In contrast with the current results, Mahjoubi et al. (Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020) observed starter intake improvement when SB was supplemented in WM, that this may be using unprotected SB in that study.

The addition of SB to the MR had an impact on small intestine and the growth and function of the pancreas (Gorka et al., Reference Gorka, Kowalski, Zabielski and Guilloteau2018); this phenomenon increases the cell division and decreases the cell death index in the jejunum epithelium (Guilloteau et al., Reference Guilloteau, Zabielski, David, Blum, Morisset, Biernat, Wolinski, Laubitz, Rome and Hamon2009b; Gorka et al., Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak and Zabielski2011b). In contrast to the current results, the addition of butyric acid to MR or the starter feed has improved (Hill et al., Reference Hill, Aldrich, Schlotterbeck and Bateman2007; Guilloteau et al., Reference Guilloteau, Zabielski, David, Blum, Morisset, Biernat, Wolinski, Laubitz, Rome and Hamon2009b; Gorka et al., Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak and Zabielski2011b, Reference Gorka, Kowalski, Pietrzak, Kotunia, Kiljanczyk, Flaga, Holst, Guilloteau and Zabielski2009; Nazari et al., Reference Nazari, Karkoodi and Alizadeh2012; Liu et al., Reference Liu, La Teng Zhu La, Evans, Gao, Yu, Bu and Ma2021; Wu et al., Reference Wu, Meng, Wang, Wang, Xu, Xiao and Xu2022) or decreased (Wanat et al., Reference Wanat, Górka and Kowalski2015; Ghaffari et al., Reference Ghaffari, Hammon, Frieten, Gerbert, Georg Dusel and Koch2021) calf growth performance. In addition, SB supplementation in WM and acidified milk improved ADG in dairy calves (Sun et al., Reference Sun, Li, Meng, Wu and Xu2019; Mahjoubi et al., Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020). However, some other researchers have not been observed any effect of inclusion butyric acid in diet on calf performance (Kato et al., Reference Kato, Sato, Chida, Roh, Ohwada, Sato, Guilloteau and Kazuo2011; Araujo et al., Reference Araujo, Terré, Mereu, Ipharraguerre and Bach2015; Davarmanesh et al., Reference Davarmanesh, Fathi Nasiri, Kalantari Firouzabad and Montazer-Torbati2015; Frieten et al., Reference Frieten, Gerbert, Koch, Dusel, Eder, Kanitz, Weitzel and Hammon2017, Reference Frieten, Gerbert, Koch, Dusel, Eder, Hoeflich, Mielenz and Hammon2018; Roh et al., Reference Roh, Kimura, Sakamoto, Nishihara, Suzuki and Katoh2018), which is in line with our results. Some of these differences are due to the type of supplemented butyric acid salt, and others are due to the age of the calf when butyric acid was included in the diet. For instance, Guilloteau et al. (Reference Guilloteau, Martin, Eeckhaut, Ducatelle, Zabielski and Van Immerseel2010a) observed no significant effect when butyric acid was fed to calves from day 12 after birth. Furthermore, studies show that the greatest effect of butyric acid is in the first week after birth (e.g. Niwińska et al., Reference Niwińska, Hanczakowska, Arciszewski and Klebaniuk2017), which is in contrast to the current study.

Feed efficiency did not show any difference among treatments in the current study. This achievement is in agreement with some studies (Kato et al., Reference Kato, Sato, Chida, Roh, Ohwada, Sato, Guilloteau and Kazuo2011; Serbester et al., Reference Serbester, Çakmakçi, Göncü and Görgülü2014; Wanat et al., Reference Wanat, Górka and Kowalski2015; Roh et al., Reference Roh, Kimura, Sakamoto, Nishihara, Suzuki and Katoh2018; Ghaffari et al., Reference Ghaffari, Hammon, Frieten, Gerbert, Georg Dusel and Koch2021) and in conflict with others (Hill et al., Reference Hill, Aldrich, Schlotterbeck and Bateman2007; Guilloteau et al., Reference Guilloteau, Savary, Jaguelin-Peyrault, Rome, Le Normand and Zabielski2010b; Nazari et al., Reference Nazari, Karkoodi and Alizadeh2012; Davarmanesh et al., Reference Davarmanesh, Fathi Nasiri, Kalantari Firouzabad and Montazer-Torbati2015; Liu et al., Reference Liu, La Teng Zhu La, Evans, Gao, Yu, Bu and Ma2021). These discrepancies may be due to the type of used salt (calcium v. sodium) as well as how it was consumed; for instance, Davarmanesh et al. (Reference Davarmanesh, Fathi Nasiri, Kalantari Firouzabad and Montazer-Torbati2015) used calcium salt which was added to the MR until day 21 and then was included in the starter feed. Furthermore, it seems that the dosage plays a role in this regard; 3% of MR DM was evaluated in the study of Hill et al. (Reference Hill, Aldrich, Schlotterbeck and Bateman2007), while Kato et al. (Reference Kato, Sato, Chida, Roh, Ohwada, Sato, Guilloteau and Kazuo2011) used an incremental dose of 3–7 g of SB.

