Federica Spina

Scale-up of a bioprocess for textile wastewater treatment using Bjerkandera adusta

Twelve basidiomycetes were investigated for their ability to degrade 13 industrial dyes and to treat four model wastewaters from textile and tannery industry, defined on the basis of discharged amounts, economic relevance and representativeness of chemical structures of the contained dyes. The best degradation yields were recorded for one strain of Bjerkandera adusta able to completely decolourise most of the dyes and to decolourise and detoxify three simulated wastewaters, showing a significant physiological versatility which is very useful for application purposes. The effects of different nutrient sources were investigated in order to optimize the yields of decolourisation and detoxification. Manganese-peroxidase and manganese-independent peroxidase were the only recorded enzymatic activities. In order to evaluate its true bioremediation potential, this strain was packed in a fixed-bed bioreactor, for treatment of large volumes of a real wastewater. The fungus resulted effective during 10 cycles of decolourisation, remaining active for a very long period, in non-sterile conditions.

Decolourisation and detoxification in the fungal treatment of textile wastewaters from dyeing processes

In this study a selected fungal strain, Bjerkandera adusta (Willdenow) P. Karsten MUT 3060, was tested in different culture conditions to assess its real potential for bioremediation of textile wastewaters in terms of both decolourisation and detoxification. The fungus efficiently decolourised (colour removal up to 96%) four simulated wastewaters that mimic the recalcitrance of real ones for pH values, concentration of dyes, additives and salts. In the culture condition with the lowest N content, the decolourisation was coupled with an important detoxification of two simulated effluents, underlining the important influence of the cultural medium composition not only on the degradation but also on the detoxification of industrial wastes. In the other cases, despite an extensive decolourisation, no detoxification was observed. The fungus was further tested against a real effluent, collected from a wastewater treatment plant before and after the tertiary treatment (ozonation) to compare the two technologies in terms of chemical and toxicological parameters. The fungal treatment, although less efficient than ozonation, caused a good decolourisation of the effluent, with colour values within the threshold limits of the Italian law; both the fungal and the ozone treatment caused a detoxification, but only towards one of the three organisms used for the ecotoxicological tests. These results underline the crucial importance of the ecotoxicological analysis in assessing the applicability of a wastewater treatment.

Integrated fungal biomass and activated sludge treatment for textile wastewaters bioremediation.

A combined biological process was investigated for effective textile wastewater treatment. The process consisted of a first step performed by selected fungal biomasses, mainly devoted to the effluent decolourisation, and of a subsequent stage by means of activated sludge, in order to reduce the remaining COD and toxicity. In particular, the treatment with Trametes pubescens MUT 2400, selected over nine strains, achieved very good results in respect to all parameters. The final scale-up phase in a moving bed bioreactor with the supported biomass of the fungus allowed to verify the effectiveness of the treatment with high volumes. Despite promising results, further steps must be taken in order to optimize the use of these biomasses for a full exploitation of their oxidative potential in textile wastewater treatment.

Oestrogenic activity of a textile industrial wastewater treatment plant effluent evaluated by the E-screen test and MELN gene-reporter luciferase assay.

This study quantified the biological oestrogenic activity in the effluent of a textile industrial wastewater treatment plant (IWWTP) in northwestern Italy. Samples of the IWWTP effluent were collected monthly, both before and after tertiary treatment (ozonation). After solid phase extraction, all samples were subjected to two in vitro tests of total estrogenic activity, the human breast cancer cell line (MCF-7 BUS) proliferation assay, or E-screen test, and the luciferase-transfected human breast cancer cell line (MELN) gene-reporter assay, to measure the 17β-oestradiol equivalent quantity (EEQ). In the E-screen test, the mean EEQ values were 2.35±1.68 ng/L pre-ozonation and 0.72±0.58 ng/L post-ozonation; in the MELN gene-reporter luciferase assay, the mean EEQ values were 4.18±3.54 ng/L pre-ozonation and 2.53±2.48 ng/L post-ozonation. These results suggest that the post-ozonation IWWTP effluent had a lower oestrogenic activity (simple paired t-tests, p<0.05). The average reduction of estrogenic activity of IWWTP effluent after ozonation was 67±26% and 52±27% as measured by E-screen test and MELN gene-reporter luciferase assay, respectively. There was a positive and significant correlation between the two tests (Rho S=0.650, p=0.022). This study indicates that the environmental risk is low because oestrogenic substances are deposited into the river via IWWTP at concentrations lower than those at which chronic exposure has been reported to affect the endocrine system of living organisms.

