The effect of giving sodium butyrate to Holstein calves on gr owth, rumen and blood parameters
Résumé
The aim of this study was to investigate the effects of sodium butyrate supplementation on growth performance, health, rumen, and blood parameters in Holstein calves during the suckling period. Forty-five calves were divided into three groups: one control group and two experimental groups, each consisting of 15 calves matched by birth weight and sex. All groups were provided with 500 grams of milk replacer feed per calf per day and ad libitum access to calf starter feed containing 10% chopped alfalfa hay throughout the experiment. In the Experimental Group I, coated sodium butyrate was added at a concentration of 0.3% to the calf starter feed. In Experimental Group II, 0.3% uncoated sodium butyrate was added to the milk replacer feed, and 0.3% coated sodium butyrate was added to the calf starter feed. The experiment lasted for 60 days. Calves were weighed on the 15th, 30th, 45th, and 60th days of the experiment to assess live weight gain. Sodium butyrate supplementation did not result in significant differences in dry matter intake, daily weight gain, or feed conversion ratio (P > 0.05). However, a significant difference was observed in the glucose levels of blood plasma obtained from samples collected on the 45th day (P = 0.018), while no differences were found on other days. No significant differences were observed in beta-hydroxybutyric acid, blood urea nitrogen, IGF-1, or total serum protein levels. Rumen fluid samples were collected on the 30th and 45th days of the experiment and analyzed for rumen pH and volatile fatty acids. The analyses showed no significant differences between the groups. In conclusion, this study demonstrated that sodium butyrate supplementation in different doses and forms did not significantly affect health or growth parameters in Holstein calves during the suckling period.
Article Details
- Comment citer
-
Oztas, E., & Turkmen, I. (2025). The effect of giving sodium butyrate to Holstein calves on gr owth, rumen and blood parameters. Journal of the Hellenic Veterinary Medical Society, 76(4), 9909–9918. https://doi.org/10.12681/jhvms.39892
- Numéro
- Vol. 76 No 4 (2025)
- Rubrique
- Research Articles
Ce travail est disponible sous licence Creative Commons Attribution - Pas d’Utilisation Commerciale 4.0 International.
Authors who publish with this journal agree to the following terms:
· Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution Non-Commercial License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
· Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g. post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
· Authors are permitted and encouraged to post their work online (preferably in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work.
Téléchargements
Les données relatives au téléchargement ne sont pas encore disponibles.
Références
Araujo, G., Yunta, C., Terre, M., Mereu, A., Ipharraguerreet, I., Bach,
A. (2015). Intestinal permeability and incidence of diarrhoea in
newborn calves. J Dairy Sci 98: 7309-7317. https:// doi. org/ 10.
/ jds. 2015- 9666
Baldwin, R.L., McLeod, K.R., Klotz, J.L., Heitmann, R.N. (2004). Rumen
development, intestinal growth and hepatic metabolism in the
pre-and postweaning ruminant. J Dairy Sci 87 (Suppl.):E55-E65.
https:// doi. org/ 10. 3168/ jds. s0022- 0302(04) 70061-2
Bedford, A., Gong, J. (2018). Implications of butyrate and its derivatives
for gut health and animal production. Anim Nutr 4:151–159 https://
doi. org/ 10. 1016/j. aninu. 2017. 08. 010
Casper, D.P., Hultquist, K.M., Acharya, I.P. (2021). Lactobacillus plantarum
GB LP-1 as a direct fed microbial for neonatal calves. J. Dairy
Sci. 104:5557–5568. https: / / doi .org/ 10 .1093/ jas/ skab235 .286.
Connor, E.E., Evock-Clover, C.M., Walker, M.P., Elsasser, T.H., Kahl,
S. ( 2015). Comparative Gut Physiology Symposium: comparative
physiology of glucagon like peptide-2: implications and applications
for production and health of ruminants. J Animal Sci 93, 492-502.
https: / / doi .org/ 10.2527/jas.2014-8785
Diao, Q., Zhang, R., Fu, T. (2019). Review of strategies to promote
rumen development in calves. Aniams 9:490. https:// doi. org/ 10.
