A review of recent developments in essential oil-based alternatives in mastitis treatment in dairy cows

Abd El-Aziz N.K., Ammar A.M., El-Naenaeey E.-s.Y., El Damaty H.M., Elazazy A.A., Hefny A.A., Shaker A., Eldesoukey I.E. (2021). Antimicrobial and antibiofilm potentials of cinnamon oil and silver nanoparticles against Streptococcus agalactiae isolated from bovine mastitis: new avenues for countering resistance. BMC Vet. Res., 17: 1-14. Search in Google Scholar

Abd El-Hamid M.I., El-Tarabili R.M., Bahnass M.M., Alshahrani M.A., Saif A., Alwutayd K.M., Safhi F.A., Mansour A.T., Alblwi N.A.N., Ghoneim M.M. (2023). Partnering essential oils with antibiotics: Proven therapies against bovine Staphylococcus aureus mastitis. Front. Cell Infect. Microbiol., 13: 1265027. Search in Google Scholar

Abdel-Raheem S.M., Abd El-Hamid M.I., Ibrahim D., El-Malt R.M., El-Ghareeb W.R., Ismail H.A., Al-Sultan S.I., Meligy A.M., ELTarabili R.M. (2023). Future scope of plant-derived bioactive compounds in the management of methicillin-resistant Staphylococcus aureus: in vitro antimicrobial and antivirulence prospects to combat MRSA. Microb. Pathog., 183: 106301. Search in Google Scholar

Abed A.H., Hegazy E.F., Omar S.A., Abd El-Baky R.M., El-Beih A.A., Al-Emam A., Menshawy A.M., Khalifa E. (2021). Carvacrol essential oil: A natural antibiotic against zoonotic multidrug-resistant Staphylococcus species isolated from diseased livestock and humans. Antibiotics, 10: 1328. Search in Google Scholar

Adaszyńska-Skwirzyńska M., Szczerbińska D. (2017). Use of essential oils in broiler chicken production-a review. Ann. Anim. Sci., 17: 317. Search in Google Scholar

Aiemsaard J., Borlace G.N., Thongkham E., Jarassaeng C. (2023). Antibacterial efficacy of essential oil spray formulation for post-milking disinfection in dairy cows. Vet. World, 16: 1552. Search in Google Scholar

Aiemsaard J., Aiumlamai S., Aromdee C., Taweechaisupapong S., Khunkitti W. (2011). The effect of lemongrass oil and its major components on clinical isolate mastitis pathogens and their mechanisms of action on Staphylococcus aureus DMST 4745. Res. Vet. Sci., 91: e31-e37. Search in Google Scholar

Aiemsaard J., Aiumlamai S., Taweechaisupapong S., Aromdee C., Khunkitti W. (2010). Chemical composition, antioxidant activity and antibacterial action of eight essential oils against clinical isolates of mastitis pathogens. Int. J. Essen. Oil Ther., 4: 37-43. Search in Google Scholar

Albuquerque K.R.S., Purgato G.A., Píccolo M.S., Rodrigues F.F., Pizziolo V.R., Muñoz G.D., Rossi C.C., Diaz M.A.N. (2023). Formulations of essential oils obtained from plants traditionally used as condiments or traditional medicine active against Staphylococcus aureus isolated from dairy cows with mastitis. Lett. Appl. Microbiol., 76: ovad034. Search in Google Scholar

Andjelkovic J., Radonjic V. (2017). Usage of intramammary antimicrobial veterinary medicinal products in the republic of Serbia from 2011 to 2014. J. Exp. Clin. Res., 18: 27-32. Search in Google Scholar

Aouadhi C., Jouini A., Maaroufi K., Maaroufi A. (2024). Antibacterial Effect of Eight Essential Oils against Bacteria Implicated in Bovine Mastitis and Characterization of Primary Action Mode of Thymus capitatus Essential Oil. Antibiotics, 13: 237. Search in Google Scholar

Arbab S., Ullah H., Bano I., Li K., Ul Hassan I., Wang W., Qadeer A., Zhang J. (2022). Evaluation of in vitro antibacterial effect of essential oil and some herbal plant extract used against mastitis pathogens. Vet. Med. Sci., 8: 2655-2661. Search in Google Scholar

Aydin H. (2021). In vitro antibacterial efficiency of some herbal extracts and theirs blends against subclinical mastitis pathogens (S. aureus and E. coli). Prog. Nutr., 23. Search in Google Scholar

Bakkali F., Averbeck S., Averbeck D., Idaomar M. (2008). Biological effects of essential oils– a review. Food Chem. Toxicol., 46: 446-475. Search in Google Scholar

Barreiros Y., de Meneses A.C., Alves J.L.F., Mumbach G.D., Ferreira F.A., Machado, R.A.F., Bolzan A., de Araujo P.H.H. (2022). Xanthan gum-based film-forming suspension containing essential oils: Production and in vitro antimicrobial activity evaluation against mastitis-causing microorganisms. Lwt, 153: 112470. Search in Google Scholar

