1. Maras-Vanlioglu F.G, Yaman H, Kayacetin F (2020) Genetic diversity analysis of some species in Brassicaceae family with ISSR markers. Biotech Studies 29:38-46.
2. Mollova S, Fidan H, Antonova D, Bozhilov D, Stanev S, Kostova I, Stoyanova A (2020) Chemical composition and antimicrobial and antioxidant activity of Helichrysum italicum (Roth) G. Don subspecies essential oils. Turk J Agric For 44: 371-378.
3. Subasi I (2020) Seed fatty acid compositions and chemotaxonomy of wild Crambe (Brassicaceae) taxa in Turkey. Turk J Agric For 44: 662-670
4. Erdemir A (2021) Anti-proliferative and apoptosis inducing activity of Calophyllum inophyllum L. oil extracts on C6 glioma cell line. Biotech Studies 30:1-6.
5. Yusuf AK, Mamza PAP, Ahmed AS, Agunwa U (2015) Extraction and characterization of castor seed oil from wild Ricinus communis Linn. Int J Sci Environ 4 (5): 1392-1404.
6. Fadhil AB, Al-Tikrity ETB, Albadree MA (2017) Biodiesel production from mixed non-edible oils, castor seed oil and waste fish oil. Fuel 210: 721-728.
7. Scarpa A, Guerci A (1982) Various uses of the castor oil plant (Ricinus communis L.) a Review. J Ethnopharmacol 5 (2):117-137.
8. Akande TO, Odunsi AA, Akinfala EO (2016) A review of nutritional and toxicological implications of castor bean (Ricinus communis L.) meal in animal feeding systems. J Anim Physiol Anim Nutr 1: 201-210.
9. Arunkumar M, Kannan M, Murali G (2019) Experimental studies on engine performance and emission characteristics using castor biodiesel as fuel in CI engine. Renew Energy 131: 737-744.
10. Zuleta EC, Rios LA, Benjumea PN (2012) Oxidative stability and cold flow behavior of Palm, Sacha-inchi, Jatropha and Castor oil biodiesel blends. Fuel Process Technol 102: 96-11. Islam MS, Ahmed AS, Islam A, Abdul Aziz S, Xian LC, Mridha M (2014) Study on emission and performance of diesel engine using castor biodiesel. J Chem 2014:451526.
12. Bueno AV, Pereira MPB, de Oliveira Pontes JV, de Luna FMT, Cavalcante CL (2017) Performance and emissions characteristics of castor oil biodiesel fuel blends. Appl Therm Eng 125: 559-566.
13. Jeong GT, Park DH (2009) Optimization of biodiesel production from castor oil using response surface methodology. Appl Biochem Biotechnol 156: 1-11.
14. Nicory IMC, de Carvalho GGP, Ribeiro OL, Silva RR. Tosto MSL, Costa-Lopes LS, Souza FNC, de Oliveira Nascimento C (2015) Ingestive behavior of lambs fed diets containing castor seed meal. Trop Anim Health Prod 47 (5): 939-944.
15. Foster JT, Allan GJ, Chan AP, Rabinowicz PD, Ravel J, Jackson PJ, Keim P (2010) Single nucleotide polymorphisms for assessing genetic diversity in castor bean (Ricinus communis). BMC Plant Biol 10 (1): 13.
16. Yousaf MM, Hussain M, Shah MJ, Ahmed B, Zeshan M, Raza MM, Ali K (2018) Yield response of castor (Ricinus communis L.) to NPK fertilizers under arid climatic conditions. Pak J Agric Res 31 (2): 180-185.
17. Arif M, Khurshid H, Siddiqui SU, Jatoi SA, Jan SA, Ilyas M, Khan SA, Khan A, Ibrahim MI, Saleem N, Ghafoor A (2015) Estimating spatial population structure through quantification of oil content and phenotypic diversity in Pakistani castor bean (Ricinus communis L.) germplasm. Sci Technol Dev 34 (3): 147-154.
18. Ruiz Olivares A, Carrillo-González R, González-Chávez M del CA, Soto Hernández R M (2013) Potential of Castor bean (Ricinus communis l.) for phytoremediation of mine tailings and oil production. J Environ Manage 114: 316-323.
