REFERENCES

1. Capps B. One health ethics. Bioethics 2022;36:348-55.

2. Sinclair JR. Importance of a One Health approach in advancing global health security and the sustainable development goals. Rev Sci Tech Off Int Epiz 2019;38:145-54.

3. Gray GC, Mazet JAK. To Succeed, One Health must win animal agriculture’s stronger collaboration. Clin Infect Dis 2020;70:535-7.

4. Ribitsch I, Baptista PM, Lange-Consiglio A, et al. Large animal models in regenerative medicine and tissue engineering: to do or not to do. Front Bioeng Biotechnol 2020;8:972.

5. Whatford L, van Winden S, Häsler B. A systematic literature review on the economic impact of endemic disease in UK sheep and cattle using a One Health conceptualisation. Prev Vet Med 2022;209:105756.

6. Omoga DCA, Tchouassi DP, Venter M, et al. Circulation of ngari virus in livestock, kenya. mSphere 2022;7:e0041622.

7. Hughes K, Watson CJ. The mammary microenvironment in mastitis in humans, dairy ruminants, rabbits and rodents: a one health focus. J Mammary Gland Biol Neoplasia 2018;23:27-41.

8. Ancheta LR, Shramm PA, Bouajram R, Higgins D, Lappi DA. Saporin as a commercial reagent: its uses and unexpected impacts in the biological sciences-tools from the plant kingdom. Toxins 2022;14:184.

9. Ferreira G, Meurisse M, Tillet Y, Lévy F. Distribution and co-localization of choline acetyltransferase and p75 neurotrophin receptors in the sheep basal forebrain: implications for the use of a specific cholinergic immunotoxin. Neuroscience 2001;104:419-39.

10. Ellenbroek B, Youn J. Rodent models in neuroscience research: is it a rat race? Dis Model Mech 2016;9:1079-87.

11. Keifer J, Summers CH. Putting the “Biology” back into “Neurobiology”: the strength of diversity in animal model systems for neuroscience research. Front Syst Neurosci 2016;10:69.

12. Morton AJ, Howland DS. Large genetic animal models of Huntington’s disease. J Huntingtons Dis 2013;2:3-19.

13. Ziegler A, Gonzalez L, Blikslager A. Large animal models: the key to translational discovery in digestive disease research. Cell Mol Gastroenterol Hepatol 2016;2:716-24.

14. Eaton SL, Wishart TM. Bridging the gap: large animal models in neurodegenerative research. Mamm Genome 2017;28:324-37.

15. Grow DA, McCarrey JR, Navara CS. Advantages of nonhuman primates as preclinical models for evaluating stem cell-based therapies for Parkinson’s disease. Stem Cell Res 2016;17:352-66.

16. European Commission. Directorate General for Health and Food Safety. Final opinion on the need for non-human primates in biomedical research, production and testing of products and devices (Update 2017). Available from: https://data.europa.eu/doi/10.2875/337906. [Last accessed on 25 Oct 2023].

17. Isaacson G, Wulc AE. Applicability of a sheep model for training in plastic surgery of eyelids and orbit. Ear Nose Throat J 2022;101:43S-9S.

18. Ianacone DC, Gnadt BJ, Isaacson G. Ex vivo ovine model for head and neck surgical simulation. Am J Otolaryngol 2016;37:272-8.

19. Dolezalova D, Hruska-Plochan M, Bjarkam CR, et al. Pig models of neurodegenerative disorders: utilization in cell replacement-based preclinical safety and efficacy studies. J Comp Neurol 2014;522:2784-801.

20. Banstola A, Reynolds JNJ. The sheep as a large animal model for the investigation and treatment of human disorders. Biology 2022;11:1251.

21. Houston F, Andréoletti O. Animal prion diseases: the risks to human health. Brain Pathol 2019;29:248-62.

22. Block AJ, Bartz JC. Prion strains: shining new light on old concepts. Cell Tissue Res 2023;392:113-33.

23. Onodera T, Sakudo A. Introduction to current progress in advanced research on prions. Curr Issues Mol Biol 2020;36:63-6.