Baskaran S.A., Kazmer G., Hinckley L., Andrew S., Venkitanarayanan K. (2009). Antibacterial effect of plant-derived antimicrobials on major bacterial mastitis pathogens in vitro. J. Dairy Sci., 92: 1423-1429. Search in Google Scholar

Bassolé I.H.N., Juliani H.R. (2012). Essential oils in combination and their antimicrobial properties. Molecules, 17: 3989-4006. Search in Google Scholar

Benić M., Maćešić N., Cvetnić L., Habrun B., Cvetnić Ž., Turk R., Đuričić D., Lojkić M., Dobranić V., Valpotić H., Grizelj J., Gračner D., Grbavac J., Samardžija M. (2018). Bovine mastitis: a persistent and evolving problem requiring novel approaches for its control-a review. Vet. arhiv, 88: 535-57. Search in Google Scholar

Bent S. (2008). Herbal medicine in the United States: review of efficacy, safety, and regulation: grand rounds at University of California, San Francisco Medical Center. J. Gen. Intern. Med., 23: 854-859. Search in Google Scholar

Bošković M., Baltić M., Janjić J., Dokmanović M., Ivanović J., Marković T., Marković R. (2013). Antimikrobna aktivnost etarskih ulja na Salmonella spp. u mesu i proizvodima od mesa. Lek. sirov., 33:39-52. Search in Google Scholar

Budri P.E., Silva N.C., Bonsaglia E.C., Júnior A.F., Júnior J.A., Doyama J.T., Gonçalves J.L., Santos M.V.d., Fitzgerald-Hughes D., Rall V.L. (2015). Effect of essential oils of Syzygium aromaticum and Cinnamomum zeylanicum and their major components on biofilm production in Staphylococcus aureus strains isolated from milk of cows with mastitis. J. Dairy Sci., 98, 5899-5904. Search in Google Scholar

Buldain D., Gortari Castillo L., Buchamer A.V., Bandoni A., Marchetti L., Mestorino N. (2022). In vitro synergistic interaction between Melaleuca armillaris essential oil and erythromycin against Staphylococcus aureus isolated from dairy cows. Front. Vet. Sci., 9: 1005616. Search in Google Scholar

Buldain D., Gortari Castillo L., Marchetti L., Buchamer A., Honor Irala F., Islan G., Mestorino N. (2024). Antimicrobial activity of nanostructured lipid carriers loaded with Melaleuca armillaris essential oil against Staphylococcus aureus sensitive and resistant to methicillin. Front. nanotechnol., 6: 1476423. Search in Google Scholar

Buldain D., Gortari Castillo L., Marchetti M.L., Julca Lozano K., Bandoni A., Mestorino N. (2021). Modeling the growth and death of Staphylococcus aureus against Melaleuca armillaris essential oil at different pH conditions. Antibiotics, 10: 222. Search in Google Scholar

Burt S. (2004). Essential oils: their antibacterial properties and potential applications in foods—a review. Int. J. Food Microbiol. 94: 223-253. Search in Google Scholar

Caneschi A., Bardhi A., Barbarossa A., Zaghini A. (2023). Plant Essential Oils as a Tool in the Control of Bovine Mastitis: An Update. Molecules, 28: 3425. Search in Google Scholar

Cao G., Liu J., Liu H., Chen X., Yu N., Li X., Xu F. (2023). Integration of Network Pharmacology and Molecular Docking to Analyse the Mechanism of Action of Oregano Essential Oil in the Treatment of Bovine Mastitis. Vet. Sci., 10: 350. Search in Google Scholar

Cerioli M.F., Moliva M.V., Cariddi L.N., Reinoso E.B. (2018). Effect of the essential oil of Minthostachys verticillata (Griseb.) epling and limonene on biofilm production in pathogens causing bovine mastitis. Front. Vet. Sci., 5: 146. Search in Google Scholar

Chen X., Liu P., Luo X., Huang A., Wang G. (2024). Study on the antibacterial activity and mechanism of Cinnamaldehyde against Methicillin-resistant Staphylococcus aureus. Eur. Food Res. Technol., 250: 1069-1081. Search in Google Scholar

Cho B.W., Cha C.N., Lee S.M., Kim M.J., Park J.Y., Yoo C.Y., Son S.E., Kim S., Lee H.J. (2015). Therapeutic effect of oregano essential oil on subclinical bovine mastitis caused by Staphylococcus aureus and Escherichia coli. Korean J. Vet. Res., 55: 253-257. Search in Google Scholar

Choi J.Y., Damte D., Lee S.J., Kim J.C., Park S.C. (2012). Antimicrobial activity of lemongrass and oregano essential oil against standard antibiotic resistant Staphylococcus aureus and field isolates from chronic mastitis cow. Int. J. Phytomed., 4: 134. Search in Google Scholar

Chouhan S., Sharma K., Guleria S. (2017). Antimicrobial activity of some essential oils— present status and future perspectives. Medicines, 4: 58. Search in Google Scholar

