Exploring the potential of phenolic and antioxidant compounds identified and quantified of Caesalpinia coriaria fruits and their impacts on lambs’ performance and health

1 Jack AA, Oghenesuvwe O, Adewumi MK, Omojola AB, Adegbeye MJ, Faniyi TO, Salem AZM, Elghandour M, Cuevas-Barragan CE, Pliego-Barbabosa A, Ekanem DE (2022) Conversion of Neem Fruit biomass for rumen manipulation, meat fatty acid profile improvement of rams. Biomass Conversion and Biorefinery https://doi.org/10.1007/s13399-022-02629-4 Search in Google Scholar

2 Jimoh AO, Temidayo DO, Okin-Aminu O, Ojo OA (2023) Herbal supplements suppress pro-infammatory cytokines, boost humoral immunity, and modulate adipokines to enhance the productivity traits of rabbit bucks in hot climatic conditions. Tropical Animal Health and Production 55:227 https://doi.org/10.1007/s11250-023-03640-1 Search in Google Scholar

3 Campos-Pérez A, Camacho-Díaz LM, Adegbeye MJ, Elghandour MMY, Cipriano-Salazar M, Olivares-Pérez J, Rojas-Hernández S, Salem AZM (2021) Valorization of Caesalpinia coriaria fruit waste to enhance the ruminal mitigation of greenhouse gases production. Waste and Bio-mass Valorization 12,4991-5000 https://doi.org/10.1007/s12649-021-01361-w Search in Google Scholar

4 Jesus-Martinez XD, Olmedo-Juarez A, Rojas Hernandez S, Zamilpa A, Mendoza P, de Gives ME, Villa-Mancera L-A, Camacho-Diaz LM, Cipriano Salazar M, Olivares-Perez J (2020) Evaluation of the hydroalcoholic extract elaborated with Caesal- piniacoriariaJacqWilld tree fruits in the control of Hemonchus- contortus Rudolphi. Agroforestry Systems 94(1315),1321 https://doi.org/10.1007/s10457-019-00398-0(0123456789 Search in Google Scholar

5 Manuel-Pablo A, Elghandour MY, Olivares-Perez J, Rojas-Hernandez S, Cipriano-Salazar M, Cruz-Lagunas B, Camacho-Diaz LM (2020) Productive performance, rumen fermentation and carcass yield of goats supplemented with cascalote fruits (Caesalpinia coriaria J. Willd). Agroforestry Systems 94(4), 1381–1391. https://doi.org/10.1007/s10457-018-0312-9 Search in Google Scholar

6 Jack AA, Adewumi MK, Adegbeye MJ, Ekanem DE, Salem AZM, Faniyi TO (2020) Growth-promoting effect of water-washed neem (Azadirachta indica A. Juss) fruit inclusion in West African dwarf rams. Tropical Animal Health and Production https://doi.org/10.1007/s11250-020-02380-w Search in Google Scholar

7 Sejian, V.; Maurya, V.P.; Kumar, K.; Naqvi, S.M.K. Effect of multiple stresses on growth and adaptive capability of Malpura ewes under semi-arid tropical environment. Trop. Anim. Health Prod. 2012, 45, 107–116. Search in Google Scholar

8 Adegbeye MJ, Aro SO, Fajemisin AN, Ravi Kanth Reddy P (2021) Effect of time of feeding on body temperature of wad bucks and pregnant does in tropical environment. Animal Review 8:1-9, https://doi.org/10.18488/journal.ar.2021.81.1.9 Search in Google Scholar

9 Abd-Elkader DY, Salem MZM, Komeil DA, Al-Huqail AA, Ali HM, Salah AH, Akrami M, Hassan HS (2021) Post-Harvest Enhancing and Botrytis cinerea Control of Strawberry Fruits Using Low Cost and Eco-Friendly Natural Oils. Agronomy 11, 1246, https://doi.org/10.3390/agronomy11061246 Search in Google Scholar

10 Zheng, W. and Clifford, M.N., 2008. Profiling the chlorogenic acids of sweet potato (Ipomoea batatas) from China. Food Chemistry, 106(1), pp.147-152 Search in Google Scholar

