Impact of treated wastewater on organismic biosensors at various levels of biological organization

Popović, Natalija Topić; Strunjak‐Perović, Ivanc̆ica; Klobučar, Roberta Sauerborn; Barišić, Josip; Babić, Sanja; Jadan, Margita; Kepec, Slavko; Kazazić, Snježana; Matijatko, Vesna; Ljubić, Blanka Beer; Car, Ivan; Repec, Siniša; Stipaničev, Draženka; Klobučar, Göran; Čož‐Rakovac, Rozelindra

doi:10.1016/j.scitotenv.2015.08.044

Cited by 23 publications

(5 citation statements)

References 53 publications

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“…From skin, fecal coliforms, E.coli, P. aeruginosa and sulphitereducing clostridia were not isolated, nor from any of the internal organs. Although fecal indicator bacteria were not retrieved in large numbers in downstream fish, and fecal coliforms and intestinal enterococci in this study were not significantly elevated in water bodies from which fish were captured (Topić Popović et al, 2015a), there is a risk of pathogens penetrating fish tissues. It rises if the total counts of heterotrophic aerobic bacteria exceed 10 4 CFU mL -1 of such water, and usually only fecal contamination indicators are used for such estimations (Molleda et al, 2008;Harnisz and Tucholski, 2010).…”

Section: Resultscontrasting

confidence: 60%

The Impact of Treated Wastewaters on Fish Bacterial Flora: A Public Health Perspective

Popović

Kepec

Kazazić

et al. 2019

Croatian Journal of Fisheries

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Wastewaters from a treatment plant discharging into a canal harboring fish may present sources of microbiological hazard for wild fish. Such fish, inhabiting microbiologically polluted bodies of water, can be contaminated by human pathogens and, if used for human consumption, may pose a risk to public health. Hence, in this work the aim was to identify tested strains from tissues of wild fish living in the receiving water bodies, captured from locations up to 12 km from the point of discharge of treated water of town Virovitica in order to assess the bacterial threat of the WWTP on fish and potentially on public health. A rather rich diversity of bacterial genera was isolated from gill tissues and internal organs. The most frequent isolate was Aeromonas hydrophila which has gained public health recognition as an opportunistic pathogen. Vibrio cholerae, an indicator bacterium for aquatic contamination, was retrieved from all investigated tissues. Opportunistic human pathogens as well as some zoonotic agents were also retrieved from fish tissues (Enterobacter amnigenus, Acinetobacter spp., Ochrobactrum anthropi, Pseudomonas aeruginosa, Flavimonas (Pseudomonas) oryzihabitans, Shewanella putrefaciens and others). Public health hazard is particularly pronounced regarding local recreational fishermen who fish out, handle and consume fish from respective waters.

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Section: Resultscontrasting

confidence: 60%

The Impact of Treated Wastewaters on Fish Bacterial Flora: A Public Health Perspective

Popović

Kepec

Kazazić

et al. 2019

Croatian Journal of Fisheries

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“…Discharges from WWTPs directly and indirectly affect both terrestrial and aquatic ecosystems (Babić et al, 2016). Treated wastewater discharged from the WWTP in this work modified the environmental parameters and xenobiotic concentrations of the receiving surface waters, while potential bacterial pathogens from fish and respective waters were observed in relatively low numbers, as described previously in Topić Popović et al (2015). S. baltica was retrieved from the gills, liver, and kidney of fish living in WWTP-affected waters, having none to slight clinical signs.…”

Section: Discussionmentioning

confidence: 57%

Shewanella spp. from wastewater treatment plant-affected environment: isolation and characterization

Popović

Kazazić

Bilić

et al. 2022

Environ Sci Pollut Res

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Bacteria from the genus Shewanella are inhabitants of marine and freshwater ecosystems, recognized fish spoilage bacteria, but less known as fish disease agents. Shewanella spp. isolated 2 from fish living in waters close to effluents of a wastewater treatment plant (WWTP) were not previously characterized. We have tested Shewanella isolates from WWTP-affected waters and related fish. Genotypic characterization identified most strains as S. baltica and S. oneidensis. In order to investigate the sensibility and accuracy of their MALDI-TOF MS identification, they were grown on two culture media enriched by various NaCl concentrations, incubated at different temperatures and duration. We analyzed their antimicrobial susceptibility on a panel of antimicrobial drugs and capacity for biofilm production. With a view to demonstrate their capacity to produce fatty acids, we assessed the impact of different culture media on their lipid profile. We performed zebrafish embryotoxicity tests to simulate the environmental infection of the earliest life stages in S. baltica-contaminated waters. The best MALDI-TOF MS identification scores were for strains cultivated on TSA for 24 h at 22 °C and with supplementation of 1.5% NaCl. Less than 17% of isolates demonstrated antimicrobial resistance.Most isolates were weak biofilm producers. Strain-to-strain variation of MIC and MBC was low.The major fatty acids were C15:0, C16:0, C16:1, C17:1, and iC15:0. Exposure of Danio rerio to different S. baltica concentrations induced severe effects on zebrafish development: decreased heartbeat rate, locomotor activity, and melanin pigmentation. S. baltica passed through chorionic pores of zebrafish.

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“…Food waste in water represents a unique field compared to solid waste; and biosensing, nanomaterials, and wireless communication have been introduced in this field to enhance the accuracy, power consumption efficiency, data storage capabilities, communication ability, remote sensing, and commercialization [ 108 ]. Biosensing technologies can be applied to test-treated waste water released from local waste water treatment plant, because it is important to monitor the treated waste water to prevent harmful effects and reduce adverse influences on the local environment and organisms living in water, such as fish and other species [ 109 ]. Future challenges in water waste biosensing processes exist in establishing multitude of sensing arrays with multi-location deployable, unique sensing properties, and better sensing accuracy; developing wireless networks to improve remote sensing qualities, and improving cost-benefit ratios in emerging waste processing sectors.…”

Section: Biosensing In Food Waste Processing and Environmentmentioning

confidence: 99%

Biosensors for Sustainable Food Engineering: Challenges and Perspectives

et al. 2018

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Current food production faces tremendous challenges from growing human population, maintaining clean resources and food qualities, and protecting climate and environment. Food sustainability is mostly a cooperative effort resulting in technology development supported by both governments and enterprises. Multiple attempts have been promoted in tackling challenges and enhancing drivers in food production. Biosensors and biosensing technologies with their applications, are being widely applied to tackling top challenges in food production and its sustainability. Consequently, a growing demand in biosensing technologies exists in food sustainability. Microfluidics represents a technological system integrating multiple technologies. Nanomaterials, with its technology in biosensing, is thought to be the most promising tool in dealing with health, energy, and environmental issues closely related to world populations. The demand of point of care (POC) technologies in this area focus on rapid, simple, accurate, portable, and low-cost analytical instruments. This review provides current viewpoints from the literature on biosensing in food production, food processing, safety and security, food packaging and supply chain, food waste processing, food quality assurance, and food engineering. The current understanding of progress, solution, and future challenges, as well as the commercialization of biosensors are summarized.

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Impact of treated wastewater on organismic biosensors at various levels of biological organization

Cited by 23 publications

References 53 publications

The Impact of Treated Wastewaters on Fish Bacterial Flora: A Public Health Perspective

The Impact of Treated Wastewaters on Fish Bacterial Flora: A Public Health Perspective

Shewanella spp. from wastewater treatment plant-affected environment: isolation and characterization

Biosensors for Sustainable Food Engineering: Challenges and Perspectives

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