More recently, Wu et al. (Reference Wu, Meng, Wang, Wang, Xu, Xiao and Xu2022) reported that the addition of free SB to the starter feed was more effective than coated SB on performance and GIT development in the pre-weaning calves. The more efficient effects of free SB compared to the coated SB could be attributed to the different releasing sites in the GIT. Butyrate is metabolized by the ruminal epithelium primarily to beta-hydroxybutyric acid and is considered as an important energy source for the ruminal epithelial cells in the pre-weaning calves (Bergman, Reference Bergman1990; Wiese et al., Reference Wiese, Górka, Mutsvangwa, Okine and Penner2013). Furthermore, butyrate is considered to be the primary chemical promoter of rumen epithelium growth which reduces cell apoptosis (Mentschel et al., Reference Mentschel, Leiser, Mülling, Pfarrer and Claus2001) and accelerates cell cycle progression in the ruminal epithelium cells (Sakata and Tamate, Reference Sakata and Tamate1978; Malhi et al., Reference Malhi, Gui, Yao, Aschenbach, Gabel and Shen2013). More research is warranted to determine if there is any difference between protected and un-protected supplemented SB to the WM. Furthermore, it is notable that the results of adding protected SB to WM should be interpreted with caution in the current study because butyric acid was previously included to the WM as unprotected. On the other hand, butyric acid was added to the MR or the starter feed in earlier studies.

Health criteria

Contrary to the initial hypothesis of the current study, butyrate did not affect diarrhoea or loose faeces during the first month of life but it was in agreement with our previous study (Mahjoubi et al., Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020). On the other hand, lower faecal score and number of days with scours observed in our study are in line with previous studies which indicated that adding SB to MR and starter reduced diarrhoea and the number of days with scours (Hill et al., Reference Hill, Aldrich, Schlotterbeck and Bateman2007; Gorka et al., 2009, Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak and Zabielski2011b; Guilloteau et al., Reference Guilloteau, Zabielski and Blum2009a). Also, Sun et al. (Reference Sun, Li, Meng, Wu and Xu2019) indicated that the occurrence of diarrhoea reduced when butyric acid was added to the acidified milk. In addition, Hill et al. (Reference Hill, Aldrich, Schlotterbeck and Bateman2007) found no effect of SB on medical days and the number of used antibiotic drugs (Gorka et al., Reference Gorka, Kowalski, Pietrzak, Kotunia, Kiljanczyk, Flaga, Holst, Guilloteau and Zabielski2009, Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak, Holst, Guilloteau and Zabielski2011a, Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak and Zabielski2011b). Less intestinal development, as a result of MR feeding instead of WM, makes newborn calves more prone to diarrhoea (Blattler et al., Reference Blattler, Hammon, Morel, Philipona, Rauprich, Rome, Le Huerou-Luron, Guilloteau and Blum2001). Since WM was used in the current study, it seems that the amount of butyric acid in milk has partially led to the development of intestinal tissue thereby being able to handle diarrhoea. It has been shown that when butyric acid is added to MR, it improves colon function and can boost animal health (Guilloteau et al., Reference Guilloteau, Zabielski, David, Blum, Morisset, Biernat, Wolinski, Laubitz, Rome and Hamon2009b). Increased butyrate concentration in GIT by feeding molasses, it has been found that despite the increase in the concentration of butyric acid in the rumen, there was no effect on the faecal score (Oltramari et al., Reference Oltramari, Nápoles, De Paula, Silva, Gallo, Pasetti and Bittar2016). Consistent with the present study, Wanat et al. (Reference Wanat, Górka and Kowalski2015) also observed a linear effect with increasing butyric acid in the form of protected microcapsules on decreasing the faecal score. These results generally show that the effect of butyric acid addition to the starter depends on the level of supplementation and method of delivery which leads to obtaining contradictory results. In contrast with our expectation, although the addition of SB in the WM did not improve incidence of diarrhoea in the first month of life, it seems that the observed improvement in the faecal score thorough the study is due to the long-term and carry-over effects of SB during pre-weaning.