24. Ayers JI, Paras NA, Prusiner SB. Expanding spectrum of prion diseases. Emerg Top Life Sci 2020;4:155-67.

25. Carlson GA, Prusiner SB. How an infection of sheep revealed prion mechanisms in Alzheimer’s disease and other neurodegenerative disorders. Int J Mol Sci 2021;22:4861.

26. Wagner J, Ryazanov S, Leonov A, et al. Anle138b: a novel oligomer modulator for disease-modifying therapy of neurodegenerative diseases such as prion and Parkinson’s disease. Acta Neuropathol 2013;125:795-813.

27. Jeffrey M, Ryder S, Martin S, et al. Oral inoculation of sheep with the agent of bovine spongiform encephalopathy (BSE). 1. Onset and distribution of disease-specific PrP accumulation in brain and viscera. J Comp Pathol 2001;124:280-9.

28. Åkesson CP, McGovern G, Dagleish MP, et al. Exosome-producing follicle associated epithelium is not involved in uptake of PrPd from the gut of sheep (Ovis aries): an ultrastructural study. PLoS One 2011;6:e22180.

29. Sisó S, Jeffrey M, Houston F, Hunter N, Martin S, González L. Pathological phenotype of sheep scrapie after blood transfusion. J Comp Pathol 2010;142:27-35.

30. Lacroux C, Vilette D, Fernández-Borges N, et al. Prionemia and leukocyte-platelet-associated infectivity in sheep transmissible spongiform encephalopathy models. J Virol 2012;86:2056-66.

31. Lim K, Kim SY, Lee B, et al. Magnetic microparticle-based multimer detection system for the detection of prion oligomers in sheep. Int J Nanomedicine 2015;10:241-50.

32. Danics K, Forrest SL, Kapas I, et al. Neurodegenerative proteinopathies associated with neuroinfections. J Neural Transm 2021;128:1551-66.

33. Lukiw WJ, Jaber VR, Pogue AI, Zhao Y. SARS-CoV-2 invasion and pathological links to prion disease. Biomolecules 2022;12:1253.

34. Reich SG, Savitt JM. Parkinson’s disease. Med Clin North Am 2019;103:337-50.

35. Rao M, Agrawal DK, Shirsath C. Thermoreversible mucoadhesive in situ nasal gel for treatment of Parkinson’s disease. Drug Dev Ind Pharm 2017;43:142-50.

36. Bourke CA. Astrocyte dysfunction following molybdenum-associated purine loading could initiate Parkinson’s disease with dementia. NPJ Parkinsons Dis 2018;4:7.

37. Bloem BR, Okun MS, Klein C. Parkinson’s disease. Lancet 2021;397:2284-303.

38. Fornai F, Schlüter OM, Lenzi P, et al. Parkinson-like syndrome induced by continuous MPTP infusion: convergent roles of the ubiquitin-proteasome system and alpha-synuclein. Proc Natl Acad Sci U S A 2005;102:3413-8.

39. Hammock BD, Beale AM, Work T, et al. A sheep model for MPTP induced Parkinson-like symptoms. Life Sci 1989;45:1601-8.

40. Baskin DS, Browning JL, Widmayer MA, Zhu ZQ, Grossman RG. Development of a model for Parkinson’s disease in sheep using unilateral intracarotid injection of MPTP via slow continuous infusion. Life Sci 1994;54:471-9.

41. Capucciati A, Zucca FA, Monzani E, Zecca L, Casella L, Hofer T. Interaction of neuromelanin with xenobiotics and consequences for neurodegeneration; promising experimental models. Antioxidants 2021;10:824.

42. Nelson PT, Greenberg SG, Saper CB. Neurofibrillary tangles in the cerebral cortex of sheep. Neurosci Lett 1994;170:187-90.

43. Reid SJ, Mckean NE, Henty K, et al. Alzheimer’s disease markers in the aged sheep (Ovis aries). Neurobiol Aging 2017;58:112-9.