The culturable mycobiota of a Mediterranean marine site after an oil spill: isolation, identification and potential application in bioremediation

Bioremediation of marine environment could be the response to oil spills threats. In the present study the fungal community from a Mediterranean marine site chronically interested by oil spills was investigated. Sixty-seven taxa were isolated from water sample and 17 from sediments; for many of the identified species is the first report in seawater and sediments, respectively. The growth of 25% of the fungal isolates was stimulated by crude oil as sole carbon source. Four strains were selected to screen hydrocarbons degradation using the 2,6-dichlorophenol indophenol (DCPIP) colorimetric assay. A. terreus MUT 271, T. harzianum MUT 290 and P. citreonigrum MUT 267 displayed a high decolorization percentage (DP≥68%). A. terreus displayed also the highest decreases of hydrocarbons compounds (up to 40%) quantified by gas-chromatography analysis. These results suggest that the selected fungi could represent potential bioremediation agents with strong crude oil degradative capabilities.

Effective Biological Treatment of Landfill Leachates by Means of Selected White Rot Fungi

In the present study, autochthonous and allochthonous fungal strains were tested towards landfill leachate. The efficacy of the treatment was monitored following the decolourisation percentage, the chemical oxygen demand and the toxicity. Among the tested strains, Porostereum spadiceum showed the best activity (40 % of decolourisation in one week). Fungal treatment showed a complete spectrum of action, being able also to significantly reduce the wastewaters toxicity.

Biological treatment of industrial wastewaters: a fungal approach

Treatment of industrial wastewaters represents an actual and spread topic. In fact, the in-use techniques are not able to completely degrade all the pollutants, present in the effluents. At the moment, other approaches are under investigation, but they often have some drawbacks in terms of economical and environmental sustainability. A strain of Bjerkandera adusta MUT 2295, previously selected for its capability to degrade several industrial model dyes, has been tested towards real industrial wastewaters, coming from textile and pharmaceutical industries. The efficacy of the treatment was monitored, following the decolourisation percentage (DP) and the modification of other parameters as the chemical oxygen demand (COD). The effect of the fungal immobilisation on 4 inert supports was investigated in order to select the best one in terms of biomass production and enzymatic activity. The efficiency of the immobilized biomass was assessed toward a textile effluent, comparing it with a freecell treatment.

A Scaling-up Issue: The Optimal Bioreactor Configuration for Effective Fungal Treatment of Textile Wastewaters

A Scaling-up Issue: The Optimal Bioreactor Configuration for Effective Fungal Treatment of Textile Wastewaters / Spina F.; Romagnolo A.; Prigione V.; Tigini V.; Varese G.C.. In: CHEMICAL ENGINEERING TRANSACTIONS. ISSN 22839216. ELETTRONICO. 38(2014), pp. 37-42. Original Citation: A Scaling-up Issue: The Optimal Bioreactor Configuration for Effective Fungal Treatment of Textile Wastewaters

Identification of fungal ene-reductase activity by means of a functional screening

Bioeconomy stresses the need of green processes promoting the development of new methods for biocatalyzed alkene reductions. A functional screening of 28 fungi belonging to Ascomycota, Basidiomycota, and Zygomycota isolated from different habitats was performed to analyze their capability to reduce C=C double bonds towards three substrates (cyclohexenone, α-methylnitrostyrene, and α-methylcinnamaldehyde) with different electron-withdrawing groups, i.e., ketone, nitro, and aldehyde, respectively. Almost all the fungi showed this reducing activity. Noteworthy Gliomastix masseei, Mucor circinelloides, and Mucor plumbeus resulted versatile and effective, being able to reduce all the model substrates quickly and with high yields.

Stimulation of laccases from Trametes pubescens: Use in dye decolorization and cotton bleaching

ABSTRACT The production of laccases from Trametes pubescens was investigated along with the role of nutrients and elicitors. Copper proved to be a fundamental inducer, although productivity yields were consistently enhanced only in the presence of additional compounds (textile dyes). Using a central composite design, the optimal culture condition was examined, by taking into consideration the three distinct variables and their combinatorial effect. The 290 U ml−1 of laccases were produced after setting nitrogen, copper, and reactive blue 19 concentration; in a bioreactor, activity recovery was lower (90 U ml−1) and pellet morphology was different. The activity of the laccase crude extract was maximal at 60°C and stable for 14 h at 50°C and for 2 months at pH 6 and room temperature. The biotechnological potential was assessed, confirming the capacity to decolorize single or mixed solutions of textile dyes and to enhance the whitening yield of raw cotton fibers, working in synergism with the conventional H2O2-based method.