/ ani90 80490
Davarmanesh, A.R., Fathi Nasri, M.H., Kalantari Firouzabad, A.R.,
Montazer-Torabi, M.B. (2015). Effect of Ca-butyrate and Oleobiotec
(a flavoring agent) supplemented starter on the per-formance
of Holstein dairy calves. J. Agric. Sci. 153, 1506-1513. https: / /
doi.org/10.1017/S0021859615000726
Eskandari, M.M., Hossein Yadi, M., Mahjoubi, E., Kazem-Bonchenari,
M. (2021). The effect of different feeding times of microencapsulated
sodium butyrate in whole milk and starter feed on growth
and health of Holstein dairy calves? J. Agric. Sci. 161(1), 117-127.
https: / / doi.org/10.21203/rs.3.rs-1117757/v1
Fellows, R., Denizot, J., Stellato, C., Cuomo, A., Jain, P., Stoyanova, E.,
Balázsi, S., Hajnády, Z., Liebert, A., Kazakevych, J., Blackburn, H.,
Corrêa, R.O., Fachi, J.L., Sato, F.T., Ribeiro, W.R., Ferreira, C.M.,
Perée, H., Spagnuolo, M., Mattiuz, R., Matolcsi, C., Varga-Weisz,
P. (2018). Microbiota derived short chain fatty acids promote histone
crotonylation in the colon through histone deacetylases. Nat
Commun 9:105. https:// doi. org/ 10. 1038/ s41467- 017- 02651-5
Ferreira LS, Bittar CMM (2011). Performance and plasma metabolites
of dairy calves fed starter containing sodium butyrate, calcium
propionate or sodium monensin. Animal (2011), 5:2, pp 239-245.
https:// doi. org/ 10.1017/S1751731110001965
Frieten, D.,C., Gerbert, C., Koch, G., Dusel, K. Eder, A. Hoeflich, B.,
Mielenz, A., Hammon, H.M. (2018). Influence of ad libitum milk
replacer feeding and butyrate supplementation on the systemic and
hepatic insulin-like growth factor I and its binding proteins in Holstein
calves. J. Dairy Sci. 101:1661–1672. https: / / doi .org/ 10
.3168/ jds .2017 -13603.
Gading, B.M., Agus, A., Irawan, A., Panjono, P. (2020). Growth performance,
hematological and mineral profile of pos-weaning calves
as influenced by inclusion of pelleted-concentrate supplement containing
essential oils and probiot-ics. Iranian J. Appl. Anim. Sci.
, 461-468.
Ghaffari, M.H., Hammon, H.M.,Frieten, D., Gerbert, C., Dusel, G.,
Koch, K. (2021). Effects of milk replacer meal size on feed intake,
growth performance, and blood metabolites and hormones
of calves fed milk replacer with or without butyrate ad libitum: A
clusteranalytic approach. J. Dairy Sci. 104:4650–4664. https://doi.
org/10.3168/jds.2020-18626
Gorka, P., Kowalski, ZM., Pietrzak, P.A., Kotunia, A., Kiljanczyk,
R., Flaga, J., Holst, J. J, Guilloteau, P., Zabielski, R.. (2009). Effect
of sodium butyrate supplementation in milk replacer and starter diet
on rumen development in calves. J Physiol Pharmacol 60, Suppl.
, 47-53. https:// doi. org/ 10. 1152/ jn. 00345. 2009
Gorka, P., Kowalski, Z.M., Pietrzak, P., Kotunia, A., Jagusiak, W., Holst
J.J., Guilloteau, P., Zabielski, R. (2011): Effect of method of delivery
of sodium butyrate on rumen development in newborn calves. J
Dairy Sci 94:5578-5588. https:// doi. org/ 10. 3168/ jds. 2011- 4166
Gorka, P., Pietrzak, P., Kotunia, A., Zabielski, R., Kowalski, Z.M.
