FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3209714807> ?p ?o ?g. }

• W3209714807 endingPage "075702" @default.
• W3209714807 startingPage "075702" @default.
• W3209714807 abstract "This study focuses on the adsorption kinetics of four highly potent sex hormones (estrone (E1), 17β-estradiol (E2), 17α-ethinylestradiol (EE2), and estriol (E3)), present in water reservoirs, which are considered a major cause of fish feminization, low sperm count in males, breast and ovarian cancer in females induced by hormonal imbalance. Herein, electrospun polymeric nanostructures were produced from cellulose acetate, polyamide, polyethersulfone, polyurethanes (918 and elastollan), and polyacrylonitrile (PAN) to simultaneously adsorbing these estrogenic hormones in a single step process and to compare their performance. These nanofibers possessed an average fiber diameter in the range 174-330 nm and their specific surface area ranged between 10.2 and 20.9 m2g-1. The adsorption-desorption process was investigated in four cycles to determine the effective reusability of the adsorption systems. A one-step high-performance liquid chromatography technique was developed to detect and quantify concurrently each hormone present in the solution. Experimental data were obtained to determine the adsorption kinetics by applying pseudo-first-order, pseudo-second-order and intraparticle diffusion models. Findings showed that E1, E2 and EE2 best fitted pseudo-second-order kinetics, while E3 followed pseudo-first-order kinetics. It was found that polyurethane Elastollan nanofibers had maximum adsorption capacities of 0.801, 0.590, 0.736 and 0.382 mg g-1for E1, E2, EE2 and E3, respectively. In addition, the results revealed that polyurethane Elastollan nanofibers had the highest percentage efficiency of estrogens removal at ∼58.9% due to its strong hydrogen bonding with estrogenic hormones, while the least removal efficiency for PAN at ∼35.1%. Consecutive adsorption-desorption cycles demonstrated that polyurethane maintained the best efficiency, even after being repeatedly used four times compared to the other polymers. Overall, the findings indicate that all the studied nanostructures have the potential to be effective adsorbents for concurrently eradicating such estrogens from the environment." @default.
• W3209714807 created "2021-11-08" @default.
• W3209714807 creator A5024312648 @default.
• W3209714807 creator A5038437636 @default.
• W3209714807 creator A5055639473 @default.
• W3209714807 creator A5083762931 @default.
• W3209714807 creator A5087627905 @default.
• W3209714807 date "2021-11-24" @default.
• W3209714807 modified "2023-10-18" @default.
• W3209714807 title "The adsorption, kinetics, and interaction mechanisms of various types of estrogen on electrospun polymeric nanofiber membranes" @default.
• W3209714807 cites W1056266460 @default.
• W3209714807 cites W1966775883 @default.
• W3209714807 cites W1968949301 @default.
• W3209714807 cites W1970490287 @default.
• W3209714807 cites W1982381284 @default.
• W3209714807 cites W1987929564 @default.
• W3209714807 cites W1990411732 @default.
• W3209714807 cites W1996974464 @default.
• W3209714807 cites W1997604877 @default.
• W3209714807 cites W2004428541 @default.
• W3209714807 cites W2005387688 @default.
• W3209714807 cites W2009089307 @default.
• W3209714807 cites W2012270576 @default.
• W3209714807 cites W2012728247 @default.
• W3209714807 cites W2013300731 @default.
• W3209714807 cites W2013736717 @default.
• W3209714807 cites W2014939665 @default.
• W3209714807 cites W2021560672 @default.
• W3209714807 cites W2027019299 @default.
• W3209714807 cites W2031611525 @default.
• W3209714807 cites W2032395525 @default.
• W3209714807 cites W2035236424 @default.
• W3209714807 cites W2045402873 @default.
• W3209714807 cites W2046034814 @default.
• W3209714807 cites W2067709777 @default.
• W3209714807 cites W2070657130 @default.
• W3209714807 cites W2072543965 @default.
• W3209714807 cites W2073624534 @default.
• W3209714807 cites W2074996979 @default.
• W3209714807 cites W2075123288 @default.
• W3209714807 cites W2076076000 @default.
• W3209714807 cites W2076288335 @default.
• W3209714807 cites W2083299916 @default.
• W3209714807 cites W2089944173 @default.
• W3209714807 cites W2096886340 @default.
• W3209714807 cites W2098225839 @default.
• W3209714807 cites W2102546285 @default.
• W3209714807 cites W2106727463 @default.
• W3209714807 cites W2115554139 @default.
• W3209714807 cites W2125559399 @default.
• W3209714807 cites W2131566852 @default.
• W3209714807 cites W2141815150 @default.
• W3209714807 cites W2142593764 @default.
• W3209714807 cites W2148330698 @default.
• W3209714807 cites W2149381982 @default.
• W3209714807 cites W2153599795 @default.
• W3209714807 cites W2155479866 @default.
• W3209714807 cites W2165463664 @default.
• W3209714807 cites W2169380284 @default.
• W3209714807 cites W2219400978 @default.
• W3209714807 cites W2326384734 @default.
• W3209714807 cites W2332232047 @default.
• W3209714807 cites W2548324093 @default.
• W3209714807 cites W2555874147 @default.
• W3209714807 cites W2557640813 @default.
• W3209714807 cites W2562578972 @default.
• W3209714807 cites W2570066282 @default.
• W3209714807 cites W2594328154 @default.
• W3209714807 cites W2610350104 @default.
• W3209714807 cites W2763605650 @default.
• W3209714807 cites W2765491052 @default.
• W3209714807 cites W2768178949 @default.
• W3209714807 cites W2776469454 @default.
• W3209714807 cites W2781540090 @default.
• W3209714807 cites W2804967355 @default.
• W3209714807 cites W2885824744 @default.
• W3209714807 cites W2888257964 @default.
• W3209714807 cites W2906552563 @default.
• W3209714807 cites W2915941709 @default.
• W3209714807 cites W2917142815 @default.
• W3209714807 cites W2987009298 @default.
• W3209714807 cites W3114091391 @default.
• W3209714807 cites W3128242912 @default.
• W3209714807 cites W3134363376 @default.
• W3209714807 cites W3135748498 @default.
• W3209714807 doi "https://doi.org/10.1088/1361-6528/ac357b" @default.
• W3209714807 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/34727533" @default.
• W3209714807 hasPublicationYear "2021" @default.
• W3209714807 type Work @default.
• W3209714807 sameAs 3209714807 @default.
• W3209714807 citedByCount "4" @default.
• W3209714807 countsByYear W32097148072022 @default.
• W3209714807 crossrefType "journal-article" @default.
• W3209714807 hasAuthorship W3209714807A5024312648 @default.
• W3209714807 hasAuthorship W3209714807A5038437636 @default.
• W3209714807 hasAuthorship W3209714807A5055639473 @default.
• W3209714807 hasAuthorship W3209714807A5083762931 @default.
• W3209714807 hasAuthorship W3209714807A5087627905 @default.

• next