Consequences of the heat stress in forage production and animal husbandry and ways to solve them (review)

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In the agro-industrial complex, in the conditions of an increasing number of extremely high summer droughts, there is an objective need for structurally significant changes in the feed production feedstock conveyor by introducing non-traditional drought-resistant forage crops - Sudan grass, sorghum and sorghum-Sudan hybrids, as well as forage crops with a short growing season for an uninterrupted supply of livestock with feed. Under heat stress, it is important to use properly selected high-quality feed and special feed additives that reduce the production of metabolic heat in the body, as well as to adjust feeding regimes, monitor the level of the temperature-humidity index, the indicators of which will allow a timely assessment of the need for cooling of animals. The article presents overview information on the state of forage production and livestock farming in conditions of extremely high temperatures. The papers of Russian and foreign authors on various practical strategies for mitigating the effects of heat stress in the maintenance and feeding of cows, which may be useful to specialists in the field of dairy farming, were reviewed.

Sobre autores

Shamil Shakirov

Federal State Budgetary Scientific Institution Ufa Federal Research Centre of the Russian Academy of Sciences; Federal State Budgetary Scientific Institution "Federal Research Center "Kazan Research Center of the Russian Academy of Sciences"

Autor responsável pela correspondência
Email: intechkorm@mail.ru
ORCID ID: 0000-0002-3362-0463

Experimental station "Ufimskaya", Tatar Research Institute of Agriculture, Dr. Sci. (Agriculture), Professor

Rússia, Ufa; Kazan

Natalia Safina

Federal State Budgetary Scientific Institution Ufa Federal Research Centre of the Russian Academy of Sciences

Email: natysafina@gmail.com
ORCID ID: 0000-0003-1184-3188

Experimental station "Ufimskaya", Cand. Sci. (Biology), Senior Researcher

Rússia, Ufa

Albina Aminova

Federal State Budgetary Scientific Institution Ufa Federal Research Centre of the Russian Academy of Sciences

Email: albina_ufa@list.ru
ORCID ID: 0000-0003-2738-4692

Experimental station "Ufimskaya", Dr. Sci. (Biology), Leading Researcher

Rússia, Ufa

Irek Mustafin

Federal State Budgetary Scientific Institution Ufa Federal Research Centre of the Russian Academy of Sciences

Email: oph_ufimskoе@mail.ru
ORCID ID: 0009-0001-5532-450X

Experimental station "Ufimskaya", Cand. Sci (Agriculture)

Rússia, Ufa

Vakil Shiriev

Federal State Budgetary Scientific Institution Ufa Federal Research Centre of the Russian Academy of Sciences

