ABSTRACT
Much of the past and current focus of bioremediation has been on laboratory studies of microbial processes. By necessity, early studies have ignored important field properties, parameters, and processes that control the ultimate success of in situ bioremediation of contaminated groundwater. This paper presents a bioengineering systems approach that examines the impact of some of these field variables on common bioremediation practices. Using simple systems, the niche of biostimulation is shown to be aquifers with high contaminant sorption. A novel gas-phase biostimulation filter and a novel resting-state bioaugmentation/biofilter approach which show promise for effective field implementation are discussed.
Subject(s)
Biodegradation, Environmental , Engineering/methods , Environmental Pollutants/metabolism , Filtration/methods , Bacteria/metabolism , Culture Media/metabolism , Environmental Pollution , Gases/administration & dosage , Gases/metabolism , Industrial Waste , Models, Biological , Water MicrobiologyABSTRACT
A study of the random motility and chemotaxis of Methylosinus trichosporium OB3b was conducted by using Palleroni-chamber microcapillary assay procedures. Under the growth conditions employed, this methanotroph was observed qualitatively with a microscope to be either slightly motile or essentially nonmotile. However, the cells did not not respond in the microcapillary assays in the manner expected for nonmotile Brownian particles. As a consequence, several hydrodynamic effects on these Palleroni microcapillary assays were uncovered. In the random-motility microcapillary assay, nondiffusive cell accumulations occurred that were strongly dependent upon cell concentration. An apparent minimal random-motility coefficient (mu) for this bacterial cell of 1.0 x 10(-7) cm2/s was estimated from microcapillary assays. A simple alternative spectrophotometric assay, based upon gravitational settling, was developed and shown to be an improvement over the Palleroni microcapillary motility assay for M. trichosporium OB3b in that it yielded a more-accurate threefold-lower random-motility coefficient. In addition, it provided a calculation of the gravitational-settling velocity. In the chemotaxis microcapillary assay, the apparent chemotactic responses were strongest for the highest test-chemical concentrations in the microcapillaries, were correlated with microcapillary fluid density, and were strongly dependent upon the microcapillary volume. A simple method to establish the maximal concentration of a chemical that can be tested and to quantify any contributions of abiotic convection is described. Investigators should be aware of the potential problems due to density-driven convection when using these commonly employed microcapillary assays for studying cells which have low motilities.
Subject(s)
Bacteriological Techniques , Chemotaxis/physiology , Methylococcaceae/physiology , Bacteriological Techniques/instrumentation , Biodegradation, Environmental , Cell Movement , Chemotaxis/drug effects , Colony Count, Microbial , Hydrocarbons/metabolism , Methylococcaceae/drug effects , Particle SizeABSTRACT
The cardiovascular effects of benzquinamide were evaluated in anesthetized dogs. Intravenous benzquinamide, 0.5 to 5 mg/kg, caused tachycardia, elevated blood norepinephrine levels, frequent ventricular arrhythmias, and brief hypotension. Ganglionic blockade by hexamethonium prior to administration of benzquinamide prevented the tachycardia and alterations in norepinephrine levels but prolonged the period of hypotension. In isolated mesenteric arterial preparations benzquinamide interfered with contractile force generated by potassium chloride, norepinephrine, and prostaglandin F2 alpha. It is concluded that benzquinamide directly relaxes vascular smooth muscle thereby producing in vivo reduced peripheral vascular resistance and hypotension, which are compensated for by reflex sympathetic activation.