Constable P.D., Hinchcliff K.W., Done S.H., Grünberg W. (2016). Veterinary medicine: a textbook of the diseases of cattle, horses, sheep, pigs and goats: Elsevier Health Sciences. Search in Google Scholar

Corona-Gómez L., Hernández-Andrade L., Mendoza-Elvira S., Ricardo-González D.I., Pérez-Gerardo M.D., Quintanar-Guerrero D. (2022a). Effect of the in vitro activity of a component derived from Thymus vulgaris essential oil and tilmicosin on different strains of Staphylococcus sp, Streptococcus sp and Escherichia coli isolated from bovine mastitis. J. Essent. Oil Res., 34: 270-277. Search in Google Scholar

Corona-Gómez L., Hernández-Andrade L., Mendoza-Elvira S., Suazo F.M., Ricardo-González D.I., Quintanar-Guerrero D. (2022b). In vitro antimicrobial effect of essential tea tree oil (Melaleuca alternifolia), thymol, and carvacrol on microorganisms isolated from cases of bovine clinical mastitis. Int. J. Vet. Sci. Med., 10: 72-79. Search in Google Scholar

Carrasco S. B. V., Curay R. R., Mazon-Velez D., Morales M. C., Moreira J. M., Bayas-Morejón F. (2024). Evaluation of the effectiveness of essential oil tea tree (Melaleuca alternifolia) against three bacterial genera isolated from bovine mastitis. J. Med. Pharm. Chem., 6: 968-980. Cui H., Zhang C., Li C., Lin L. (2019). Antibacterial mechanism of oregano essential oil. Ind. Crops Prod., 139: 111498. Search in Google Scholar

da Silva A.T., Rosa D.S., Tavares M.R.S., Souza R.d.F.S., Navarro D.M.d.A.F., de Aguiar J.C.R.d.O.F., da Silva M.V., da Costa M.M. (2024). Essential oils of Eugenia spp.(myrtaceae) show in vitro antibacterial activity against Staphylococcus aureus isolates from bovine mastitis. Braz. J. Microbiol., 55: 3081-3096. Search in Google Scholar

Dai Min D.M., Peng Cheng P.C., Wan Feng, W.F., Peng Fu P.F. (2012). Antibacterial activity and mechanism of Pogostemon cablin against bacteria from milk of dairy cows suffering with mastitis. J. Anim. Vet. Adv., 11: 3289-3297. Search in Google Scholar

Dal Pozzo M., Santurio D., Rossatto L., Vargas A., Alves S., Loreto E., Viegas J. (2011). Activity of essential oils from spices against Staphylococcus spp. isolated from bovine mastitis. Arq. Bras. Med. Vet. Zootec., 63: 1229-1232. Search in Google Scholar

Dal Pozzo M., Loreto É.S., Santurio D.F., Alves S.H., Rossatto L., de Vargas A.C., Viegas J., da Costa M.M. (2012). Antibacterial activity of essential oil of cinnamon and transcinnamaldehyde against Staphylococcus spp. isolated from clinical mastitis of cattle and goats. Acta Sci. Vet., 40: 1-5. Search in Google Scholar

de Jesus G.S., Micheletti A.C., Padilha R.G., de Souza de Paula J., Alves F.M., Leal C.R.B., Garcez F.R., Garcez W.S., Yoshida N.C. (2020). Antimicrobial potential of essential oils from cerrado plants against multidrug− resistant foodborne microorganisms. Molecules, 25: 3296. Search in Google Scholar

Diaz M., Rossi C., Ribon A., Silva D., Aguilar A., Munoz G. (2009). Chemical composition and biological activity of some essential oils from traditional medicinal plants against clinical isolates of Staphylococcus aureus from bovine mastitis. Int. J. Essent. Oil Ther., 3: 119-124. Search in Google Scholar

Diaz M.A., Rossi C.C., Mendonça V.R., Silva D.M., Ribon A.d.O., Aguilar A.P., Muñoz G.D. (2010). Screening of medicinal plants for antibacterial activities on Staphylococcus aureus strains isolated from bovine mastitis. Rev. Bras. Farmacogn., 20: 724-728. Search in Google Scholar

Ebani V.V., Mancianti F. (2020). Use of essential oils in veterinary medicine to combat bacterial and fungal infections. Vet. Sci., 7: 193. Search in Google Scholar

European Medicine Agency (2016). Assessment report on Thymus vulgaris L. or Thymus zygis L., herba and Primula veris L. or Primula elatior (L.) Hill, radix Committee on Herbal Medicinal Products (HMPC). Available online: https://www.ema.europa.eu/en/documents/herbal-monograph/final-community-herbal-monograph-thymus-vulgaris-l-and-thymus-zygis-l-herba-and-primula-veris-l-and-primulaelatior-l-hill-radix_en.pdf (assessed 1 November 2024) Search in Google Scholar

European Medicine Agency (2017). Guideline on the conduct of efficacy studies for intramammary products for use in cattle. Available online: https://www.ema.europa.eu/en/conduct-efficacy-studies-intramammary-products-use-cattle-scientific-guideline (assessed 1 November 2024) Search in Google Scholar

