ADSORPCE ORGANICKÝCH LÁTEK PRODUKOVANÝCH SINICÍ MICROCYSTIS AERUGINOSA NA AKTIVNÍM UHLÍ / ADSORPTION OF ALGAL ORGANIC MATTER PRODUCED BY MICROCYSTIS AERUGINOSA ONTO ACTIVATED CARBON

Krsová, Magdalena

January 2013

The aim of this diploma thesis is to evaluate the efficiency of two types of granular activated carbon (GAC), Filtrasorb TL 830 and Picabiol 12x40, for the adsorption of cellular peptides with low molecular weight produced by cyanobacterium Microcystis aeruginosa that are hardly removable during the coagulation/flocculation processes. The effect of different carbon properties (surface charge, textural characteristics), peptide properties (molecular size, surface functionality and charge) and solution characteristics (ionic strength and pH value) on the peptide uptake was investigated using laboratory equilibrium and kinetic adsorption experiments. The results showed that adsorption of peptides was influenced by the charge conditions in adsorption system that depend on solution pH. The pH value influences surface charge and the point of zero charge (pHpzc) of GAC as well as dissociation and protonization of peptide functional groups. It was found that efficiency of the peptide adsorption increased with decreasing pH value for both GACs. Under these conditions adsorption was enhanced by attractive electrostatic interactions between GAC surface and peptide functional groups and was also positively influenced by the conformation changes in peptide structure. GAC Picabiol 12x40 showed the total highest...

Effects of Elevated Salinity and Oxidative Stress on the Physiology of the Toxigenic Cyanobacterium Microcystis Aeruginosa

Warhurst, Billy Christopher

01 January 2014

Harmful algal blooms (HABs) are found worldwide, particularly in places where warm, well-lit, and stagnant waters are common. HABs can have negative effects on aquatic plants and wildlife due to the reduction in light availability associated with turbidity, decrease in O2 availability, and the production of secondary metabolites that can harm or even prove lethal. Aquatic ecosystems are regularly being affected by elevated salinity because of recent water management strategies, episodes of drought, and salt water intrusion. This research focused on how salinity levels ranging from 0-10ppt affected physiological attributes such as cellular growth and abundance, cell mortality, toxin release, and oxidative stress in the toxigenic cyanobacterium, Microcystis aeruginosa. It was determined that salinity treatments of 7ppt and above caused a decrease in both cellular growth and abundance, as well as an increase in toxin release due to cell mortality. M. aeruginosa was able to survive in salinities up to 7ppt. A pattern of caspase activity in response to elevated salinity was shown, but whether cellular mortality was due solely to programmed cell death (PCD) was not definitive. A strong antioxidant response, measured through catalase activity, was noted when salinity was enhanced to 7ppt. Above this value, the damaging effects of salinity caused elevated levels of reactive oxygen species (ROS) production and cell death. It was determined that the maximum amount of hydrogen peroxide that M. aeruginosa could withstand without significant impact to growth and abundance was below 250µM. Salinities of 7ppt and above had a negative impact on the physiology of M. aeruginosa, leading to cell death and an increase in microcystin release into the environment. These two factors can lead to fish kills, poor drinking water, and other recreational and commercial problems for an aquatic ecosystem. By determining the precise salinity that HAB cellular mortality is imminent, predictive models can be employed to predict the impacts of salt intrusion and groundwater management.

Thesis

University of North Florida

UNF

Dissertations

Dissertations

Academic -- UNF -- Biology

cyanobacteria

harmful algal blooms

oxidative stress

PCD

salt stress

Microcystis aeruginosa

Biology

Terrestrial and Aquatic Ecology

​​USE OF ALGAE, CYANOBACTERIA, AND INDIGENOUS BACTERIA FOR THE SUSTAINABLE TREATMENT OF AQUACULTURE WASTEWATER​<b> </b>

Yolanys Nadir Aranda Vega (18433941)

27 April 2024

<p dir="ltr">Aquaculture is a controlled aquatic farming sector and one of the most important human food sources. Fish farming is one of the predominant, fast-growing sectors that supply seafood products worldwide. Along with its benefits, aquaculture practices can discharge large quantities of nutrients into the environment through non-treated or poorly treated wastewater. This study aims to understand the nutrient composition of fish wastewater and the use of indigenous bacteria, cyanobacteria, and microalgae as an alternative biological treatment method. Wastewater samples from a local fish farming facility were collected and treated using six different species of cyanobacteria and microalgae include <i>Chroococcus</i><i> </i><i>minutus</i>, <i>Porphyridium</i><i> </i><i>cruentum</i>, <i>Chlorella vulgaris</i>, <i>Microcystis aeruginosa</i>, <i>Chlamydomonas </i><i>reinhardtii</i>, and <i>Fischerella</i><i> </i><i>muscicola</i>. All the samples were incubated for 21 days, and the following parameters were measured weekly: Chemical oxygen demand (COD), phosphate, total dissolved nitrogen, and dissolved inorganic nitrogen. In addition, dissolved organic nitrogen (DON), bioavailable DON (ABDON), and biodegradable DON (BDON) were calculated from the mass-balance equations. Colorimetric and digestive methods were used for the parameter measurements. The results showed that <i>C. </i><i>reinhardtii</i> reduced the soluble COD concentration by 74.6%, DON by 94.3%, and phosphorous by more than 99%. Moreover, <i>M. aeruginosa</i>, and <i>C. </i><i>minutus</i> significantly reduced inorganic nitrogen species (>99%). This alternative fish wastewater treatment method was explored to gain insight into fish wastewater nutrient composition and to create a sustainable alternative to conventional fish wastewater treatment methods.<b> </b></p>

Aquaculture

Microbial ecology

Virology

Environmentally sustainable engineering

Biological control

Bioremediation

aquaculture effluent water

Microcystis aeruginosa cells

wastewater treatment facility effluent