44. Davies ES, Morphew RM, Cutress D, Morton AJ, McBride S. Characterization of microtubule-associated protein tau isoforms and Alzheimer’s disease-like pathology in normal sheep (ovis aries): relevance to their potential as a model of Alzheimer’s disease. Cell Mol Life Sci 2022;79:560.

45. Skene DJ, Middleton B, Fraser CK, et al. Metabolic profiling of presymptomatic Huntington’s disease sheep reveals novel biomarkers. Sci Rep 2017;7:43030.

46. Taghian T, Gallagher J, Batcho E, et al. Brain alterations in aged OVT73 sheep model of Huntington’s disease: an MRI based approach. J Huntingtons Dis 2022;11:391-406.

47. Morton AJ. Large-brained animal models of Huntington’s disease: sheep. In: Precious SV, Rosser AE, Dunnett SB, editors. Huntington’s Disease. New York: Springer; 2018. p. 221-39.

48. Howland DS, Munoz-Sanjuan I. Mind the gap: models in multiple species needed for therapeutic development in Huntington’s disease. Mov Disord 2014;29:1397-403.

49. Jacobsen JC, Bawden CS, Rudiger SR, et al. An ovine transgenic Huntington’s disease model. Hum Mol Genet 2010;19:1873-82.

50. Handley RR, Reid SJ, Patassini S, et al. Metabolic disruption identified in the Huntington’s disease transgenic sheep model. Sci Rep 2016;6:20681.

51. Reid SJ, Patassini S, Handley RR, et al. Further molecular characterisation of the OVT73 transgenic sheep model of Huntington’s disease identifies cortical aggregates. J Huntingtons Dis 2013;2:279-95.

52. Morton AJ, Rudiger SR, Wood NI, et al. Early and progressive circadian abnormalities in Huntington’s disease sheep are unmasked by social environment. Hum Mol Genet 2014;23:3375-83.

53. Vas S, Nicol AU, Kalmar L, Miles J, Morton AJ. Abnormal patterns of sleep and EEG power distribution during non-rapid eye movement sleep in the sheep model of Huntington’s disease. Neurobiol Dis 2021;155:105367.

54. Morton AJ, Middleton B, Rudiger S, Bawden CS, Kuchel TR, Skene DJ. Increased plasma melatonin in presymptomatic Huntington disease sheep (Ovis aries): Compensatory neuroprotection in a neurodegenerative disease? J Pineal Res 2020;68:e12624.

55. Morton AJ, Avanzo L. Executive decision-making in the domestic sheep. PLoS One 2011;6:e15752.

56. McBride SD, Perentos N, Morton AJ. A mobile, high-throughput semi-automated system for testing cognition in large non-primate animal models of Huntington disease. J Neurosci Methods 2016;265:25-33.

57. Mears ER, Handley RR, Grant MJ, et al. A multi-omic Huntington’s disease transgenic sheep-model database for investigating disease pathogenesis. J Huntingtons Dis 2021;10:423-34.

58. Mondo E, Moser R, Gao G, et al. Selective neuronal uptake and distribution of AAVrh8, AAV9, and AAVrh10 in sheep after intra-striatal administration. J Huntingtons Dis 2018;7:309-19.

59. Pfister EL, DiNardo N, Mondo E, et al. Artificial miRNAs reduce human mutant huntingtin throughout the striatum in a transgenic sheep model of Huntington’s disease. Hum Gene Ther 2018;29:663-73.

60. Amorim IS, Mitchell NL, Palmer DN, et al. Molecular neuropathology of the synapse in sheep with CLN5 Batten disease. Brain Behav 2015;5:e00401.

61. Frugier T, Mitchell NL, Tammen I, et al. A new large animal model of CLN5 neuronal ceroid lipofuscinosis in Borderdale sheep is caused by a nucleotide substitution at a consensus splice site (c.571+1G>A) leading to excision of exon 3. Neurobiol Dis 2008;29:306-15.

62. Nelvagal HR, Lange J, Takahashi K, Tarczyluk-Wells MA, Cooper JD. Pathomechanisms in the neuronal ceroid lipofuscinoses. Biochim Biophys Acta Mol Basis Dis 2020;1866:165570.