Blood chemical items

Glucose is considered the preferred energy substrate in pre-ruminant calves (Donkin and Armentano, Reference Donkin and Armentano1995). In agreement with previous studies (Ślusarczyk et al., Reference Ślusarczyk, Strzetelski and Furgał-Dierżuk2010; Roh et al., Reference Roh, Kimura, Sakamoto, Nishihara, Suzuki and Katoh2018; McCurdy et al., Reference McCurdy, Wilkins, Hiltz, Moreland, Klanderman and Laarman2019; Mahjoubi et al., Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020; Ghaffari et al., Reference Ghaffari, Hammon, Frieten, Gerbert, Georg Dusel and Koch2021) we did not observe any effect of SB on glucose concentration. However, Kato et al. (Reference Kato, Sato, Chida, Roh, Ohwada, Sato, Guilloteau and Kazuo2011) and Frieten et al. (Reference Frieten, Gerbert, Koch, Dusel, Eder, Kanitz, Weitzel and Hammon2017) showed that butyric acid has potential to increase tissue sensitivity to insulin and decreases blood glucose concentration. Gorka et al. (Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak, Holst, Guilloteau and Zabielski2011a) showed that calves fed WM had more glucose in their blood than calves fed MR; also, the addition of butyric acid caused a significant increase in glucose concentration (Gorka et al., Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak, Holst, Guilloteau and Zabielski2011a, Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak and Zabielski2011b; Nazari et al., Reference Nazari, Karkoodi and Alizadeh2012), which is contrary to the present study. Most likely, the reason for this variation is related to the length of the study or the amount of SB consumed. In the present study calves were weaned at day 74, while Gorka et al. (Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak, Holst, Guilloteau and Zabielski2011a, Reference Gorka, Kowalski, Pietrzak, Kotunia, Jagusiak and Zabielski2011b) slaughtered the experimental calves at 26 days of age.

The BHB concentration is an indicator of active rumen development in infant calves (Kristensen et al., Reference Kristensen, Sehested, Jensen and Vestergaard2007). Mahjoubi et al. (Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020) indicated an increase in BHB concentration when calves fed 4 or 8 g/day of SB were added to milk. This increase in BHB also indicates better ruminal function and development, so it affected the starter consumption of these groups. It was shown that BHB is produced by the rumen epithelium in well-fed ruminants (Pennington, Reference Pennington1952); accordingly, greater serum BHB indirectly indicates that SB leads to more extensive development in SB-fed calves. In agreement with the current results, previous studies (Ślusarczyk et al., Reference Ślusarczyk, Strzetelski and Furgał-Dierżuk2010; Davarmanesh et al., Reference Davarmanesh, Fathi Nasiri, Kalantari Firouzabad and Montazer-Torbati2015; Frieten et al., Reference Frieten, Gerbert, Koch, Dusel, Eder, Kanitz, Weitzel and Hammon2017; Ghaffari et al., Reference Ghaffari, Hammon, Frieten, Gerbert, Georg Dusel and Koch2021) reported no effect on BHB by adding butyric acid to milk substitute but not others (Nazari et al., Reference Nazari, Karkoodi and Alizadeh2012; Roh et al., Reference Roh, Kimura, Sakamoto, Nishihara, Suzuki and Katoh2018).