European Commission (2024). EU Action on Antimicrobial Resistance. Available online: https://health.ec.europa.eu/antimicrobial-resistance/eu-action-antimicrobial-resistance_en (assessed 15 December 2024) Search in Google Scholar

Faria M.J.M.d., Braga C.A.d.S.B., Paula J.R.d., André M.C.D.P.B., Vaz B.G., Carvalho T.C.d., Romão W., Costa H.B.d., Conceição E.C.d. (2017). Antimicrobial activity of Copaifera spp. against bacteria isolated from milk of cows with mastitis. Ciênc. Anim. Bras., 18: e39068. Search in Google Scholar

Fratini F., Casella S., Leonardi M., Pisseri F., Ebani V.V., Pistelli L., Pistelli L. (2014). Antibacterial activity of essential oils, their blends and mixtures of their main constituents against some strains supporting livestock mastitis. Fitoterapia, 96: 1-7. Search in Google Scholar

Gautam N., Mantha A.K., Mittal S. (2014). Essential oils and their constituents as anticancer agents: a mechanistic view. Biomed. Res. Int., 2014: 154106. Search in Google Scholar

Gruet P., Maincent P., Berthelot X., Kaltsatos V. (2001). Bovine mastitis and intramammary drug delivery: review and perspectives. Adv. Drug Deliv. Rev., 50: 245-259. Search in Google Scholar

Grzesiak B., Głowacka A., Krukowski H., Lisowski A., Lassa H., Sienkiewicz M. (2016). The in vitro efficacy of essential oils and antifungal drugs against Prototheca zopfii. Mycopathologia, 181: 609-615. Search in Google Scholar

Grzesiak B., Kołodziej B., Głowacka A., Krukowski H. (2018). The effect of some natural essential oils against bovine mastitis caused by Prototheca zopfii isolates in vitro. Mycopathologia, 183: 541-550. Search in Google Scholar

Guimarães N.M., Ferreira N.S., Menezes K.V., Neto C.S., Cunha G.M., Menini L., Resende J.A., Villanova J.C. (2024). Formulating an Innovative Emulsion Based on Poloxamer 407 Containing Oregano and Thyme Essential Oils as Alternatives for the Control of Mastitis Caused by Staphylococcus aureus. Processes, 12: 2640. Search in Google Scholar

Guo W., Qiu M., Pu Z., Long N., Yang M., Ren K., Ning, R., Zhang S., Peng F., Sun F. (2023). Geraniol-a potential alternative to antibiotics for bovine mastitis treatment without disturbing the host microbial community or causing drug residues and resistance. Front. Cell Infect. Microbiol., 13: 131. Search in Google Scholar

Hennessy S. (2006). Use of health care databases in pharmacoepidemiology. Basic Clin. Pharmacol. Toxicol., 98: 311-313. Search in Google Scholar

Hillerton J.E., Kliem K.E. (2002). Effective treatment of Streptococcus uberis clinical mastitis to minimize the use of antibiotics. J. Dairy Sci., 85: 1009-1014. Search in Google Scholar

Hogeveen H, Huijps K, Lam T. Economic aspects of mastitis: new developments. New Zealand veterinary journal. 2011;59(1):16-23. Search in Google Scholar

Hollenbach C.B., Bing R.S., Stedile R., da Silva Mello F.P., Schuch T.L., Rodrigues M.R.A., de Mello F.B., de Mello J.R.B. (2015). Reproductive toxicity assessment of Origanum vulgare essential oil on male Wistar rats. Acta Sci. Vet., 43: 1-7. Search in Google Scholar

Horky P., Skalickova S., Smerkova K., Skladanka J. (2019). Essential oils as a feed additives: Pharmacokinetics and potential toxicity in monogastric animals. Animals, 9: 352. Search in Google Scholar

Hyldgaard M., Mygind T., Meyer R.L. (2012). Essential oils in food preservation: mode of action, synergies, and interactions with food matrix components. Front. Microbiol., 3: 12. Search in Google Scholar

Kaseke T.B., Chikwambi Z., Gomo C., Mashingaidze A.B., Murungweni C. (2023). Antibacterial activity of medicinal plants on the management of mastitis in dairy cows: A systematic review. Vet. Med. Sci., 9: 2800-2819. Search in Google Scholar

Keyvan E., Tutun H. (2019). Effects of carvacrol on Staphylococcus aureus isolated from bulk tank milk. Med. Weter., 75: 238-241. Search in Google Scholar

Kovačević Z., Kladar N., Čabarkapa I., Radinović M., Maletić M., Erdeljan M., Božin B. (2021a). New perspective of Origanum vulgare L. and Satureja montana L. essential oils as bovine mastitis treatment alternatives. Antibiotics, 10: 1460. Search in Google Scholar

Kovačević Z., Radinović M., Čabarkapa I., Kladar N., Božin B. (2021b). Natural agents against bovine mastitis pathogens. Antibiotics, 10: 205. Search in Google Scholar

