Augmentation of biodegradability of olive mill wastewater by electrochemical pre-treatment: effect on phytotoxicity and operating cost.

In order to exploit the fertilizer value of olive oil mill wastewaters (OMW), a novel method has been developed for its treatment. OMW effluents were pre-treated first by electrocoagulation using aluminum electrode and then by a biological process using a selected strain of Aspergillus niger van Tieghem. The effect of treatments was assessed through COD removal, reduction of total phenols, and decrease of phytotoxicity using durum wheat (Triticum durum) seeds. This sequential treatment scheme was capable of reducing concentration of organics, phenolics and phytotoxicity. The goal of this investigation was achieved, the phytotoxicity was completely removed and the germination index was 106% of OMW after sequential treatment. It can be concluded that the sequential process of OMW treatment might serve for the production of a fertilizer which is able to improve the growth of plants. These results are encouraging in the context of developing a low-budget technology for the effective management of OMW.

Detoxification and discoloration of Moroccan olive mill wastewater by electrocoagulation.

The objective of the present study was to assess the electrocoagulation treatment of olive mill wastewater using an aluminum electrode. We have examined the effect of the following parameters on the removal of chemical oxygen demand (COD), polyphenols and dark color removal efficiency: Electrolysis time, Current density, Chloride concentration and Initial pH. The olive mill wastewater (OMW)--diluted 5 times--used in this study had 20.000 mg/L chemical oxygen demand, 3.6 mS/cm conductivity and acidic pH (4.2). It also contains considerable quantities of polyphenols (260 mg/L). The evolution of the physico-chemical parameters during the treatment by electrocoagulation showed that under the following conditions: electrolysis time 15 min, NaCl concentration 2g/L, initial pH 4.2 and current density 250 A/m(2), the discoloration of the olive mill wastewater, the reduction of the chemical oxygen demand and the reduction of polyphenols exceeded 70%, the electrodes consumption was 0.085 kg Al/kg COD(removed) and the specific energy consumed was 2.63 kWh/ kg COD(removed). Under these optimal experimental conditions, olive mill wastewater became non-toxic for Bacillus cereus.

In vitro inhibition of microbial flora of fish by nisin and lactoperoxidase system.

AIMS: To test the antimicrobial effects of nisin and lactoperoxidase system (LP system) against sardines flora. This study is part of a programme designed to investigate the preservability of fish using these inhibitors as potential biopreservatives. METHODS AND RESULTS: Antimicrobial effects of nisin and LP system alone or in combination were tested by the agar diffusion method against bacterial strains isolated from sardines (Sardina pilchardus). Nisin inhibited only Gram-positive bacteria, whereas LP system inhibited all strains studied. The combination of nisin (100 IU ml-1) and LP system (10 level) was significantly more effective than LP system or nisin alone against all strains, excepting Aeromonas salmonicida subsp. salmonicida and Vibrio alginolyticus. CONCLUSION: These results clearly demonstrated the efficiency of LP System-nisin combination for inhibiting spoilage flora of fish. SIGNIFICANCE AND IMPACT OF THE STUDY: Because LP system has a broad activity spectrum, it may be an interesting additional hurdle to improve the safety of food preservation by nisin. Combination of nisin and LP system could be of great interest as biopreservatives for fish and fish products.

Roles of two white-rot basidiomycete fungi in decolorisation and detoxification of olive mill waste water.

A Phanerochaete chrysosporium strain was isolated from Moroccan olive mill waste water (OMW) and its ability to degrade OMW in different culture conditions was investigated and compared to that of Pleurotus ostreatus. The results indicated that Ph. chrysosporium isolate is more efficient than Pl. ostreatus in decolorising and detoxifying OMW in the presence of added nutrients. Ph. chrysosporium is able to remove more than 50% of the colour and phenols from OMW within 6 days of incubation, whereas Pl. ostreatus needs more than 12 days to reach similar results in the same conditions. Many factors affecting the treatment of diluted OMW (20%) by Ph. chrysosporium were studied, including the effects of added nutrients, initial pH, temperature and inoculated biomass. Once the optimisation of 20% OMW biodegradation process had been set up, higher OMW concentrations (50%) were tested. The results show that the fungus is capable of reducing all parameters analysed (colour A395, phenol content and chemical oxygen demand) by at least 60%, after only 9 days of growth.

Antilisterial activity of enterocin 81, a bacteriocin produced by Enterococcus faecium WHE 81 isolated from cheese.

Enterocin 81, a bacteriocin produced by Enterococcus faecium WHE 81 previously isolated from cheese, exhibited a very narrow spectrum of activity, which is mainly directed against enterococci and Listeria spp. including Listeria monocytogenes. Enterocin 81 activity, which was extremely rapid with maximal effect achieved within 30 min, could not be detected after treatment with various proteolytic enzymes. This activity was bactericidal in nature and induced an important efflux of intracellular material, which was visualized under electron microscopy as filaments coming out of L. monocytogenes cells. However, enterocin 81 did not display bacterial lysis on sensitive cells, as no changes in cell morphology were detected following the bactericidal action. Furthermore, this bacteriocin was shown to be equally active at pH values ranging from 4.0 to 8.0, which, along with the narrow activity spectrum, are two factors of paramount interest with regards to possible use of this bacteriocin in fermented foods.