63. Handrup MM, Mølgaard H, Andersen BN, Ostergaard JR. Pacemaker implantation in juvenile neuronal ceroid lipofuscinosis (CLN3)-a long-term follow-up study. Front Neurol 2022;13:846240.

64. Batten Disease News. Juvenile Batten Disease. Available from: https://battendiseasenews.com/juvenile-batten-disease/. [Last accessed on 25 Oct 2023].

65. Huber RJ, Hughes SM, Liu W, Morgan A, Tuxworth RI, Russell C. The contribution of multicellular model organisms to neuronal ceroid lipofuscinosis research. Biochim Biophys Acta Mol Basis Dis 2020;1866:165614.

66. Nelvagal HR, Cooper JD. Translating preclinical models of neuronal ceroid lipofuscinosis: progress and prospects. Expert Opinion on Orphan Drugs 2017;5:727-40.

67. Palmer DN, Neverman NJ, Chen JZ, et al. Recent studies of ovine neuronal ceroid lipofuscinoses from BARN, the Batten Animal Research Network. Biochim Biophys Acta 2015;1852:2279-86.

68. Eaton SL, Proudfoot C, Lillico SG, et al. CRISPR/Cas9 mediated generation of an ovine model for infantile neuronal ceroid lipofuscinosis (CLN1 disease). Sci Rep 2019;9:9891.

69. Mitchell NL, Russell KN, Barrell GK, Tammen I, Palmer DN. Characterization of neuropathology in ovine CLN5 and CLN6 neuronal ceroid lipofuscinoses (Batten disease). Dev Neurobiol 2023;83:127-42.

70. Nelvagal HR, Eaton SL, Wang SH, et al. Cross-species efficacy of enzyme replacement therapy for CLN1 disease in mice and sheep. J Clin Invest 2022;132:e163107.

71. Murray SJ, Almuqbel MM, Felton SA, et al. Progressive MRI brain volume changes in ovine models of CLN5 and CLN6 neuronal ceroid lipofuscinosis. Brain Commun 2023;5:fcac339.

72. kleine Holthaus S, Smith AJ, Mole SE, Ali RR. Gene therapy approaches to treat the neurodegeneration and visual failure in neuronal ceroid lipofuscinoses. In: Ash JD, Anderson RE, Lavail MM, Bowes Rickman C, Hollyfield JG, Grimm C, editors. Retinal Degenerative Diseases. Cham: Springer International Publishing; 2018. p. 91-9.

73. Murray SJ, Mitchell NL. Intravitreal injections in the ovine eye. J Vis Exp 2022.

74. Mitchell NL, Murray SJ, Wellby MP, et al. Long-term safety and dose escalation of intracerebroventricular CLN5 gene therapy in sheep supports clinical translation for CLN5 Batten disease. Front Genet 2023;14:1212228.

75. Perentos N, Martins AQ, Watson TC, et al. Translational neurophysiology in sheep: measuring sleep and neurological dysfunction in CLN5 Batten disease affected sheep. Brain 2015;138:862-74.

76. Barry LA, Kay GW, Mitchell NL, Murray SJ, Jay NP, Palmer DN. Aggregation chimeras provide evidence of in vivo intercellular correction in ovine CLN6 neuronal ceroid lipofuscinosis (Batten disease). PLoS One 2022;17:e0261544.

77. Sawiak SJ, Perumal SR, Rudiger SR, et al. Rapid and progressive regional brain atrophy in CLN6 Batten disease affected sheep measured with longitudinal magnetic resonance imaging. PLoS One 2015;10:e0132331.

78. Tyynelä J, Sohar I, Sleat DE, et al. A mutation in the ovine cathepsin D gene causes a congenital lysosomal storage disease with profound neurodegeneration. EMBO J 2000;19:2786-92.

79. Cronin GM, Beganovic DF, Sutton AL, Palmer D, Thomson PC, Tammen I. Manifestation of neuronal ceroid lipofuscinosis in Australian Merino sheep: observations on altered behaviour and growth. Appl Anim Behav Sci 2016;175:32-40.