Kovačević Z., Mihajlović J., Mugoša S., Horvat O., Tomanić D., Kladar N., Samardžija M. (2022a). Pharmacoeconomic analysis of the different therapeutic approaches in control of bovine mastitis: Phytotherapy and antimicrobial treatment. Antibiotics, 12: 11. Search in Google Scholar

Kovačević Z., Tomanić D., Čabarkapa I., Šarić L., Stanojević J., Bijelić K., Galić I., Ružić Z., Erdeljan M., Kladar N. (2022b). Chemical Composition, Antimicrobial Activity, and Withdrawal Period of Essential Oil-Based Pharmaceutical Formulation in Bovine Mastitis Treatment. Int. J. Environ. Res. Public Health., 19: 16643. Search in Google Scholar

Kovačević Z., Samardžija M., Horvat O., Tomanić D., Radinović M., Bijelić K., Vukomanović A.G., Kladar N. (2022). Is there a relationship between antimicrobial use and antibiotic resistance of the most common mastitis pathogens in dairy cows?. Antibiotics, 12: 3. Search in Google Scholar

Ksouri S., Djebir S., Bentorki A., Gouri A., Hadef Y., Benakhla A. (2017). Antifungal activity of essential oils extract from Origanum floribundum Munby, Rosmarinus officinalis L. and Thymus ciliatus Desf. against Candida albicans isolated from bovine clinical mastitis. J. Mycol. Med., 27: 245-249. Search in Google Scholar

Lago A., Godden S., Bey R., Ruegg P., Leslie K. (2011). The selective treatment of clinical mastitis based on on-farm culture results: I. Effects on antibiotic use, milk withholding time, and short-term clinical and bacteriological outcomes. J. Dairy Sci., 94: 4441-4456. Search in Google Scholar

Langeveld W.T., Veldhuizen E.J., Burt S.A. (2014). Synergy between essential oil components and antibiotics: a review. Crit. Rev. Microbiol., 40: 76-94. Search in Google Scholar

Liang T., Huo G., Chen L., Ding L., Wu J., Zhang J., Wang R. (2023). Antibacterial activity and metabolomic analysis of linalool against bovine mastitis pathogen Streptococcus agalactiae. Life Sci., 313: 121299. Search in Google Scholar

Liang T., Wang X., Chen L., Ding L., Wu J., Zhang J., Wang R. (2024). Transcriptomic and metabolomic analyses reveal the antibacterial mechanism of Zanthoxylum bungeanum Maxim. Essential oil against GBS. Food Biosci., 57: 103528. Search in Google Scholar

Lopes T.S., Fontoura P.S., Oliveira A., Rizzo F.A., Silveira S., Streck A.F. (2020). Use of plant extracts and essential oils in the control of bovine mastitis. Res. Vet. Sci., 131: 186-193. Search in Google Scholar

Lopes T.S., Fussieger C., Theodoro H., Silveira S., Pauletti G.F., Ely M.R., Lunge V.R., Streck A.F. (2023). Antimicrobial activity of essential oils against Staphylococcus aureus and Staphylococcus chromogenes isolated from bovine mastitis. Braz. J. Microbiol., 54: 2427-2435. Search in Google Scholar

Mancini E., Senatore F., Del Monte D., De Martino L., Grulova D., Scognamiglio M., Snoussi M., De Feo V. (2015). Studies on chemical composition, antimicrobial and antioxidant activities of five Thymus vulgaris L. essential oils. Molecules, 20: 12016-12028. Search in Google Scholar

Marcelo N.A., Andrade V.A., Souza C.N., Mourão R.P., Mourthe M.H.F., Silva L.M.V., de Oliveira Xavier A.R.E., de Sousa Xavier M.A., Faraco A.A.G., Almeida A.C. (2020). Efficacy of novel antiseptic product containing essential oil of Lippia origanoides to reduce intramammary infections in cows. Vet. World, 13: 2452. Search in Google Scholar

Mariotti M., Lombardini G., Rizzo S., Scarafile D., Modesto M., Truzzi E., Benvenuti S., Elmi A., Bertocchi M., Fiorentini L. (2022). Potential applications of essential oils for environmental sanitization and antimicrobial treatment of intensive livestock infections. Microorganisms, 10: 822. Search in Google Scholar

Moliva M.V., Cariddi L.N., Pereyra E.R., Raviolo J.M., Sambuceti N., Posadaz A., Campra N.A., Reinoso E.B. (2023). Evaluation of antibacterial and antibiofilm properties of Minthostachys verticillata essential oils against bovine Staphylococcus aureus strains. Biocatal. Agric. Biotechnol., 50: 102697. Search in Google Scholar

Montironi I.D., Cariddi L.N., Reinoso E.B. (2016). Evaluation of the antimicrobial efficacy of Minthostachys verticillata essential oil and limonene against Streptococcus uberis strains isolated from bovine mastitis. Rev. Argent. Microbiol., 48: 210-216. Search in Google Scholar