Email: vakil2005@mail.ru
ORCID ID: 0009-0009-8223-0961

Experimental station "Ufimskaya", Dr. Sci. (Biology), Professor

Rússia, Ufa

Bibliografia

  1. Abilov A, Zhavoronkova N, Abilova S. Do not overheat your cows. Animal Husbandry of Russia. 2018;5:51-54.
  2. Levakhin GI, Miroshnikov IS, Ryazanov VA, Grechkina VV. Activity of digestive enzymes and the amount of digestive juices in calves fed diets containing protein of different quality. Izvestia Orenburg State Agrarian University. 2018;6(74):244-245.
  3. Shakirov ShK, Krupin EO, Shaitanov OL, et al. Analysis of the state and planning of feed production in agricultural enterprises of the Republic of Tatarstan. Kazan: Publishing house "Logos Press";2022:84.
  4. Safina NYu, Fattakhova ZF, Gainutdinova ER, Shakirov ShK. Association of coenzyme Q9 (COQ9) gene polymorphism with indicators of reproductive qualities of Holstein cows. Russian Agricultural Science. 2023;3:59-62. doi: 10.31857/S2500262723030110
  5. Bokzonadi A. Eat stress. Monitoring the condition of dairy cows. Effective Animal Husbandry. 2021;3(169):98-101.
  6. Bolshakov AZ, Tselovalnikov IK, Semenova FK. Grain sorghum as a new feed resource for dairy and meat cattle in the conditions of planetary warming. Bulletin of the Belarusian State Agricultural Academy. 2023;2:109-113.
  7. Buryakov NP, Buryakova MA, Aleshin DE. Heat stress and feeding features of the dairy cattle. Russian Veterinary Journal. 2016;3:5-13.
  8. Lebedev SV, Kvan OV, Gubaidullina IZ, Gavrish IA, Grechkina VV, Momčilović B, Ryabov NI. Effect of chromium nanoparticles on digestive enzymes activity and morphological and biochemical parameters of calf blood. Animal Husbandry and Fodder Production. 2018a;101(4):136-142.
  9. Lebedev SV, Levakhin GI, Gubaidullina IZ, Markova IV, Sheyda EV. Effect of different protein sources in the ration on nutrients assimilation in the digestive tract of animals. Izvestia Orenburg State Agrarian University. 2018b;6(74):205-208.
  10. Lebedev SV, Gavrish IA, Kwan OV, Rusakova EA, Gubaidullina IZ. The effect of nanoparticles chromium and chromium picolinate on hematological parameters of blood in laboratory animals. Technologies of Living Systems. 2018с;15(4):56-61. doi: 10.18127/j20700997-201804-07
  11. Gubaidullina IZ, Gavrish IA, Markova IV, Mustafina AS. Effect of ultradispersed chrome particles of different dosage on the elemental status of broilers-chicks. Bulletin of Orenburg State Agrarian University. 2018;6(74):263-265.
  12. Voronov D, Senko A, Sutko S. Mechanism of development of thermal stress in cows: modern scientific data. Belarusian Agriculture. 2024;5(263):39-42.
  13. Galimova RG. Analysis of changes in temperature and humidity regime in the republic of Bashkortostan in recent period. Bulletin of Udmurt University. Series Biology. Earth Sciences. 2020;30(1):83-93. doi: 10.35634/2412-9518-2020-30-1-83-93
  14. Golovan VT, Yurin DA, Kucheryavenko AV. Methods and devices for protecting livestock from intense radiation in the south of Russia. Effective Animal Husbandry. 2017;4(134):60-63.
  15. Shaitanov OL, Nizamov RM, Shakirov ShK, Idiyatova RKh. Natural grass stands as a reserve for increasing the production and quality of feed: reference book. Kazan: Publishing house of the Academy of Sciences of the Republic of Tatarstan; 2023: 51 p.
  16. Mukhanina EN, Shakirov ShK, Safina NYu, Gainutdinova ER. Study of the negative effect of heat stress on dairy productivity of cows under different housing methods. International Bulletin оf Veterinary Medicine. 2024;4:509-517. doi: 10.52419/issn2072-2419.2023.3.267
  17. Kamalova RG, Kozlova AS, Firstov AO. Modern changes in agroclimatic resources in natural agricultural zones of the Republic of Bashkortostan during warm period. Bulletin of Udmurt University. Series Biology. Earth Sciences. 2023;33(4):434-444. doi: 10.35634/2412-9518-2023-33-4-434-444