80. Johnson TB, Cain JT, White KA, Ramirez-Montealegre D, Pearce DA, Weimer JM. Therapeutic landscape for Batten disease: current treatments and future prospects. Nat Rev Neurol 2019;15:161-78.

81. Mitchell NL, Russell KN, Wellby MP, et al. Longitudinal in vivo monitoring of the CNS demonstrates the efficacy of gene therapy in a sheep model of CLN5 Batten disease. Mol Ther 2018;26:2366-78.

82. Hughes SM, Hope KM, Xu JB, Mitchell NL, Palmer DN. Inhibition of storage pathology in prenatal CLN5-deficient sheep neural cultures by lentiviral gene therapy. Neurobiol Dis 2014;62:543-50.

83. Sharif-Alhoseini M, Khormali M, Rezaei M, et al. Animal models of spinal cord injury: a systematic review. Spinal Cord 2017;55:714-21.

84. Wilson S, Nagel SJ, Frizon LA, et al. The hemisection approach in large animal models of spinal cord injury: overview of methods and applications. J Invest Surg 2020;33:240-51.

85. Mesquita RC, D’Souza A, Bilfinger TV, et al. Optical monitoring and detection of spinal cord ischemia. PLoS One 2013;8:e83370.

86. Petteys RJ, Spitz SM, Syed H, et al. Design and testing of a controlled electromagnetic spinal cord impactor for use in large animal models of acute traumatic spinal cord injury. J Clin Neurosci 2017;43:229-34.

87. Wilson S, Abode-Iyamah KO, Miller JW, et al. An ovine model of spinal cord injury. J Spinal Cord Med 2017;40:346-60.

88. Kwon BK, Oxland TR, Tetzlaff W. Animal models used in spinal cord regeneration research. Spine 2002;27:1504-10.

89. Yeo JD, Payne W, Hinwood B, Kidman AD. The experimental contusion injury of the spinal cord in sheep. Paraplegia 1975;12:279-98.

90. Safayi S, Jeffery ND, Shivapour SK, et al. Kinematic analysis of the gait of adult sheep during treadmill locomotion: parameter values, allowable total error, and potential for use in evaluating spinal cord injury. J Neurol Sci 2015;358:107-12.

91. Dalm BD, Viljoen SV, Dahdaleh NS, et al. Revisiting intradural spinal cord stimulation: an introduction to a novel intradural spinal cord stimulation device. Innovative Neurosurgery 2014;2:13-20. Available from: https://www.researchgate.net/profile/Sina-Safayi/publication/269392974_Revisiting_intradural_spinal_cord_stimulation_An_introduction_to_a_novel_intradural_spinal_cord_stimulation_device/links/548863560cf2ef3447908d46/Revisiting-intradural-spinal-cord-stimulation-An-introduction-to-a-novel-intradural-spinal-cord-stimulation-device.pdf. [Last accessed on 25 Oct 2023]

92. Flouty OE, Oya H, Kawasaki H, et al. Intracranial somatosensory responses with direct spinal cord stimulation in anesthetized sheep. PLoS One 2013;8:e56266.

93. Böckler D, Kotelis D, Kohlhof P, et al. Spinal cord ischemia after endovascular repair of the descending thoracic aorta in a sheep model. Eur J Vasc Endovasc Surg 2007;34:461-9.

94. Kaiser EE, West FD. Large animal ischemic stroke models: replicating human stroke pathophysiology. Neural Regen Res 2020;15:1377-87.

95. Taha A, Bobi J, Dammers R, et al. Comparison of large animal models for acute ischemic stroke: which model to use? Stroke 2022;53:1411-22.

96. NHLBI, NIH. Stroke. Treatment. Available from: https://www.nhlbi.nih.gov/health/stroke/treatment. [Last accessed on 25 Oct 2023].

97. Graczyk S, Zdun M. The structure of the rostral epidural rete mirabile in selected representatives of the Cervidae and Bovidae families. Acta Zoologica 2021;102:496-501.

