As a result of increased interest in the production of plant-based drugs for the treatment of many diseases has become a significant reason why people have become more coversant in the use of traditional medicine for the treatment of mild and serious illness. Due to increase in the thrust for the production of plant-based drugs, this present study was carried out to compare the phytochemical constituents and antioxidant potencies of acetone, methanol and aqueous leaf extracts of Acalypha wilkesiana collected from Kaura Namoda Botanical Garden in Zamfara State-Nigeria. The antioxidant activities was evaluated using various assays; The total phenolic content of aqueous, methanol and acetone leaf extract were 15.58 0.66 mg GAE/g, 14.10 2.17 mg GAE/g and 8.70 0.01 mg GAE/g respectively. Total flavonol contents; 207.10 11.53 mg QE/g, 196.08 5.53 mg QE/g and 112.04 8.27 mg QE/g respectively. Total flavonoid contents; 240.99 9.50 mg QE/g, 252.52 3.73 mg QE/g and 123.88 5.58 mg QE/g respectively. FRAP values were 679.14 0.45 mmol/g, 611.90 7.09 mmol/g and 292.07 11.38mmol/g respectively. ABTS activity of aqueous, methanol and acetone leaf extract were 24.30 5.86 mg AAE/g, 14.49 1.02 mg AAE/g and 7.00 0.57 mg AAE/g respectively, methanol leaf extract had the highest percentage DPPH Inhibition value of 42.64 5.13, followed by aqueous (31.77 4.08) at 0.25mg/ml while aqueous had the highest (52.63 0.67), followed by methanol extract (44.80 2.80) at 0.50mg/ml. Aqueous extract had the highest percentage inhibition of Nitric Oxide with a value of 59.74 1.30, followed by methanol extract (46.11 2.54) at 0.25mg/ml. inhibition for aqueous was also highest at 0.5 mg/ml. Aqueous extract had the highest percentage lipid peroxidation inhibition value of 22.66 2.93, followed by methanol leaf extract with the value of 18.89 0.80 while at 0.50mg/ml methanol leaf extract had the highest percentage inhibition of lipid peroxidation (39.42 3.10), followed by aqueous leaf extract with the value of 31.48 1.61. The results showed that aqueous and methanol leaf extract of Acalypha wilkesiana displayed potent antioxidant effects with the aqueous having an edge. This present study therefore supports the view that Acalypha wilkesiana can be used in the management of oxidative stress and other related diseases.

Constituent, Oxidative Potencies, Acetone, Methanol, Aqueous leaf extracts, Acalypha Wilkesiana

Adesina SK, Idowu O, Ogundaini AO, Oladimeji H, Olubgade TA, Onawunmi GO, & Pais M (2020). Antimicrobial constituents of the leaves of Acalypha wilkesiana and Acalypha Hispida. Phytotherapy Research. 14: 371-374.

Adesina SK, Oguntimehin BJ, & Akinwusi DD (2018). Phytochemical and biological examination of the leaves of Acalypha wilkesiana. Journal of Crude Drug Research. 18: 45-48.

Akinde BE & Odeyemi OO (2018). Extraction and microbiological evaluation of the oils from leaves of Acalyphawilkesiana. Nigerian Medical Journal. 17: 163-165.

Alade PJ & Irobi ON (2012). Anti-microbial activities of crude leaf extracts of Acalypha wilkesiana. Journal of Ethnopharmacology. 39: 171 -174.

Ames BN, Shigenaga MK, & Hagen TM (2013). Oxidants, antioxidants, and the degenerative diseases of aging. Proceedings of the National Academy of Sciences. 90, 7915-7922.

Andreasen MF, Landbo AK, Christensen LP, Hansen A, & Meyer AS (2019). Antioxidant effects of phenolic rye (Secalecereale L.) extracts, monomeric hydroxycinnamates, and ferulic acid dehydrodimers on human low-density lipoproteins. Journal of Agricultural and Food chemistry. 47:1453-1459.

Ayoola GA, Folawewo AD, Adesegun SA, Abioro OO, Adepoju-Bello AA, & Coker HAB (2018). Phytochemical and antioxidant screening of some plants of Apocynaceae from South West Nigeria. African Journal of Plant Science. 2(9):124-128.

Benzie IFF & Strain JJ (2016). The ferric reducing ability of plasma (FRAP) as a measure of antioxidant power: The FRAP assay. Analytical Biochemistry. 239: 70-76.

Bhattacharya S (2015). Reactive Oxygen Species and Cellular Defense System. Free Radicals in Human Health and Disease. 17-29

Brand M (2020). The sites and topology of mitochondrial superoxide production. Exp. Gerontol.45, 466472.

Callow RK (2016). Steroids proc royal, soc. London Series A. 157:194. Chance, B., Sies, H. and Boveris, A. (2019). Hydroperoxide metabolism in mammalian organs.Physiological Reviews. 59:527-605