11 Clifford, M. N. (2003). The analysis and characterization of chlorogenic acids and other cinnamates. In C. Santos-Buelga & G. Williamson (Eds.), Methods polyphenol analysis (pp. 314–337). Cambridge: Royal Society of Chemistry. Search in Google Scholar

12 Masood A, Stark KD, Salem N (2005) A simplified and efficient method for the analysis of fatty acid methyl esters suitable for large clinical studies. Journal of Lipid Research 46 (10), 2299–2305 Search in Google Scholar

13 Michalski R, Łyko A (2010) Determination of bromate in water samples using post column derivatization method with triiodide. Journal of Environmental Science and Health Part A 45 (10), 1275–1280 Search in Google Scholar

14 Thienpont D, Rochette F, Vanparijs OFJ (1986) Diagnóstico de las helminthiasis por médio del examen coprológico. (2ª edição). (pp. 69-89). Beerse, Belgium: Janssen Research Foundation Search in Google Scholar

15 Madeira de Carvalho LM (2001) Epidemiologia e controlo da estrongilidose em diferentes sistemas de produção equina em Portugal. Tese de doutoramento em Sanidade Animal. (pp. 128-373). Lisboa: Faculdade de Medicina Veterinária – Universidade Técnica de Lisboa Search in Google Scholar

16 Zamiri MJ, RajaeiSharifabadi H, Bagheri AS, Solhjoo A (2015) Efects of inclusion of licorice (Glycyrrhiza glabra L.) leaves, a tannin-containing plant, in a low-protein diet on feedlot performance and carcass characteristics of fat-tailed lambs. Tropical Animal Health and Production 47, 597–602 Search in Google Scholar

17 Huang Q, Liu X, Zhao G, Hu T, Wang Y (2018) Potential and challenges of tannins as an alternative to in-feed antibiotics for farm animal production. Anim Nutr 4:137–150. Search in Google Scholar

18 Shangru LI, Chengrui Z, Ruixue W, Jiamei S, Hangshu X, Yonggen Z, Yukun S (2022) Establishment of a feed intake prediction model based on eating time, ruminating time and dietary composition. Computers and Electronics in Agriculture 202:107296 https://doi.org/10.1016/j.compag.2022.107296 Search in Google Scholar

19 Carnevalli RA, de Mello A, Coletti AJ, Garcia LF, Xavier DB (2020) Shade controls the ruminating and idleness times of dairy heifers in tropical integrated systems. Agro-forestry Systems 94:779–790 Search in Google Scholar

20 Kadzere CT, Murphy MR, Silanikove N, Maltz E 2002. Heat stress in lactating dairy cows: a review. Livestock Production Science 77, 59–91 Search in Google Scholar

21 Itavo CC, Morais MG, Cosra C, Itavo LCV, Franco GL, Silva JA, Reis FA (2011) Addition of propolis or monensin in the diet: Bahaviour and productivity of lambs in feedlots. Animal Feed Science and Tecnology 165:161-166 Search in Google Scholar

22 Adegbeye MJ (2022) Impact of Chronomanagement on the performance of West African dwarf goats. PhD Thesis. Federal University of Technology Akure, Nigeria. Pg 1-237 Search in Google Scholar

23 García-Hernández F, Rojo-Rubio R, Mendoza-de Gives P, González-Cortazar M, Zamilpa A, Mondragón-Ancelmo J, Villa-Mancera A, Olivares-Pérez J, Tapia-Maruri D, Olmedo-Juárez A (2022) In vitro and in vivo anthelmintic properties of Caesalpinia coriaria fruits against Hemonchus contortus. Experimental Parasitology 242:108401 Search in Google Scholar

24 Jeeva K, Thiyagarajan M, Elangovan V, Geetha N, Venkatachalam P (2014) Caesalpinia coriaria leaf extracts mediated biosynthesis of metallic silver nanoparticles and their antibacterial activity against clinically isolated pathogens. Industrial Crops and Products. 52:714–720 Search in Google Scholar