98. Boltze J, Förschler A, Nitzsche B, et al. Permanent middle cerebral artery occlusion in sheep: a novel large animal model of focal cerebral ischemia. J Cereb Blood Flow Metab 2008;28:1951-64.

99. Wells AJ, Vink R, Blumbergs PC, et al. A surgical model of permanent and transient middle cerebral artery stroke in the sheep. PLoS One 2012;7:e42157.

100. Breen KM, Karsch FJ. New insights regarding glucocorticoids, stress and gonadotropin suppression. Front Neuroendocrinol 2006;27:233-45.

101. Karsch FJ, Battaglia DF, Breen KM, Debus N, Harris TG. Mechanisms for ovarian cycle disruption by immune/inflammatory stress. Stress 2002;5:101-12.

102. Tilbrook AJ, Turner AI, Clarke IJ. Effects of stress on reproduction in non-rodent mammals: the role of glucocorticoids and sex differences. Rev Reprod 2000;5:105-13.

103. Merkley CM, Shuping SL, Nestor CC. Neuronal networks that regulate gonadotropin-releasing hormone/luteinizing hormone secretion during undernutrition: evidence from sheep. Domest Anim Endocrinol 2020;73:106469.

104. Karsch FJ, Moenter SM. Neuroendocrine regulation of seasonal breeding cycles in the ewe. J Exp Zool Suppl 1990;256:17-21.

105. Clarke IJ. Sex and season are major determinants of voluntary food intake in sheep. Reprod Fertil Dev 2001;13:577-82.

106. Weems PW, Lehman MN, Coolen LM, Goodman RL. Chapter Four - The roles of neurokinins and endogenous opioid peptides in control of pulsatile LH secretion. Vitam Horm 2018;107:89-135.

107. Veldhuis JD, Fletcher TP, Gatford KL, Egan AR, Clarke IJ. Hypophyseal-portal somatostatin (SRIH) and jugular venous growth hormone secretion in the conscious unrestrained ewe. Neuroendocrinology 2002;75:83-91.

108. Frohman LA, Downs TR, Clarke IJ, Thomas GB. Measurement of growth hormone-releasing hormone and somatostatin in hypothalamic-portal plasma of unanesthetized sheep. Spontaneous secretion and response to insulin-induced hypoglycemia. J Clin Invest 1990;86:17-24.

109. Lehman MN, Coolen LM, Goodman RL. Importance of neuroanatomical data from domestic animals to the development and testing of the KNDy hypothesis for GnRH pulse generation. Domest Anim Endocrinol 2020;73:106441.

110. Engler D, Pham T, Fullerton MJ, Ooi G, Funder JW, Clarke IJ. Studies of the secretion of corticotropin-releasing factor and arginine vasopressin into the hypophysial-portal circulation of the conscious sheep. I. Effect of an audiovisual stimulus and insulin-induced hypoglycemia. Neuroendocrinology 1989;49:367-81.

111. Wilson M, Barrell G. Modification of a method for cannulation of the cisterna magna in sheep to enable chronic collection of cerebrospinal fluid. Lab Anim 2015;49:85-7.

112. Falconer J, Owens PC, Smith R. Cannulation of the cisterna magna in sheep: a method for chronic studies of cerebrospinal fluid. Aust J Exp Biol Med Sci 1985;63 (Pt 2):157-62.

113. Scott CJ, Tilbrook AJ, Rawson JA, Clarke IJ. Gonadal steroid receptors in the regulation of GnRH secretion in farm animals. Anim Reprod Sci 2000;60-1:313-26.

114. Clarke IJ. Multifarious effects of estrogen on the pituitary gonadotrope with special emphasis on studies in the ovine species. Arch Physiol Biochem 2002;110:62-73.

115. Tilbrook AJ, Clarke IJ. Negative feedback regulation of the secretion and actions of gonadotropin-releasing hormone in males. Biol Reprod 2001;64:735-42.

