Artículos de revistas
Sustainable bioremediation of antibacterials, metals and pathogenic DNA in water
Registration in:
0959-6526
Author
Islas Espinoza, Marina
Aydin, Sevcan
De las Heras, Alejandro
Cerón, Cecilia A.
Martínez, Saúl G.
Vazquez Chagoyan, Juan Carlos
Institutions
Abstract
The global antibacterial resistance requires urgent attention from different fields of engineering. Here, several
unit operations were assessed in a novel water treatment train capable of remediating antibacterials, metals
and pathogenic DNA to generate clean water. The analyses used 14C-respirometry, spectrometry, and a set
of molecular analyses. Multiresistant bacteria hold antibacterial resistance genes (ARGs), which were harnessed
for bioremediation of pollutant mixtures. Treatment efficiencies were 25–71% for 8-days with aerobic
Cr(VI) reduction and removal of Cd and Pb; and 34.8% erythromycin (ERY) was biodegraded aerobically in
20 days. The anaerobic digestion (AD) bioremediated 65–73% mixed antibacterials ERY and sulfamethoxazol
(SMX) in 60 days. However, high concentrations of mixed antibacterials induced inhibition of bacteria
and methanogens and higher diversity of ARGs. ARGs were eliminated at 60 °C and 5.8 kPa for 10 min. The
suggested coupling sequence of operations was metal, then antibacterial aerobic bioremediation, AD (yielding
biomethane as energy source), recirculation of ARGs in situ, and thermo-pressure pathogenic DNA degradation. Universidad Autónoma del Estado de México proyecto No. 3883M/2015