(2014). Effect of method of delivery of sodium butyrate on maturation
of the small intestine in newborn calves. J Dairy Sci 97,1026-
https:// doi. org/ 10. 3168/ jds. 2013- 7251
Górka, P., Kowalski, Z.M., Zabielski, R., Guilloteau, P. (2018). Invited
review: Use of butyrate to promote gastrointestinal tract devel opment
in calves. J. Dairy Sci. 101:4785–4800. https: / / doi .org/
3168/ jds .2017 -14086.
Govil, K., Yadav, D.S., Patil, A.K., Nayak, S., Baghel, R.P.S, Yadav
P.K., Malapure, C.D., Thakur, D. (2017). Feeding management for
early rumen development in calves. Journal of Entomology and
Zoology Studies 5, 1132-1139.
Guilloteau, P., Zabielski, R. (2005). Digestive secretions in preruminant
and ruminant calves and some aspects of their regulation.
In Calf and Heifer Rearing,159-189. https://doi.org/10.22358/
jafs/70358/2005
Guilloteau, P., Romé, V., Le Normand L, Savary, G., Zabielski, R.
(2004). Is Na-butyrate a growth factor in the preruminant calf?
Preliminary results. J Anim Feed Sci 13:393–396. https:// doi. org/
1079/ 97808 51996 349. 0285
Guilloteau, P., Zabielski, R., David, J.C., Blum, J.W., Morisset,
J.A., Biernat, M., Wolinski, J., Laubitz, D., Hamon, Y. (2009).
Sodiumbutyrate as a growth promoter in milk replacer formula
for young calves. J Dairy Sci 92, 1038-1049. https:// doi. org/ 10.
/ jds. 2008- 1213
Guilloteau, P., Martin, L., Eeckhaut, V., Ducatelle, R., Zabielski, R.
Immerseel FV (2010). From the gut to the peripheral tissues: the
multiple effects of butyrate. Nutr Res Rev 23:366–384. https:// doi.
org/ 10. 1017/ S0954 42241 00002 47
Heinrichs, A.J., Jones, C.M., Vanroekel, L.R., Fowler, M.A. (2003).
Calf track: a system of dairy calf workforce management, training,
and evaluation and health evaluation. J Dairy Sci 86,115.
Kato, S., Sato, K., Chida, H., Roh, S.G., Ohwada, S., Sato, S., Guil-loteau,
P., Katoh, K. (2011). Effects of Na-butyrate supple-mentation
in milk formula on plasma concentrations of GH and insulin, and on
rumen papilla development in calves. J. Endocrinol. 211, 241-248.
Liu, L., Mao, D.S., Zhu, W. Liu, J. (2019). Infusion of sodium butyrate
promotes rumen papillae growth and enhances expression of genes
related to rumen epithelial VFA uptake and metabolism in neonatal
twin lambs. J. Anim. Sci. 97:909–921. https: / / doi .org/ 10 .1093/
jas/ sky459.
Liu, T., Hultquist, K., Froehlich, K., Casper, D.P. (2020). Feeding an
amino acid-formulated milk replacer for Holstein calves during 2
time periods. J. Dairy Sci. 103:10108–10121. https: / / doi .org/ 10
.3168/ jds .2020 -18529.
Liu, W., La, A.L.T.Z., Evans, A., Gao, S., Yu, Z., Bu, D., Ma, L. (2021).
Supplementation with sodium butyrate improves growth and antioxidant
function in dairy calves before wean-ing. J. Anim. Sci. Biotechnol.
, 2-11. https:// doi. org/ 10. 1186/ s40104- 020- 00521-7
Liu, H., Zhao, J., Zhang, W., Nie, C. (2023). Impacts of sodium butyrate
on intestinal mucosal barrier and intestinal microbial community in
a weaned piglet model. Front Microbiol 13:1041885. https:// doi.
org/ 10. 3389/ fmicb. 2022. 10418 85
Liu, T., Z. Luo, P., Cheng, Li, S.Zu, J. Casper, D.P. (2025). Growth
performance of neonatal Holstein heifers fed acidified waste milk
containing essential oil blend and encapsulated butyrate alone or
in combination. J. Dairy Sci. 108:1509–1526. https: / / doi .org/
.3168/jds .2024 -25333.