116. Clarke IJ. The GNRH/gonadotropin axis in the ewe, cow and sow. Domest Anim Endocrinol 1989;6:1-14.

117. Nestor CC, Bedenbaugh MN, Hileman SM, Coolen LM, Lehman MN, Goodman RL. Regulation of GnRH pulsatility in ewes. Reproduction 2018;156:R83-99.

118. McCosh RB, Lopez JA, Szeligo BM, et al. Evidence that nitric oxide is critical for LH surge generation in female sheep. Endocrinology 2020;161:bqaa010.

119. Wickramasuriya N, Hawkins R, Atwood C, Butler T. The roles of GnRH in the human central nervous system. Horm Behav 2022;145:105230.

120. Wang F, Flanagan J, Su N, et al. RNAscope: a novel in situ RNA analysis platform for formalin-fixed, paraffin-embedded tissues. J Mol Diagn 2012;14:22-9.

121. Merkley CM, Renwick AN, Shuping SL, Harlow K, Sommer JR, Nestor CC. Undernutrition reduces kisspeptin and neurokinin B expression in castrated male sheep. Reprod Fertil 2020;1:1-13.

122. Christian P, Smith ER. Adolescent undernutrition: global burden, physiology, and nutritional risks. Ann Nutr Metab 2018;72:316-28.

123. Harlow K, Griesgraber MJ, Seman AD, et al. The impact of undernutrition on KNDy (kisspeptin/neurokinin B/dynorphin) neurons in female lambs. J Neuroendocrinol 2022;34:e13135.

124. Aerts EG, Harlow K, Griesgraber MJ, et al. Kisspeptin, neurokinin B, and dynorphin expression during pubertal development in female sheep. Biology 2021;10:988.

125. Wood S, Loudon A. Clocks for all seasons: unwinding the roles and mechanisms of circadian and interval timers in the hypothalamus and pituitary. J Endocrinol 2014;222:R39-59.

126. Esposito E, Li W, T Mandeville E, et al. Potential circadian effects on translational failure for neuroprotection. Nature 2020;582:395-8.

127. Piccione G, Giannetto C, Casella S, Caola G. Circadian activity rhythm in sheep and goats housed in stable conditions. Folia Biol 2008;56:133-7.

128. Wyse CA, Zhang X, McLaughlin M, et al. Circadian rhythms of melatonin and behaviour in juvenile sheep in field conditions: effects of photoperiod, environment and weaning. Physiol Behav 2018;194:362-70.

129. Plaza J, Palacios C, Abecia JA, Nieto J, Sánchez-garcía M, Sánchez N. GPS monitoring reveals circadian rhythmicity in free-grazing sheep. Appl Anim Behav Sci 2022;251:105643.

130. Helm B, Ben-Shlomo R, Sheriff MJ, et al. Annual rhythms that underlie phenology: biological time-keeping meets environmental change. Proc Biol Sci 2013;280:20130016.

131. Tsingotjidou A, Papadopoulos GC. Neuronal expression of Fos-like protein along the afferent pathway of the milk-ejection reflex in the sheep. Brain Res 1996;741:309-13.

132. Tsingotjidou AS, Papadopoulos GC. Anatomic organization of the ascending branch of the milk-ejection reflex in sheep: primary afferent neurons. J Comp Neurol 2003;460:66-79.

133. Ricordeau G, Martinet J, Denamur R, Petrequin P, Carpentier M. Traite a la machine des brebis préalpes du sud. importance des différentes opérations de la traite. (in French). Ann Zootech 1963;12:203-23.

134. Kosmidis EK, Tsingotjidou AS, Iliadis L, Batzios C, Papadopoulos GC. A sparsely connected network to model the relay stations of the sheep milk ejection reflex. Neurocomputing 2009;73:80-6.

135. O’Callaghan TF, Ross RP, Stanton C, Clarke G. The gut microbiome as a virtual endocrine organ with implications for farm and domestic animal endocrinology. Domest Anim Endocrinol 2016;56 Suppl:S44-55.

136. Kraimi N, Dawkins M, Gebhardt-Henrich SG, et al. Influence of the microbiota-gut-brain axis on behavior and welfare in farm animals: a review. Physiol Behav 2019;210:112658.

