SZAKMAI - TUDOMÁNYOS ROVAT














            Larcher, S., & Yargeau, V. (2011). Biodegradation of sul- Mikkelsen L. H., 1999. A Physico-Chemical Approach
            famethoxazole by individual and mixed bacteria. App- to the Floc Strength Concept – with Dewatering Imp-
            lied Microbiology and Biotechnology, 91 (1), 211–218. lications. Thesis (PhD). Aalborg University.


            Lee, D. G., Zhao, F., Rezenom, Y. H., Russell, D. H.,  Moreira, F.C., Soler, J., Alpendurada, M.F., Boaventura,
            & Chu, K.-H. (2012). Biodegradation of triclosan by  R. A.R., Brillas, E., Vilar, V.J.P. (2016). Tertiary treatment
            a wastewater microorganism. Water Research, 46(13),  of a municipal wastewater toward pharmaceuticals
            4226–4234.                                       removal by chemical and electrochemical advanced
                                                             oxidation processes. Water Research 105, 251–263.
            Li, A . , Cai, R., Cui, D., Qiu, T., Pang, C., Yang, J., Ma,
            F., Ren, N., (2013). Characterization  and biodegra- Moreira, I. S. Bessa, V. S. Murgolo, S. , Piccirillo, C.
            dation kinetics of a new cold-adapted carbamazepi- Mascolo, G., & Castro, P. M. L. (2018). Biodegradation
            ne-degrading bacterium, Pseudomonas sp. CBZ-4. J.  of Diclofenac by the bacterial strain Labrys portu-
            Environ. Sci. 25, 2281-2290.                     calensis F11. Ecotoxicology and Environmental Safety,
                                                             152, 104–113.
            Luo, Y., Guo, W., Ngo, H. H., Nghiem, L. D., Hai, F.
            I., Zhang, J., Liang, S., Wang, X. C. (2014). A review  Moreira, I.S., Ribeiro, A .R. , Afonso, C. M. Tiritan, M.E.,
            on the occurrence of micropollutants in the aquatic  Castro, P.M.L., (2014). Enantioselective biodegrada-
            environment and their fate and removal during was- tion of fluoxetine by the bacterial strain Labrys portu-
            tewater treatment. Science of The Total Environment,  calensis F11. Chemosphere 111, 103–111.
            473-474, 619–641.
                                                             Murdoch, R. W., & Hay. A .G. (2005). Formation of ca-
            Maeng, S. K., Choi, B. G., Lee, K. T., & Song, K. G.  techols via removal of acid side chains from ibuprofen
            (2013). Influences of solid retention time, nitrification  and related aromatic acids. Applied and Environmen-
            and microbial activity on the attenuation of pharma- tal Microbiology, 71(10), 6121–6125.
            ceuticals and estrogens in membrane bioreactors.
            Water Research, 47 (9), 3151–3162.               Müller, E., Schüssler, W., Horn, H., & Lemmer, H. (2013).
                                                             Aerobic biodegradation of the sulfonamide antibio-
            Marco-Urrea, E., Pérez-Trujillo, M., Cruz-Morató, C.,  tic sulfamethoxazole by activated sludge applied as
            Caminal, G., & Vicent, T. (2010). Degradation of the  co-substrate and sole carbon and nitrogen source.
            drug sodium diclofenac by Trametes versicolor pel- Chemosphere, 92(8), 969–978.
            lets and identification of some intermediates by NMR.
            Journal of Hazardous Materials, 176(1-3), 836–842.  O’Grady, D., Evangelista, S., & Yargeau, V. (2009). Re-
                                                             moval of Aqueous 17α-Ethinylestradiol by Rhodococ-
            Márialigeti, K. (szerk), Borsodi, A.  Felföldi T. , Jáger, K.,  cus Species. Environmental Engineering Science, 26
            Makk, J., Romsics, Cs., Tóth, E., Bánfi, R., Pohner, Zs.  (9), 1393–1400.
            (2013). Bevezetés a prokarióták világába. ELTE



                                                                                                           35