Lombard, J., Urie, N., Garry, F., Godden, S., Quigley, J., Earleywine,
T., McGuirk, S., Moore, D.,Branan, M., Chamorro, M., Smith,
G., Shivley, C., Catherman, D. Haines, D., Heinrichs, J., James,
R., Maas, J., Sterner, K. (2020). Consensus recommendations on
calf- and herd-level passive immunity in dairy calves in the United
States. J. Dairy Sci. 103:7611–7624. https: / / doi .org/ 10 .3168/
jds .2019 -17955.
Mahjoubi, E., Armakan, A., Hossein Yazdi, M., Zahmatkesh, D. (2020).
Effect of adding butyric acid to whole milk on growth performance
and blood parameters of Holstein calves in pre-weaning and
postweaning. Anim. Sci. J. 126, 17-30. https://doi.org/10.22092/
asj.2019.123406.1775
Malhi, M., Gui, H., Yao, L., Aschenbach, J.R., Gäbel, G., Shen, Z.
(2013). Increased papillae growth and enhanced short-chain fatty acid absorption in the rumen of goats are associated with transient
increases in cyclin D1 expression after ruminal butyrate infusion. J
Dairy Sci 96, 7603-7616. https:// doi. org/ 10. 3168/ jds.2013- 6700
Manzanilla, E.G., Nofrarias, M., Anguita, M., Castillo, M., Perez, J.F.,
Martin-Orue, S.M., Kamel, C. Gasa, J. (2006). Effects of butyrate,
avilamycin, and a plant extract combination on the intestinal equilibrium
of early-weaned pigs. J. Anim. Sci. 84, 2743-2745. https://
doi: 10.2527/jas.2005-509
Mirzababaei, M., Ghanbari, F., Bayat Kouhsar, J., Farivar, F. (2024).
The Effects of Oregano Essential Oil and Sodium Butyrate on the
Growth Performance, Blood and Rumen Fermentation Parameters
of Suckling Holstein Calves. Iranian Journal of Applied Animal
Science, 14(2),175-186. https :// sanad. iau. ir/ Journal/ ijas/ Article/
Niwińska, B., Hanczakowska, E., Arciszewski, M.B., Klebaniuk, R.
(2017). Review: Exogenous butyrate implications for the functional
development of ruminal epithelium and calf performance. Animal
:1522–1530. https://doi.org/10.1017/ S 1751731117000167.
Robbers, L., Jorritsma, R., Nielen, M., Koets, A. (2021). A scoping
review of on-farm colostrum management practices for optimal
transfer of immunity in dairy calves. Front. Vet. Sci. 8:668639.
https:/ / doi .org/ 10 .3389/ fvets .2021 .668639.
Shen, H., Xu, Z.,Shen, Z., Lu, Z. (2019). The regulation of ruminal
short-chain fatty acids on the functions of rumen barriers. Front.
Physiol. 10:1305. https: / / doi .org/ 10 .3389/ fphys .2019 .01305.
Soltani, M., Kazemi-Bonchenari, M., Khaltabadi-Farahani, A.H., Afsarian,
O. (2017). Interaction of forage provision (alfalfa hay) and
sodium butyrate supplementation on performance, structural growth,
blood metabolites and rumen fermentation characteristics of lambs
during pre-weaning period. Anim. Feed Sci. Technol. 230, 77-86.
Stefańska, B., Katzer, F., Golińska, B., Sobolewska, P., Smulski, S.,
Frankiewicz, A., Nowak, W. (2022). Different methods of eubiotic
feed additive provision affect the health, performance, fermentation,
and metabolic status of dairy calves during the preweaning
period. BMC Vet. Res. 18:138. https: / / doi .org/ 10 .1186/ s12917
-022 -03239-y.
