Avaliação ecotoxicológica de efluentes tratados por alagados construídos / Ecotoxicological evaluation of effluents treated by constructed wetlands

RESUMO O objetivo deste trabalho foi avaliar o desempenho de alagados construídos com fluxo subsuperficial horizontal cultivados com as macrófitas aquáticas Eleocharis sp. (junco) e Typha sp. (taboa) na redução da toxicidade de efluentes domésticos. Para isso, foram utilizados ensaios ecotoxicológicos com o microcrustáceo Daphnia similis, a dicotiledônea Lactuca sativa (alface), a monocotiledônea Sorghum vulgare (sorgo) e as macrófitas aquáticas Lemna sp. (lentilha-d'água) e Azolla sp. O efluente doméstico mostrou-se tóxico à Daphnia similis com média de EC50 de 1,3%. Os tratamentos com macrófitas reduziram significativamente a toxicidade do efluente, com médias de EC50 de 73% para o tratamento com junco, 53,17% para o com taboa e 78,25% para o com taboa + junco. O controle (sem macrófitas) também reduziu significativamente a toxicidade, com média de EC50 de 63,13%. Nos ensaios de fitotoxidade, a alface e o sorgo não se mostraram sensíveis ao efluente analisado, embora sejam para outros tipos de efluentes. A macrófita Lemna sp. também não foi sensível ao efluente estudado, no entanto, observou-se a capacidade de identificar, com essa espécie, o potencial eutrofizante do efluente, já que esta se desenvolveu melhor no efluente bruto do que nos tratados. Com a macrófita Azolla sp., foi possível verificar que o efluente bruto apresenta maior potencial eutrofizante se comparado com os tratamentos com junco, taboa e controle, nos quais houve remoção de nitrogênio e fósforo. No entanto, evidenciou-se efeito tóxico para Azolla sp. nos efluentes tratados.

ABSTRACT The research objective was to evaluate the performance of wetlands constructed with vertical sub-surface flow cultivated with Eleocharis sp. (Junco) and Typha sp. (Taboa). For this, ecotoxicological tests were used with the microcrustacean Daphnia similis, with the dicotyledon Lactuca sativa (alface), the monocotyledon Sorghum vulgare (sorgo) and the aquatic macrophytes Lemna sp. (Duckweed) and Azolla sp. The domestic effluent was toxic to Daphnia similis with a mean EC50 of 1.3%. Macrophyte treatments significantly reduced effluent toxicity with EC50 averages of 73% for junco treatment, EC50 53.17% for taboa treatment, and EC50 78.25% for taboa + junco treatment. The control (without macrophytes) also significantly reduced toxicity, with a mean EC50 of 63.13%. In the phytotoxicity tests, lettuce and sorgo were not sensitive to the analyzed effluent, although they were for other types of effluents. The macrophyte Lemna sp. was also not sensitive to the effluent studied. However, it was possible to identify the eutrophic potential of the effluent with this species, since it was better developed in the raw effluent than in treated ones. With the macrophyte Azolla sp., it was possible to verify that the raw effluent has greater eutrophic potential when compared to the treatments with junco, taboa and control, where nitrogen and phosphorus removal was observed. However, toxic effect was observed for Azolla sp. in treated effluents.

Removal of Metal Nanoparticles Colloidal Solutions by Water Plants.

The ability of seven species of aquatic plants (Elodea canadensis, Najas guadelupensis, Vallisneria spiralis L., Riccia fluitans L., Limnobium laevigatum, Pistia stratiotes L., and Salvinia natans L.) to absorb metal nanoparticles from colloidal solutions was studied. It was established that investigated aquatic plants have a high capacity for removal of metal nanoparticles from aqueous solution (30-100%) which indicates their high phytoremediation potential. Analysis of the water samples content for elements including the mixture of colloidal solutions of metal nanoparticles (Mn, Cu, Zn, Ag + Ag2O) before and after exposure to plants showed no significant differences when using submerged or free-floating hydrophytes so-called pleuston. However, it was found that the presence of submerged hydrophytes in aqueous medium (E. canadensis, N. guadelupensis, V. spiralis L., and R. fluitans L.) and significant changes in the content of photosynthetic pigments, unlike free-floating hydrophytes (L. laevigatum, P. stratiotes L., S. natans L.), had occur. Pleuston possesses higher potential for phytoremediation of contaminated water basins polluted by metal nanoparticles. In terms of removal of nanoparticles among studied free-floating hydrophytes, P. stratiotes L. and S. natans L. deserve on special attention.