25 Tipu, M.A., Akhtar, M.S., Anjumi, M.I., Raja, M.L., 2006. New dimension of medicinal plants as animal feed, Pakistan Veterinary Journal, 26 (3), 144-148 Search in Google Scholar

26 Salem, A.Z.M., Elghandour, M.M.Y., Kholif, A.E., Lopez, S., Pliego, A.B., Cipriano-Salazar, M., Chagoyán, J.V., de Oca Jiménez, R., Alonso, M.U., 2017. Tree leaves of Salix babylonica extract as a natural anthelminthic for small-ruminant farms in a semiarid region in Mexico, Agroforestry Systems, 91(1), 111-122. Search in Google Scholar

27 Daniel UN, Ohalete CN, Ibiam UK, Okechukwu RJ 2015. Medicinal plants effectiveness against helminths of cattle, Journal of Applied Biosciences, 86, 7900-7917 Search in Google Scholar

28 Indu S, Pareek A, 2015. A Review: Growth and Physiological Adaptability of Sheep to Heat Stress under Semi –Arid Environment. International Journal of Emerging Trends in Science and Technology 2:3188-3198 http://dx.doi.org/10.18535/ijetst/v2i9.09 Search in Google Scholar

29 Rodrigues NEB, Zangeronimo MG, Fialho ET (2010) Adaptações fisiológicas de suínos sob estresse térmico. Re-vista Eletrônica Nutritime 7:1197-1211 Search in Google Scholar

30 Morris CJ, Garcia JI, Myers S, Yang JN, Trienekens N, Scheer F (2015) The human circadian system has a dominating role in causing the morning/evening difference in diet-induced thermogenesis. Obesity biology and integrated physiology 23:2053-2058 Search in Google Scholar

31 Piccione G, Caola G, Refinetti R (2003) Circadian rhythms of body temperature and liver function in fed and food-deprived goats. Comparative Biochemistry and Physiology Part A 134:563–572 Search in Google Scholar

32 Adegbeye MJ (2022) Impact of Chronomanagement on the performance of West African dwarf goats. PhD Thesis. Federal University of Technology Akure, Nigeria. Pg 1-237D’Alterio G, Casella S, Gatto M, Gianesella M, Piccione G, Morgante M 2011. Circadian rhythm of foot temperature assessed using infrared thermography in sheep Czech Journal of Animal Sciecne 56:293–300 Search in Google Scholar

33 Cuesta M, Boudreau P, Cermakian N, Boivin DB, (2017) Skin Temperature Rhythms in Humans Respond to Changes in the Timing of Sleep and Light. Journal Of Biological Rhythms 32:257–273 https://doi.org/10.1177/0748730417702974 Search in Google Scholar

34 Babar, Z.M., Azizi, W.M., Ichwan, S.J., Ahmed, Q.U., Azad, A.K. and Mawa, I., 2019. A simple method for extracting both active oily and water-soluble extract (WSE) from Nigella sativa (L.) seeds using a single solvent system. Natural product research, 33(15), pp.2266-2270. Search in Google Scholar

35 N. Marzougui, F. Guasmi, M. Mkaddem et al., “Assessment of Tunisian Trigonella foenum graecum diversity using seed vitamin B6, B1, B9 and C contents,” Journal of Food, Agriculture and Environment, vol. 7, no. 1, pp. 56–61, 2009 Search in Google Scholar

36 Servicio Meteorológico Nacional (SMN). Normales Climatológicas por Estado. 2020. Available online: https://smn.conagua.gob.mx/es/climatologia/informacion-climatologica/normales-climatologicas-por-estado Search in Google Scholar

37 Kibler H.H., 1964. Environmental physiology and shelter engineering. LXVII. Thermal effects of various temperature-humidity combinations on Holstein cattle as measured by eight physiological responses. Res. Bull. Missouri Agric. Exp. Station. 862. Search in Google Scholar

38 World Meteorological Organization (WMO). 1989. Available online: https://public.wmo.int/en Search in Google Scholar

39 SAS (Statistical Analysis System). Institute, Cary SAS. User’s Guide: Statistics, Version 9.0; SAS Institute: Cary, NC, USA. 2002 Search in Google Scholar