An Investigation on Effectiveness of nanominerals on some ruminal fermentation parameters: A Meta-Analysis

Document Type : Research Paper

Authors

Assistant Professor, Department of Animal Sciences, Faculty of Agriculture and Animal Science, University of Torbat-e Jam, Torbat-e Jam, Iran.

Abstract

Nanotechnology brings new solution for improving ruminal fermentation. Meta-analysis study of the effect of nanoparticles on ruminal fermentation can help to better understand how to manipulate ruminal fermentation. After searching and selecting appropriate articles, data related to ruminal fermentation parameters were extracted. Meta-analyses were carried out using the Comprehensive Meta-Analysis package, version 3. The effect sizes of across studies were calculated with fixed and random effect models. Possible publication bias was evaluated with funnel plot and statistical tests. The results of meta-analysis showed that the administration of nanoparticles in the diet, has a positive effect on gas production, total VFAs concentration and apparent dry matter digestibility. Addition of nanoparticles in the diet decrease N-NH3 concentration. The values of I2 for GP and TVFAs indicated moderate and values of I2 for N-NH3 concentration and apparent dry matter digestibility effect size indicated high heterogeneity, respectively. Administration of nanoparticles can improve ruminal fermentation process due to its positive effects on microbial growth, fiber degradation, DM digestibility, TVFAs concentration, and reduce the ratio of acetate to propionate and methane production.