19. Román-Figueroa C, Cea M, Paneque M, González ME (2020) Oil content and fatty acid composition in Castor bean naturalized accessions under Mediterranean conditions in Chile. Agronomy 10 (8): 1145.
20. Abolfazl A, Nasrin F, Habib S, Saeid H (2011) The effect of climatic factors on the production and quality of castor oil. Nat Sci 9 (4): 15-19.
21. Muraguri S, Xu W, Chapman M, Muchugi A, Oluwaniyi A, Oyebanji O, Liu A (2020) Intraspecific variation within Castor bean (Ricinus communis l.) based on chloroplast genomes. Ind Crops Prod 155: 112779.
22. Koutroubas SD, Papakosta DK, Doitsinis A (1999) Adaptation and yielding ability of Castor plant (Ricinus communis l.) genotypes in a Mediterranean climate. Eur J Agron 11 (3-4): 227–237.
23. FAO. Food and agricultural organization.
24. Rodríguez-Leyes EA, Canavaciolo VLG, Delange DM, Enríquez ARS, Fajardo YA (2007) Fatty acid composition and oil yield in fruits of five Arecaceae species grown in Cuba. J Am Oil Chem Soc 84 (8): 765-767.
25. Ergun Z, Bozkurt T (2020) Determination of fatty acid composition and antioxidant activity of fig seed oil. Int J Agric Nat Sci 13 (2): 101-107.
26. Zarifikhosroshahi M, Ergun Z (2021) The effect of storage temperature on the composition of fatty acids in crimson sweet (Citrullus lanatus var. lanatus) watermelon cultivar seeds. J Inst Sci Technol 11 (2): 839-845.
27. Ilhan G, Gundogdu M, Karlović K, Židovec V, Vokurka A, Ercisli S (2021) Main agro-morphological and biochemical berry characteristics of wild-grown sea buckthorn (Hippophae rhamnoides L. ssp. Caucasica Rousi) genotypes in Turkey. Sustainability 13 (3):1198.
28. Beyhan O, Ozcan A, Ozcan H, Kafkas E, Kafkas S, Sutyemez M, Ercisli S (2017) Fat, fatty acids and tocopherol content of several walnut genotypes. Not Bot Horti Agrobot Cluj-Napoca 45 (2): 437-441.
29. Ercisli S, Orhan E (2008) Fatty acid composition of seeds of yellow, red, and black colored Prunus mahaleb fruits in Turkey. Chem Nat Compd 44 (1): 87-89.
30. Binder RG, Applewhite TH, Kohler GO, Goldblatt LA (1962) Chromatographie analysis of seed oils. fatty acid composition of Castor oil. J Am Oil Chem Soc 39 (12); 513-517.
31. Canoira L, García Galeán J, Alcántara R, Lapuerta M, García-Contreras R. Fatty acid methyl esters (FAMEs) from Castor oil: Production process assessment and synergistic effects in its properties. Renew Energy 35 (1): 208-217.
32. Salimon J, Mohd Noor DA, Nazrizawati AT, Mohd Firdaus MY, Noraishah A (2010) Fatty acid composition and physicochemical properties of Malaysian Castor bean Ricinus communis L. seed oil. Sains Malays 39 (5): 761-764.
33. Sreenivasan B, Kamath NR, Kane JG. Studies on Castor oil (1956) I. Fatty acid composition of Castor oil. J Am Oil Chem Soc 33 (2): 61-66.
34. Ercisli S, Agar G, Orhan E, Yildirim N, Hizarci Y (2007) Interspecific variability of rapd and fatty acid composition of some pomegranate cultivars (Punica granatum L.) growing in Southern Anatolia Region in Turkey. Biochem Syst Ecol 35 (11): 764-769.
35. Serce S, Ercisli S, Sengul M, Gunduz K, Orhan E (2010) Antioxidant activities and fatty acid composition of wild grown Myrtle (Myrtus communis L.) fruits. Pharmacogn Mag 6 (21): 9–12.
36. Guney M, Oz AT, Kafkas E (2015) Comparison of lipids, fatty acids and volatile compounds of various kumquat species using HS/GC/MS/FID techniques. J Sci Food Agric 95 (6): 1268-1273.
37. Guney M (2020) Determination of fatty acid profile and antioxidant activity of rosehip seeds from Turkey. Int J Agric Environ Food Sci 4 (1): 81-86.
