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Highly tuned cobalt-doped MnO sub(2) nanozyme as remarkably efficient uricase mimic

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dc.contributor.author Parmekar, M.V.
dc.contributor.author Salker, A.V.
dc.date.accessioned 2019-08-08T04:27:41Z
dc.date.available 2019-08-08T04:27:41Z
dc.date.issued 2019
dc.identifier.citation Applied Nanoscience. 10(1); 2020; 317-328. en_US
dc.identifier.uri https://doi.org/10.1007/s13204-019-01118-x
dc.identifier.uri http://irgu.unigoa.ac.in/drs/handle/unigoa/5812
dc.description.abstract Gouty arthritis is a commonly occurring metabolic disorder in adult humans. It is caused by accumulation of uric acid (UA) in the joints owing to lack of any enzyme like uricase, which can metabolise excess UA in the human body. In this work, we propose a solution for the same. After testing the oxidase-like activity of Co-doped MnO sub(2) using 3,3',5,5'-tetramethylbenzidine (TMB), as less as 50 microgram mL sup(-1) of this catalyst was found to readily oxidise and completely degrade a 50 micro M uric acid solution at 37 degrees C within 4 h (pH 7.4). The rate of the reaction found to be 1.208 x 10 sup(-4) s sup(-1) at this temperature. The result clearly indicates better activity of these nanoparticles over bacterial uricase enzyme as the activation energy of the reaction decreased from the reported value of 53 to 43 kJ mol sup(-1) in this work. This is by far the lowest reported Eact by any enzyme mimic for uricase. Composed of two bio-relevant metals namely Mn and Co, the nanozyme is economical as well as safe to use for treatment of gout. The nanozyme could be successfully recycled four times with no loss in the oxidase-like activity and proved to be quite stable in the employed conditions as the metal content and morphology were retained even after reuse. Generation of in situ singlet oxygen/superperoxide radical-type species was another striking feature of the employed nanozyme. LC-MS data of the degraded products further gave insights on the pathway followed for degradation over the nanozyme. Overall, a bio-relevant as well as cost effective alternate for the treatment of gout envisaged in the current study. en_US
dc.publisher Springer en_US
dc.subject Chemistry en_US
dc.title Highly tuned cobalt-doped MnO sub(2) nanozyme as remarkably efficient uricase mimic en_US
dc.type Journal article en_US
dc.identifier.impf y


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