Post-weaning albumin and TP increased in SB-fed calves, which is in line with previous reports (Mahjoubi et al., Reference Mahjoubi, Armakan, Hossein Yazdi and Zahmatkesh2020). However, this observation is in contrast with prior studies in which SB feeding did not have impact on blood TP concentration (Sun et al., Reference Sun, Li, Meng, Wu and Xu2019; Ghaffari et al., Reference Ghaffari, Hammon, Frieten, Gerbert, Georg Dusel and Koch2021). Higher serum TP in calves fed SB also should be considered as a positive effect of SB supplementation, indicating greater accessibility of proteins for the developing organism. The response of albumin and TP to SB during the post-weaning period is probably because of the beneficial effect of butyric acid on intestine health (Gorka et al., Reference Gorka, Pietrzak, Kotunia, Zabielski and Kowalski2014) for the time of the transition period in which intestine permeability increases (Wood et al., Reference Wood, Palmer and Steele2015; Adab et al., Reference Adab, Mahjoubi and Hossein Yazdi2020) and it may negatively interfere with the nutrient absorption.

Conclusion

At least in the first weeks of a calf's life, most of the butyrate supplemented in a protected form is expected to bypass the forestomach and abomasum and be delivered to the small intestine, where it exerts a local effect on the intestinal epithelium. However, supplementation of WM with SB did not have a noticeable effect on the feed intake and growth performance of dairy calves during the pre- and post-weaning periods in the current study. However, faecal score and the number of days with loose faeces decreased as SB was added to milk within early weeks of life (SB-4-32) and entire period of experiment (SB-4-88) in the pre-weaning period, and throughout the study. Under the condition of this study, although the faecal score and some blood metabolites were affected, but contrary to our hypothesis, supplementation with encapsulated SB in WM could not significantly affect calf performance, medical days and health status when it was fed during the first month of life. Given that the previous studies used the unprotected form of butyrate in WM, further research is needed to indicate clear difference between effects of addition of free or encapsulated SB into WM.

Acknowledgements

The authors gratefully acknowledge Mr Ashrafinia and Dr Mirzaei (Arak University, Arak, Iran), and Dr Ghofrani (Javaneh Khorasan Company, Mashhad, Iran), and the staff of Avin Dasht Dairy Farm for their assistance in carrying out of the current experiment. We also appreciate Javaneh Khorasan Company (Iran) for providing us with 25 kg of Novyrate®C product.

Authors' contributions

All authors conceived and designed study. M. M. Eskandary conducted data gathering. M. Hossein Yazdi performed statistical analyses. M. Hossein Yazdi and E. Mahjoubi wrote the first draft of the manuscript. M. Kazemi-Bonchenari critically revised the paper. All authors have read and agreed to the published version of the manuscript.

Financial support

The current work was developed as part of the first author's thesis (grant no. 98-6994) that was financially supported by the deputy of research and technology at Arak University.

Conflict of interest

The authors declare there are no conflicts of interest.

Ethical standards

All experimental procedures were approved by the Ethics Committee on Animal Science at Arak University (IACUC no. IR2018011) and, in compliance with those norms, the animals did not suffer during the experimental procedures.

References

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Figure 0

Fig. 1. Schematic diagram represents the amounts of milk consumed (kg/day) by calves; 5 litres of milk/day from 4 to 16 days, 7 litres/day from 17 to 59 days, 6 litres/day from 60 to 63 days, 5 litres/day from 64 to 66 days, 4 litres/day from 67 to 69 days and 2 litres/day from 70 to 74 days of age.

Figure 1

Table 1. Starter diet ingredients and chemical composition

Figure 2

Fig. 2. ADG of calves supplemented with SB to WM. (♦) Control (CON) without microencapsulated SB supplementation; (■) with 4 g/day SB added to milk since days 4–32 (SB-4-32); (▴) with 4 g/day SB added to milk since days 61–74 and added to starter since days 75–88 (SB-61-88) and (×) with 4 g/day SB added to milk (since days 4–74) and the starter (since days 75–88) for the total experiment (SB-4-88).

Figure 3

Table 2. Effects of SB supplementation to WM on feed intake of Holstein calves (n = 12 calves per treatment)

Figure 4

Table 3. Effects of SB supplementation to WM on growth performance of Holstein calves (n = 12 calves per treatment)

Figure 5

Table 4. Effects of SB supplementation to WM on structural growth indices of Holstein calves (n = 12 calves per treatment)

Figure 6

Table 5. Mean values for health criteria and days experiencing a health criterion of Holstein calves supplemented with SB (n = 12 calves per treatment)

Figure 7

Table 6. Effects of SB supplementation to WM on serum metabolites of Holstein calves (n = 12 calves per treatment)