Sun, Y.Y., Li, J., Meng, Q.S., Wu, D.L., Xu, M. (2019). Effects of butyric
acid supplementation of acidified milk on digestive function and
weaning stress of cattle calves. Livest. Sci. 225, 78-84. https://doi.
org/10.1016/j.livsci.2019.04.021
Vazquez-Mendoza, O., Elghandour, M.M.Y., Salem, A.Z.M., Cheng, L.,
Sun, X., Lisete Garcia-Flor, V., Pilego, A.B., Vazquez-Mendoza,
P., Anele, U. (2020). Effects of sodium butyrate and active Bacillus
amyloliquefaciens supplemented to pasteurized waste milk on
growth performance and health condition of Holstein dairy calves.
Anim. Biotechnol. 31, 209-216. https://doi.org/10.1080/10495398
.2019.1578785
Wanat, P., Gorka, P., Kowalski, Z.M. (2015). Short communication:
Effect of inclusion rate of microencapsulated sodium butyrate in
starter mixture for dairy calves. J Dairy Sci 98: 2682-2686. https://
doi.org/10.3168/jds.2014-8482
Wang, M.Y., Li, Y., Gao, M., Song, L.W., Xu, M., Zhao, X.L., Jia, Y.,
Zhao, M., Sun, Y.Y., Hu, H.L. (2021a). Effects of subacute ruminal
acidosis on colon epithelial morphological structure, permeability,
and expression of key tight junction proteins in dairy goats. J Dairy
Sci 104:4260–4270. https:// doi. org/ 10. 3168/ jds. 2020- 18738
Wang, Y., Wang, Y., Lin, X., Gou, Z., Fan, Q., Jiang, S. (2021b). Effects
of clostridium butyricum, sodium butyrate, and butyric acid
glycerides on the reproductive performance, egg quality, intestinal
health, and offspring performance of yellow-feathered breeder
hens. Front Microbiol 12:657542. https:// doi. org/ 10. 3389/ fmicb.
657542
Wenhui, L., Alateng. L., Evans, A., Gao, S., Yu, Z., Bu, D., Ma, L.
(2020). Supplementation with sodium butyrate improves rumen
fermentation, antioxidant capability, and immune function in dairy
calves before weaning. J Animal Sci 2,1-25. https://doi.org/10.1186/
s40104-020-00521-7
Wu, D.L., Meng, Q.S., Wang, Y.D., Wang, M.Y., Xu E.H., Xiao, L.,
Xu, M. (2022). Dietary supplementation of free or two fat-coated
sodium butyrate with varying release times on gastrointestinal development
and tight junctions in preweaned Holstein calves. Anim
Feed Sci Technol 285:115224. https:// doi. org/ 10. 1016/j. anife
edsci. 2022. 115224
Wu, D., Zhang, Z., Wang. X., Harmon, D.L., Jia, Y., Qi, J., Li, X., Jia,
H., Xu, M. (2024). Exploring the role of g protein expression in
sodium butyrate-enhanced pancreas development of dairy calves:
a proteomic perspective. J Agric Food Chem 72(11):5645–5658.
https:// doi. org/ 10. 1021/ acs. jafc. 3c084 05
Xiao, C., Zhang, L., Zhang, B., Kong, L., Pan, X., Goossens, T., Song,
Z. (2023). Dietary sodium butyrate improves female broiler breeder
performance and offspring immune function by enhancing maternal
intestinal barrier and microbiota. Poult Sci 102:102658. https://doi.
org/ 10. 1016/j. psj. 2023. 102658
Zou, X., Ji, J., Qu, H., Wang, J., Shu, D.M., Wang, Y., Liu, T.F., Li, Y.,
Luo, C.L. (2019). Effects of sodium butyrate on intestinal health
and gut microbiota composition during intestinal inflammation
progression in broilers. Poult Sci 98:4449–4456. https:// doi. org/
3382/ ps/ pez279