Mullen K., Lee A., Lyman R., Mason S., Washburn S., Anderson K. (2014). An in vitro assessment of the antibacterial activity of plant-derived oils. J. Dairy Sci., 97: 5587-5591. Search in Google Scholar

Munive Nuñez K.V., Abreu A.C.d.S., Almeida J.M.d., Gonçalves J.L., Bonsaglia É.C.R., dos Santos M.V., Silva N.C.C. (2024). Antimicrobial Activity of Selected Essential Oils against Staphylococcus aureus from Bovine Mastitis. Dairy, 5: 54-65. Search in Google Scholar

Nardoni S., Pisseri F., Pistelli L., Najar B., Luini M., Mancianti F. (2018). In vitro activity of 30 essential oils against bovine clinical isolates of Prototheca zopfii and Prototheca blaschkeae. Vet. Sci., 5: 45. Search in Google Scholar

Neculai-Valeanu A.S., Ariton A.M., Mădescu B.M., Rîmbu C.M., Creangă Ş. (2021). Nanomaterials and essential oils as candidates for developing novel treatment options for bovine mastitis. Animals, 11: 1625. Search in Google Scholar

Nojo H., Ishijima S.A., Morikawa M., Ito T., Kano R. (2024). In vitro susceptibility testing of phytochemicals from essential oils against Prototheca species. J. Vet. Med. Sci., 86: 847-849. Search in Google Scholar

Noori S., Rahchamani R., Bayat Kohsar J., Bahri Binabaj F. (2019). Antibacterial eff ect of Lavandula stoechas and Origanum majorana essential oils against Staphylococcus aureus, Streptococcus agalactiae, and Escherichia coli. Iran. J. Vet. Sci. Technol., 11: 35-41. Search in Google Scholar

Oliveira L., Ruegg P. (2014). Treatments of clinical mastitis occurring in cows on 51 large dairy herds in Wisconsin. J. Dairy Sci., 97: 5426-5436. Search in Google Scholar

Oliver J.P., Gooch C.A., Lansing S., Schueler J., Hurst J.J., Sassoubre L., Crossette E.M., Aga D.S. (2020). Invited review: Fate of antibiotic residues, antibiotic-resistant bacteria, and antibiotic resistance genes in US dairy manure management systems. J. Dairy Sci., 103: 1051-1071. Search in Google Scholar

Omonijo F.A., Ni L., Gong J., Wang Q., Lahaye L., Yang C. (2018). Essential oils as alternatives to antibiotics in swine production. Anim. Nutr., 4: 126-136. Search in Google Scholar

O’Neill L.J. (2021). What Is the Right Way to Structure Global Health? The Case for Radical New Organisations and Thinking. In Consensus or Conflict? China and Globalization in the 21st Century. Singapore: Springer Nature Singapore, pp. 151-159. Search in Google Scholar

Oztuna A. (2025). Effectiveness analysis of antimicrobial use in veterinary medicine: Balancing economic and public health considerations. Journal of Ekonomi, 7: 52-59. Search in Google Scholar

Paiano R.B., de Sousa R.L., Bonilla J., Moreno L.Z., de Souza E.D., Baruselli P.S., Moreno A.M. (2023). In vitro effects of cinnamon, oregano, and thyme essential oils against Escherichia coli and Trueperella pyogenes isolated from dairy cows with clinical endometritis. Theriogenology, 196: 106-111. Search in Google Scholar

Pașca C., Mărghitaș L., Dezmirean D., Bobiș O., Bonta V., Chirilă F., Matei I., Fiț N. (2017). Medicinal plants based products tested on pathogens isolated from mastitis milk. Molecules, 22: 1473. Search in Google Scholar

Pașca C., Mărghitaș L.A., Dezmirean D.S., Matei I.A., Bonta V., Pașca I., Chirilă F., Cîmpean A., Fiț N.I. (2020). Efficacy of natural formulations in bovine mastitis pathology: Alternative solution to antibiotic treatment. J. Vet. Res., 64: 523-529. Search in Google Scholar

Petrović S., Kukić-Marković J., Pavlović-Drobac M. (2012). Biljni lekoviti proizvodi: uslovi za bezbednu primenu. Arh. Farm., 62: 119-135. Search in Google Scholar

Pinedo P., Karreman H., Bothe H., Velez J., Risco C. (2013). Efficacy of a botanical preparation for the intramammary treatment of clinical mastitis on an organic dairy farm. Can. Vet. J., 54: 479. Search in Google Scholar

Pyörälä S. (2009). Treatment of mastitis during lactation. Ir. Vet. J., 62: 1-5. Search in Google Scholar

Rahchamani R., Bayat Kouhsar J., Noori S. (2023). The antimicrobial activity of peppermint (Mentha piperita) and pennyroyal (Mentha pulegium) essential oil on three mastitis-causing pathogens in milk. Iran. J. Vet. Sci. Technol., 15: 29-36. Search in Google Scholar