  18. Karpach OE. Causes and prevention of heat stress in cows. Our agriculture. 2024;10(330):54-58.
  19. Karpach OE. Heat stress in cows: causes and prevention. Our agriculture. 2023;14(310):4-12.
  20. Krokhina VA, Ilyukhina LA, Khrenov AA. Combined feed, additives and premixes in feeding highly productive cows. New in Feeding Highly Productive Animals: collection of scientific papers. Moscow: Agropromizdat: 1989:65-73.
  21. Kudelich V. Heat stress and reproduction of dairy cattle: mitigation strategy. Belarusian Agriculture. 2024;5(265):32-35.
  22. Kuznetsov SG, Kalashnik VI. Effectivity of premix using in cow in-milk feeding. Zooteсhniya. 2002;2:14-18.
  23. Nurzhanov BS, Levakhin YuI, Ryazanov VA, Dzhulamanov EB, Poberukhin MM. Variety of different fat-containing drugs including micro- and nanoelements in animal feeding (review). Animal Husbandry and Fodder Production. 2019;102(1):149-163. doi: 10.33284/2658-3135-102-1-149
  24. Khairullin DD, еt al. Scientific and practical aspects of correction of vitamin and mineral nutrition of ruminants. Kazan: Kazan State Academy of Veterinary Medicine named after N.E. Bauman; 2020:172 р.
  25. Nurzhanov BS, Logachev KG, Duskaev GK. Efficiency of compound feeds with adjusted mineral nutrition according to various NRC and NASEM standards on milk productivity of cows. Animal Husbandry and Fodder Production. 2024;107(4):169-176. doi: 10.33284/2658-3135-107-4-169
  26. Kamirova AM, Sizova EA, Ivanishcheva AP, Shoshin DE, Yausheva EV. The organic mineral complex based on ultrafine silicon-containing particles as a microbiome modulator of gastrointestinal tract of cattle. Animal Husbandry and Fodder Production. 2024;107(2):13-26. doi: 10.33284/2658-3135-107-2-13
  27. Sheyda EV, Lebedev SV, Miroshnikov SA, Grechkina VV, Ryazanov VA. Assessment of influence of ultrafine particles of Cr2O3 on metabolic processes in the body of calves raised on protein diets. Animal Husbandry and Fodder Production. 2020;103(4):14-25. doi: 10.33284/2658-3135-103-4-14
  28. Wtory VF, Gordeev VV, Wtory SV, Lantsova EO. The cowsheds temperature-and-humidity conditions with graphic information modeling using assessment. Bulletin of the All-Russian Research Institute of Animal Husbandry Mechanization. 2016;4(24):67-72.
  29. Lebedev SV, Kvan OV, Sheyda EV, Markova IV, Gubaidullina IZ, Grechkina VV, Korolyov VL. Digestion of nutrients in different sections of the gastrointestinal tract depending on protein quality in the calf diet. Animal Husbandry and Fodder Production. 2018d;101(4):158-163.
  30. Piron O, Malinin I. How to live through thermal stress and not to lose milk. Animal Husbandry of Russia. 2015;6:48-50.
  31. Polkhovskaya N. Heat stress: impact on cow productivity. Combined feed. 2016;6:52-55.
  32. Rud EN, Kuzminova EV, Semenenko MP, et al. Heat stress problem in dairy farming. Veterinary Science of Kuban. 2020;3:10-11. doi: 10.33861/2071-8020-2020-3-10-11
  33. Kuzminova EV, Semenenko MP, Abramov AA, Rud NA, Rud EN. Heat stress problem in dairy farming. Veterinary Science of Kuban. 2020;3:10-11. doi: 10.33861/2071-8020-2020-3-10-11
  34. Shakirov ShK, Shajtanov OL, Sushencova MA, et al . Modern technologies in feed and animal production, problems and ways to solve them (500 questions and answers): reference book. 4th ed., revised and enlarged. Kazan: AN RT Publishing House; 2023: 426 p.
  35. Dronov AV, Dyachenko VV, Belchenko SA, Simonov VYu. Sorghum crops in the green and raw material conveyors of the regional forage production. Vestnik of the Bryansk State Agricultural Academy. 2016;2(54):52-58.
  36. Shakirov ShK, Shaitanov OL, Krupin EO, et al. Theory and practice of production and use of bulk feeds. 2nd ed., revised and enlarged. Kazan: FEN; 2021: 292 p.
  37. Warren H. Mitigating the Negative Consequences of Heat Stress in the Enterprise. International Dairy Topics. 2024; 3 (16): 7-9.
