DSpace Community:http://hdl.handle.net/2440/102013-05-22T03:24:46Z2013-05-22T03:24:46ZA novel approach to exploit indigenous mining algal-microbes in a photo-rotating biological contactor for heavy metal removal from acid mine drainageOrandi, SanazLewis, David MiltonEslami, AfsarMohebbi, Alihttp://hdl.handle.net/2440/773372013-05-01T05:30:09Z2012-12-31T13:30:00ZTitle: A novel approach to exploit indigenous mining algal-microbes in a photo-rotating biological contactor for heavy metal removal from acid mine drainage
Author: Orandi, Sanaz; Lewis, David Milton; Eslami, Afsar; Mohebbi, Ali
Abstract: Extremophilic acidic microbial biofilms, that thrive in acidic mine drainages (AMD), are well known as natural metal-resistant biosorbents for removing heavy metals throught active and passive cellular functions. To benefit from the resistant and cleansing nature of these microorganisms and to develop a system applicable to mining sites, an indigenous AMD biofilm was immobilized in a laboratory scale photo-rotating biological contactor (PRBC) to investigate its heavy metal removal potential from AMD. The microbial consortium used for biofilm development contained filamentous green micro-algae, bacteria, fungi and yeasts, collected from AMD and the Sarcheshmeh copper mine in Iran. The PRBC was operated with synthesised AMD representing the multi-ion and acidic composition of the wastewater (composing 18 elements with a pH of 3.5+0.3) from which the microbial consortium was collected. Light, nutrient dosing and rotational speeds were optimised to encourage biofilm development. Electron microscopy was used to monitor the development of the algal-microbial biofilm on the PROBC discs over a 60 day batch mode operation. The PRBC was then run continuously with a 24 h hydraulic residence time (HRT) over a ten week period. The weekly average of water analysis results demonstrated the ability for the algal-microbial biofilm to remove 15-50% of various metals in the order of Cu> Ni> Mn> Zn> Sb> Cr> Co> Al. These results clearly indicate the significant potential for indigenous AMD biofilm to be exploited within a PRBC for AMD treatment.2012-12-31T13:30:00ZApplication of artificial neural networks for formulation and modeling of dye adsorption onto multiwalled carbon nanotubesShahryari, ZohreMohebbi, A. R.Goharrizi, Ataallah SoltaniForghani, Amir Ahmadhttp://hdl.handle.net/2440/772552013-04-29T04:30:26Z2011-12-31T13:30:00ZTitle: Application of artificial neural networks for formulation and modeling of dye adsorption onto multiwalled carbon nanotubes
Author: Shahryari, Zohre; Mohebbi, A. R.; Goharrizi, Ataallah Soltani; Forghani, Amir Ahmad2011-12-31T13:30:00ZBlood-brain barrier: a real obstacle for therapeutics Response - authors responseLosic, Dusanhttp://hdl.handle.net/2440/772432013-05-10T00:27:22Z2011-12-31T13:30:00ZTitle: Blood-brain barrier: a real obstacle for therapeutics Response - authors response
Author: Losic, Dusan
Description: Author Response published in conjunction with Letter to the Editor. Response only appears when viewing 'Full text' or 'PDF'2011-12-31T13:30:00ZEnzyme-responsive controlled release of covalently bound prodrug from functional mesoporous silica nanospheresPopat, AmiraliRoss, Benjamin P.Liu, JianJambhrunkar, SiddharthKleitz, FreddyQiao, Shizhanghttp://hdl.handle.net/2440/770022013-04-17T02:30:32Z2011-12-31T13:30:00ZTitle: Enzyme-responsive controlled release of covalently bound prodrug from functional mesoporous silica nanospheres
Author: Popat, Amirali; Ross, Benjamin P.; Liu, Jian; Jambhrunkar, Siddharth; Kleitz, Freddy; Qiao, Shizhang2011-12-31T13:30:00Z