137. Forcina G, Pérez-Pardal L, Carvalheira J, Beja-Pereira A. Gut microbiome studies in livestock: achievements, challenges, and perspectives. Animals 2022;12:3375.

138. McDonough CM, Xu HS, Guo TL. Toxicity of bisphenol analogues on the reproductive, nervous, and immune systems, and their relationships to gut microbiome and metabolism: insights from a multi-species comparison. Crit Rev Toxicol 2021;51:283-300.

139. Ammerman CB, Miller SM, Fick KR, Hansard SL 2nd. Contaminating elements in mineral supplements and thier potential toxicity: a review. J Anim Sci 1977;44:485-508.

140. Soliman SA, Svendsgaard D, Farmer JD, Curley A, Durham WF. Six-month daily treatment of sheep with neurotoxic organophosphorus compounds. Toxicol Appl Pharmacol 1983;69:417-31.

141. Evans NP, Bellingham M, Sharpe RM, et al. Reproduction Symposium: does grazing on biosolids-treated pasture pose a pathophysiological risk associated with increased exposure to endocrine disrupting compounds? J Anim Sci 2014;92:3185-98.

142. Guignard D, Canlet C, Tremblay-Franco M, et al. Gestational exposure to bisphenol a induces region-specific changes in brain metabolomic fingerprints in sheep. Environ Int 2022;165:107336.

143. Shen X, Chi Y, Xiong K. The effect of heavy metal contamination on humans and animals in the vicinity of a zinc smelting facility. PLoS One 2019;14:e0207423.

144. Pinnapureddy AR, Stayner C, McEwan J, Baddeley O, Forman J, Eccles MR. Large animal models of rare genetic disorders: sheep as phenotypically relevant models of human genetic disease. Orphanet J Rare Dis 2015;10:107.

145. Kalds P, Zhou S, Cai B, et al. Sheep and goat genome engineering: from random transgenesis to the CRISPR era. Front Genet 2019;10:750.

146. Banstola A, Reynolds JNJ. Mapping sheep to human brain: the need for a sheep brain atlas. Front Vet Sci 2022;9:961413.

147. Murray SJ, Mitchell NL. The translational benefits of sheep as large animal models of human neurological disorders. Front Vet Sci 2022;9:831838.

148. Kendrick KM. Response to 'Sheep recognize familiar and unfamiliar human faces from two-dimensional images'. R Soc Open Sci 2019;6:182187.

149. Gerussi T, Graïc JM, Grandis A, Peruffo A, Cozzi B. The orbitofrontal cortex of the sheep. Topography, organization, neurochemistry, digital tensor imaging and comparison with the chimpanzee and human. Brain Struct Funct 2022;227:1871-91.

150. Murray SJ, Black BL, Reid SJ, et al. Chemical neuroanatomy of the substantia nigra in the ovine brain. J Chem Neuroanat 2019;97:43-56.

151. Guidelines for the housing of sheep in scientific institutions. Available from: https://www.animalethics.org.au/__data/assets/pdf_file/0010/249913/Guide-23-housing-sheep.pdf. [Last accessed on 25 Oct 2023].

152. Cornell University College of Veterinary Medicine. Basic biosecurity best management practices for sheep & goat farms. Available from: https://www.vet.cornell.edu/animal-health-diagnostic-center/programs/nyschap/modules-documents/basic-biosecurity-best-management-practices-sheep-goat-farms. [Last accessed on 25 Oct 2023].

153. Allen MJ, Borkowski GL. The laboratory small ruminant. 1st ed. CRC Press. Available from: https://doi.org/10.1201/9780849377518. [Last accessed on 25 Oct 2023].

154. Cost to keep a sheep for one year in city limits. Available from: http://www.tvsp.org/cost_to_keep_a_sheep.html?fbclid=IwAR3PW02mmzhI1y2_BpejoJoZz4D4dJAhG_tiSC6Iu6X0YPU6FkwA74Q4wqA. [Last accessed on 25 Oct 2023].