38. Ilyasoǧlu H (2014) Characterization of rosehip (Rosa canina L.) seed and seed oil. Int J Food Prop 17 (7): 1591-1598.
39. Stearns EM, Morton WT (1975) Biosynthesis of fatty acids from acetate in soybean suspension cultures. Lipids 10 (10): 597-601.
40. Stearns EM, Morton WT (1975) Effects of growth regulators on fatty acids of soybean suspension cultures. Phytochemistry 14 (3): 619-622.
41. Hafez RM, Mohammed AAY, El-Naby AERMA, Tolba AEA, Khalifa EYM, Hamed H M, Abdullah MMK, Ahmed MMF, Hekal MS, Ali DHA (2019) Changes in the profiling of fatty acids of Glycine max L. (Soybean) callus after mutagen treatments. Egypt J Bot 59 (3): 679-694.
42. Koufan M, Belkoura I, Mazri MA, Amarraque A, Essatte A, Elhorri H, Zaddoug F, Alaoui T (2020) Determination of antioxidant activity, total phenolics and fatty acids in essential oils and other extracts from callus culture, seeds and leaves of Argania spinosa (L.) skeels. Plant Cell Tissue Organ Cult 141 (1): 217-227.
43. Hernandez LR, Mendiola MAR, Castro CA, Gutiérrez-Miceli FA (2015) Effect of plant growth regulators on fatty acids composition in Jatropha curcas L. callus culture. J Oleo Sci 64 (3): 325-330.
44. Aly MAM, Amer EA, Al-Zayadneh WA, Eldin AEN (2008) Growth regulators influence the fatty acid profiles of in vitro induced Jojoba somatic embryos. Plant Cell Tissue Organ Cult 93 (1): 107-114.
45. Murashige T, Skoog FA (1962) Revised medium for rapid growth and bioassays with tobacco tissue cultures. Physiol Plant 15 (3): 473-497.
46. Perdomo FA, Acosta-Osorio AA, Herrera G, Vasco-Leal JF, Mosquera-Artamonov JD, Millan-Malo B, Rodriguez-Garcia ME (2013) Physicochemical characterization of seven Mexican Ricinus communis L. seeds & oil contents. Biomass Bioenerg 48: 17-24.
47. Demirtas I, Pelvan E, Ozdemir IS, Alasalvar C, Ertas E (2013) Lipid characteristics and phenolics of native grape seed oils grown in Turkey. Eur J Lipid Sci Technol 115 (6): 641-647.
48. Kohler U, Luniak M (2005) Data Inspection Using Biplots. Stata J 5 (2): 208-223.
49. Dabuwar Benjamin E, Adamu Ishaku G, Andrew Peingurta F, Samuel Afolabi A (2019) Callus culture for the production of therapeutic compounds. Am J Plant Biol 4 (4): 76-84.
50. Aftab F, Akram S, Iqbal J (2008) Estimation of fixed oils from various explants and in vitro callus cultures of Jojoba (Simmondsia chinensis). Pak J Bot 40 (4): 1467-1471.
51. Murthy HN, Lee EJ, Paek KY (2014) Production of secondary metabolites from cell and organ cultures: strategies and approaches for biomass improvement and metabolite accumulation. Plant Cell Tissue Organ Cult 16: 1-16.
52. Dörnenburg H, Knorr D (1995) Strategies for the improvement of secondary metabolite production in plant cell cultures. Enzyme Microb Technol 1: 674–684.
53. da Luz Costa J, da Silva ALL, Bier MCJ, Brondani GE, Gollo AL, Letti LAJ, Erasmo E AL, Soccol CR (2015) Callus growth kinetics of physic nut (Jatropha curcas l.) and content of fatty acids from crude oil obtained in vitro. Appl Biochem Biotechnol 176 (3): 892-902.
54.Liu JY, Qiu W, Song YM (2016) Stimulatory effect of auxins on the growth and lipid productivity of Clorella pyrenoidosa and Scenedesmus quadricauda. Algal Res 18:273-280.
55. Park HY, Saini RK, Gopal J, Keum Y-S, Kim DH, Lee O, Sivanesan I (2017) Micropropagation and subsequent enrichment of carotenoids, fatty acids, and tocopherol contents in Sedum dasyphyllum L. Front Chem 5:77.