Raheel I.A., Hassan W.H., Salam H.S., Abed A.H., Salem S.S. (2023). Antifungal Effect of Some Natural Substances on Fluconazole-resistant Candida species Recovered from Mastitis. J. Adv. Vet. Res., 13: 1583-1587. Search in Google Scholar

Radinović M., Kovačević Z., Davidov I., Stanojević J. (2021). Mastitisi krava-etiologija, faktori rizika i mere kontrole. Annals of Agronomy, 45: 113-118 Search in Google Scholar

Rani S., Verma S., Singh H., Ram C. (2022). Antibacterial activity and mechanism of essential oils in combination with medium‐chain fatty acids against predominant bovine mastitis pathogens. Lett. Appl. Microbiol., 74: 959-969. Search in Google Scholar

Ratajac R. (2013). Procena antimikrobnog i citotoksičnog potencijala etarskih ulja na endometrijum krava u uslovima in vitro. Doktorska disertacija, Univerzitet u Novom Sadu. Search in Google Scholar

Rogožarski D., Dimitrijević G., Dobrosavljević I. (2011). Participation of diagnosed mastitits in cows in milk hygiene of Branicevo district in 2002. Arch. Vet. Med., 4: 65-71. Search in Google Scholar

Rollin E., Dhuyvetter K., Overton M. (2015). The cost of clinical mastitis in the first 30 days of lactation: An economic modeling tool. Prev. Vet. Med., 122: 257-264. Search in Google Scholar

Ruegg P.L. (2013). Antibiotic treatments for bovine mastitis: Who, what, when, how and why?, American Association of Bovine Practitioners Conference Proceedings, pp. 72-78. Search in Google Scholar

Sharifi A., Mohammadzadeh A., Salehi T.Z., Mahmoodi P., Nourian A. (2021). Cuminum cyminum L. essential oil: A promising antibacterial and antivirulence agent against multidrug-resistant Staphylococcus aureus. Front. Microbiol., 12: 667833. Search in Google Scholar

Sharun K., Dhama K., Tiwari R., Gugjoo M.B., Iqbal Yatoo M., Patel S.K., Pathak M., Karthik K., Khurana S.K., Singh R. (2021). Advances in therapeutic and managemental approaches of bovine mastitis: a comprehensive review. Vet. Q., 41: 107-136. Search in Google Scholar

Sivamaruthi B.S., Kesika P., Daungchana N., Sisubalan N., Chaiyasut C. (2024). Composition, bioactivities, microbiome, safety concerns, and impact of essential oils on the health status of domestic animals. Appl. Sci., 14: 6882. Search in Google Scholar

Smith R., Cohen S.M., Doull J., Feron V., Goodman J., Marnett L., Portoghese P., Waddell W., Wagner B., Hall R. (2005). A procedure for the safety evaluation of natural flavor complexes used as ingredients in food: essential oils. Food Chem. Toxicol., 43: 345-363. Search in Google Scholar

Song Z., Sun H., Yang Y., Jing H., Yang L., Tong Y., Wei C., Wang Z., Zou Q., Zeng H. (2016). Enhanced efficacy and anti-biofilm activity of novel nanoemulsions against skin burn wound multi-drug resistant MRSA infections. Nanomedicine, 12: 1543-1555. Search in Google Scholar

Suarez-Barreiro J.M., Suarez M.C., Calvo M.A., Parada F., Cortés F., Tobón F., Toro S. (2024). Screening of essential oils against oxacillin-resistant Staphylococcus aureus strains isolated from bovine mastitis. Bol. Latinoam. Caribe Plantas Med. Aromat., 23: 401-409. Search in Google Scholar

Sungkatavat P., Khongkhai H., Kanchana W., Saengsawarng P., Sangkanu S., Nissapatorn V., de Lourdes Pereira M., Ontong J.C., Mitsuwan W. (2023). Piper betle extract and its application in bovine teat dipping solution inhibit and eliminate biofilms in bovine mastitis-inducing staphylococci. Vet. World, 16: 2135. Search in Google Scholar

Suthovski G., Catarina A.S., Perin D.P., Mainardes R.M., Starikoff K.R., Gallina A.L., Azevedo M.G.B., Dalmolin F., Cervo L.V., Benvegnú D.M. (2023). Effect of polycaprolactone nanocapsules loaded with essential oils on biofilm formation by Staphylococcus aureus strains isolated from bovine mastitis cases. Braz. J. Pharm. Sci., 59: e23068. Search in Google Scholar

Szweda P., Zalewska M., Pilch J., Kot B., Milewski S. (2018). Essential oils as potential anti-staphylococcal agents. Acta Vet. Beograd, 68: 95-107. Search in Google Scholar

Tang K.L., Caffrey N.P., Nóbrega D.B., Cork S.C., Ronksley P.E., Barkema H.W., Polachek A.J., Ganshorn H., Sharma N., Kellner J.D. (2019). Comparison of different approaches to antibiotic restriction in food-producing animals: stratified results from a systematic review and meta-analysis. BMJ Glob. Health, 4: e001710. Search in Google Scholar