  38. Faber W, Akmaliev T, Guseva O. Mineral nutrition for ruminants. Animal Husbandry of Russia. 2020а;5:30-33.
  39. Faber W, Akmaliev TА, Guseva OА. Chromium for ruminants. Journal of Dairy and Beef Cattle Breeding. 2020b;4:42-45.
  40. Kuzminova EV, Rud EN, Semenenko MP, Chernykh OYu, Osepchuk DV, Abramov AA, Semenenko KA. Pharmacocorrection of heat stress in dairy cattle: method. recommendations. Krasnodar: Krasnodar Scientific Center for Animal Science and Veterinary Science; 2022: 47 p. doi: 10.48612/monograph-2022-4
  41. Stepanov DV, Gafforov AK, Mamaev AV, Rodina ND. Formation of animals adaptation to the environmental temperatures. Vestnik OrelGAU. 2015;1(52):51-60.
  42. Kharlamov AV, Frolov AN, Ilyin VV. The influence of feed additives containing organic Zn and Se on productive and hematological parameters of Black Spotted bulls on final fattening. Animal Husbandry and Fodder Production. 2024;107(3):79-88. doi: 10.33284/2658-3135-107-3-79
  43. Shaitanov OL, Tagirov MSh. Main trends of climate change in Tatarstan in the twentieth century. Kazan: Foliant; 2018: 63 p.
  44. Shoshina OV. Assessment of the elemental and biochemical composition of blood serum after inclusion of chromium picolinate in Kazakh White-Headed bulls’ diet. Animal Husbandry and Fodder Production. 2024;107(1):31-41. doi: 10.33284/2658-3135-107-1-31
  45. Dovydenkova MV, Kolodina EN, Nikanova DA, Logvinova TI, Artemyeva OA. Efficiency of using carotene-synthesizing yeast Rhodotorula spp. in the feeding of farm animals (review). Animal Husbandry and Fodder Production. 2024;107(2):149-169. doi: 10.33284/2658-3135-107-2-149
  46. Bernabucci U, Biffani S, Buggiotti L, Vitali A, Lacetera N, Nardone A. The effects of heat stress in Italian Holstein dairy cattle. Journal of Dairy Science. 2014;97(1):471-486. doi: 10.3168/jds.2013-6611
  47. Brown-Brandi TM. Understanding heat stress in beef cattle. Revista Brasileira de Zootecnia. 2018;47:e20160414. doi: 10.1590/rbz4720160414
  48. Efimova IO, Zagidullin LR, Khisamov RR, Akhmetov TM, Shaidullin RR, Tyulkin SV, Gilmanov KhKh. Assessment on milk productivity and milk quality in cattle with different genotypes by HSP70.1 gene. IOP Conference Series: Earth and Environmental Science. 2020;604:012016. doi: 10.1088/1755-1315/604/1/012016
  49. Hassan F, Nawaz A, Rehman MS, Ali MA, Dilshad SMR, Yang Ch. Prospects of HSP70 as a genetic marker for thermo-tolerance and immuno-modulation in animals under climate change scenario. Animal Nutrition. 2019;5(4):340-350. doi: 10.1016/j.aninu.2019.06.005
  50. Kasimanickam R, Kasimanickam V. Impact of heat stress on embryonic development during first 16 days of gestation in dairy cows. Scientific Reports. 2021;11:14839. doi: 10.1038/s41598-021-94278-2
  51. Lebedev S, Gavrish I, Rusakova E, Kvan O, Gubaidullina I. Influence of various chromium compounds on physiological, morpho-biochemical parameters, and digestive enzymes activity in Wistar rats. Trace Elements and Electrolytes. 2018;35(4):242-245. doi: 10.5414/TEX0155419
  52. Li G, Chen S, Chen J, Peng D, Gu X. Predicting rectal temperature and respiration rate responses in lactating dairy cows exposed to heat stress. J Dairy Sci. 2020;103:5466-5484. doi: 10.3168/jds.2019-16411
  53. Mariana E, Sumantri C, Astuti DA, Anggraeni A, Gunawan A. Association of HSP70 gene with milk yield and milk quality of Friesian Holstein in Indonesia. IOP Conf. Series: Earth and Environmental Science. 2020;425:012045. doi: 10.1088/1755-1315/425/1/012045
  54. Zimbelman RB, Collier RJ. Feeding strategies for high producing dairy cows during periods of elevated heat and humidity. Tri-State Dairy Nutrition Conference. 2011:111-126.

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Declaração de direitos autorais © Шакиров Ш.K., Сафина Н.Y., Аминова А.L., Мустафин И.G., Шириев В.M., 2025

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