Keywords

References

Abd El-Galil, Etab R.I. and El-Bordeny, N.E.Y. (2018). Evaluation of nanocobalt particles addition in ruminant rations by in vitro gas production. Egyptian journal of nutrition and feeds. 21(1): 91-102.
Abd El-Hack, M., Alagawany, M., Farag, M., Arif, M., Emam, M., Dhama, K., Sarwar, M. and Sayab, M. (2017). Nutritional and pharmaceutical applications of nanotechnology: Trends and advances. International Journal of Pharmacology. 13: 340-350.
Abdollahi, M., Rezaei, J. and Fazaeli, H. (2019). Performance, rumen fermentation, blood minerals, leukocyte and antioxidant capacity of young Holstein calves receiving high-surface ZnO instead of common ZnO. Archives of animal nutrition. 74(3): 189-205.
Adegbeye, M.J., Elghandour, M.M., Barbabosa-Pliego, A., Monroy, J.C. and Mellado, M. (2019). Nanoparticles in equine nutrition: mechanism of action and application as feed additives. Journal of equine veterinary science. 78(1): 29-37.
Bunglavan, S.J., Garg, A.K., Dass R.S. and Shrivastava, S. (2014). Use of nanoparticles as feed additives to improve digestion and absorption in livestock. Livestock research international. 2(3): 36-47.
Buxton, D.R. and Redfearn, D.D. (1997). Plant limitations to fiber digestion and utilization. The journal of nutrition. 127(5): 814-818.
Chaji, M. and Monjezi, Y. (2016). Compare the effect of different levels of nano-selenium on digestion and fermentation parameters of rumen microorganisms of sheep and goat. Animal science researches. 27(4): 183-199.
Chen, J., Wang, W. and Wang, Z. (2011). Effect of nano-zinc oxide supplementation on rumen fermentation in vitro. China journal of animal nutrition. 23: 1415-1421.
Faixová, Z., Faix, S., Leng, L., Váczi1, P., Maková, Z. and Szabóová, R. (2007). Haematological, blood and rumen chemistry changes in lambs following supplemen- ˇ tation with Se-yeast. Acta veterinaria brunensis. 76: 3-8.
Fesseha, H., Degu, T. and Getachew, Y. (2020). Nanotechnology and its application in animal production: A review. Veterinary Medicine – Open Journal. 52: 43-50.
Gonzalez-Estrella, J., Sierra-Alvarez, R. and Field J.A. (2013). Toxicity assessment of inorganic nanoparticles to acetoclastic and hydrogenotrophic methanogenic activity in anaerobic granular sludge. Journal of hazardous materials. 260: 278-285.
Hosseini-Vardanjani, S.F., Rezaei, J., Karimi-Dehkordi, S. and Rouzbehan. Y. (2020). Effect of feeding nano-ZnO on performance, rumen fermentation, leukocytes, antioxidant capacity, blood serum enzymes and minerals of ewes. Small ruminant research. 191: 106170.
Huang, S., Wang, L., Liu, L., Hou, Y. and Li, L. (2015). Nanotechnology in agriculture, livestock, and aquaculture in China. A review. Agronomy for Sustainable Development. 35: 369-400.
Ibrahimi Khoram Abadi, E., Kazemi, M. and Heidari, S. (2021). Effect of Green Silver Nanoparticles Synthesized via Phlomis cancellata Bunge Extract on in vitro ruminal fermentation. Iranian Journal of animal science research. 13(4).
Ivan, M., Neill, L., Forster, R., Alimon, R., Rode, L.M. and Entz, T. (2000). Effects of Isotricha, Dasytricha, Entodinium, and total fauna on ruminal fermentation and duodenal flow in wethers fed different diets. Journal of diry science. 83(4): 776-787.
Jahanbin, R., Yazdanshenas, P., Rahimi, M., Hajarizadeh, A., Tvrda, E., Nazari, S.A., Mohammadi-Sangcheshmeh, A. and Ghanem, N. (2021). In vivo and in vitro evaluation of bull semen processed with zinc (zn) nanoparticles. Biological Trace Element Research. 199: 126-135.
Ma, D., Wang, J., Chen, T., Shi, C., Peng, S. and Yue, Z. (2015). Iron-Oxide-Promoted Anaerobic Process of the Aquatic Plant of Curly Leaf Pondweed. Energy and fuels. 29(7): 4356-4360.
McAllister, T.A. and Newbold, C.J. (2008). Redirecting rumen fermentation to reduce methanogenesis. Australian journal of experimental agriculture. 48(2): 7-13.
McSweeney, C., and Mackie, R. (2012). Micro-organisms and ruminant digestion: State of knowledge, trends and future prospects. Commission on Genetic Resources for Food and Agriculture, Food and Agriculture Organization of United Nations, Rome, Italy, Background study- 61.
Mihaliková, K., Gresaková, L., Boldizarová, K., Faix, S., Leng, L. and Kisidayová, S. (2005). The effects of organic selenium supplementation on the rumen ciliate population in sheep. Folia microbial: 50: 353-356.
Mortimer, M., Kasemets, K. and Kahru, A. (2010). Toxicity of ZnO and CuO nanoparticles to ciliated protozoa Tetrahymena thermophila. Toxicology. 269(2): 182-189.
Nagaraja, T. G., Newbold, C, J., VanNevel, C. J. and Demeyer, D. I. (1997). Manipulation of ruminal fermentation. In The rumen microbial ecosystem. Springer Netherlands. 523-632.
Naziroglu, M., Aksakal, M., Cay, M. and Celik, S. (1997). Effects of vitamin E and selenium on some rumen parameters in lambs. Acta veterinaria hungarica. 45: 447-456.
Osama, E., El-Sheikh Sawsan, M.A., Khairy, M.H. and Galal Azza, A.A. (2020). Nanoparticles and their Potential Applications in Veterinary Medicine. Journal of Advanced Veterinary Research. 10: 268-273.
Rajendran, R. (2013). Application of nano minerals in animal production system.Research. Journal of biotechnology, 8(3). 1-3.
Riazi, H., Rezaei, J. and Rouzbehan, Y. (2019). Effects of supplementary nano-ZnO on in vitro ruminal fermentation, methane release, antioxidants, and microbial biomass. turkish journal of veterinary and animal sciences. 43: 737-746.
Sai Ram Kumar, S. (2017). Green synthesis of nanoparticles using plant extracts and their effect on rumen fermentation in vitro. Thesis.
Shi, L., Xun, W., Yue, W., Zhang, C., Ren, Y., Liu, Q., Wang, Q. and Shi, L. (2011a). Effect of elemental nano-selenium on feed digestibility, rumen fermentation, and purine derivatives in sheep. Animal feed science and technology, 163(2): 136-142.
Shi L., Yang, R.J., Yue, W.B., Xun, W.J., Zhang, C.X., Ren, Y.S., Shi, L. and Lei, F.L. (2010). Effect of elemental nano-selenium on semen quality, glutathione peroxidase activity, and testis ultrastructure in male Boer goats. Animal reproduction science. 118(2): 248-254.
Van Soest, P. J. (1994). Nutritional ecology of the ruminant. Cornell University Press.
Vázquez-Armijo, J.F., Martinez-Tinajero, J.J., Lopez, D., Salem, A.Z.M. and Rojo, R. (2011). In vitro gas production and dry matter degradability of diets consumed by goats with or without copper and zinc supplementation. Biological trace element research. 144(1-3): 580-587.
Vesterinen, H.M., Sena, E.S., Egan, K.J., Hirst, T.C., Churolov, L. and Currie, G.L. (2014). Meta-analysis of data from animal studies: a practical guide. Journal of Neuroscience Methods. 221: 92-102.
Wang, C., Liu, Q., Yang, W.Z., Dong, Q., Yang, X.M., He, D.C., Zhang, P., Dong, K.H. and Huang, Y.X. (2009). Effects of selenium yeast on rumen fermentation, lactation performance and feed digestibilities in lactating dairy cows. Livestock science. 126: 239-244.
Xun, W., Shi, L., Yue, W., Zhang, C., Ren, Y. and Liu, Q. (2012). Effect of high-dose nano selenium and selenium–yeast on feed digestibility, rumen fermentation, and purine derivatives in sheep. Biological trace element research. 150(1-3): 130-136.
Yang, ZP. and Sun, L. P. (2006). Effects of nanometer ZnO on growth performance of early weaned piglets. Journal of shanxi agriculture science. 3: 0-24.
Zaboli, K.H. and Aliarabi, H. (2013). Effect of different levels of zinc oxide nano particles and zinc oxide on some ruminal parameters by in vitro and in vivo methods. Animal production research. 2(1): 1- 14.
Zhisheng, C.J. (2011). Effect of nano-zinc oxide supplementation on rumen fermentation in vitro. Chinese journal of animal nutrition. 8: 0-23.
Animal Sciences Journal
Volume 35, Issue 137
March 2023
Pages 59-73

Files

Share

How to cite

Statistics