Thompson-Crispi K.A., Miglior F., Mallard B.A. (2013). Incidence rates of clinical mastitis among Canadian Holsteins classified as high, average, or low immune responders. Clin. Vaccine Immunol., 20: 106-12. Search in Google Scholar

Tomanić Z., Stanojević J., Galić I., Ružić Z., Kukurić T., Tešin N., Prpa B., Kovačević Z. (2022). Review of trends in essential oils as alternatives to antibiotics in bovine mastitis treatment. Zb. Matice Srp. Prir. Nauk., 142: 47-60. Search in Google Scholar

Tomanić D., Božin B., Čabarkapa I., Kladar N., Radinović M., Maletić M., Kovačević Z. (2022a). Chemical composition, antioxidant and antibacterial activity of two different essential oils against mastitis associated pathogens. Acta Vet. Beograd,7: 45-58 Search in Google Scholar

Tomanić D., Božin B., Kladar N., Stanojević J., Čabarkapa I., Stilinović N., Apić J., Božić D.D., Kovačević Z. (2022b). Environmental bovine mastitis pathogens: prevalence, antimicrobial susceptibility, and sensitivity to Thymus vulgaris L., Thymus serpyllum L., and Origanum vulgare L. essential oils. Antibiotics, 11: 1077. Search in Google Scholar

Tomanić D., Kladar N., Radinović M., Stančić I., Erdeljan M., Stanojević J., Galić I., Bijelić K., Kovačević Z. (2023a). Intramammary Ethno-Veterinary Formulation in Bovine Mastitis Treatment for Optimization of Antibiotic Use. Pathogens, 12: 259. Search in Google Scholar

Tomanić D., Samardžija M., Kovačević Z. (2023b). Alternatives to antimicrobial treatment in bovine mastitis therapy: A Review. Antibiotics, 12: 683. Search in Google Scholar

Tomanić D., Božić D.D., Kladar N., Samardžija M., Apić J., Baljak J., Kovačević Z. (2024). Clinical Evidence on Expansion of Essential Oil-Based Formulation’s Pharmacological Activity in Bovine Mastitis Treatment: Antifungal Potential as Added Value. Antibiotics, 13: 575. Search in Google Scholar

Tongnuanchan P., Benjakul S. (2014). Essential oils: extraction, bioactivities, and their uses for food preservation. J. Food Sci., 79: 1231-1249. Search in Google Scholar

Tortorano A.M., Prigitano A., Dho G., Piccinini R., Dapra V., Viviani M.A. (2008). In vitro activity of conventional antifungal drugs and natural essences against the yeast-like alga Prototheca. J. Antimicrob. Chemother., 61: 1312-1314. Search in Google Scholar

Touza-Otero L., Landin M., Diaz-Rodriguez P. (2024). Fighting antibiotic resistance in the local management of bovine mastitis. Biomed. Pharmacother., 170, 115967. Search in Google Scholar

Tudor L., Pituru M.T., Gheorghe-Irimia R.A., Șonea C., Tăpăloagă D. (2023). Optimizing milk production, quality and safety through essential oil applications. Farmacia, 71: 5. Search in Google Scholar

Ucella-Filho J.G.M., Ferreira N.S., Alves M.R., Ignacchiti M.D.C., Júnior A.F.D., Resende J.A. (2024). Evaluation of natural products as therapeutic alternatives for bovine mastitis and implications for future research. S. Afr. J. Bot., 167: 310-321. Search in Google Scholar

Ünal N., Kiymaci M.E., Savluk M., Erdogan H., Seker E. (2024). Determination of antibacterial and anti-biofilm activities of Terpinen-4-ol loaded polydopamine nanoparticles against Staphylococcus aureus isolates from cows with subclinical mastitis. Vet. Res. Commun., 48: 3655-3668. Search in Google Scholar

Vaou N., Stavropoulou E., Voidarou C., Tsakris Z., Rozos G., Tsigalou C., Bezirtzoglou E. (2022). Interactions between medical plant-derived bioactive compounds: focus on antimicrobial combination effects. Antibiotics, 11: 1014. Search in Google Scholar

Wang J., Liu M., Wu Y., Wang L., Liu J., Jiang L., Yu Z. (2016). Medicinal herbs as a potential strategy to decrease methane production by rumen microbiota: a systematic evaluation with a focus on Perilla frutescens seed extract. Appl. Microbiol. Biotechnol., 100: 9757-9771. Search in Google Scholar

Williamson J., Callaway T., Rollin E., Ryman V. (2022). Association of milk somatic cell count with bacteriological cure of intramammary infection—a review. Agriculture, 12: 1437. Search in Google Scholar

Zarooni S., Rahchamani R., Ghanbari F., Khanahmadi A. (2021). Antibacterial effect of Satureja hortensis and Salvia officinalis essential oils against major bovine mastitis bacteria. Iran J. Vet. Sci. Technol., 13: 75-81. Search in Google Scholar