Soil Bioremediation. Группа авторов
Читать онлайн книгу.[70]. Several researchers have studied the addition of N and P to enhance nutrient level. The biodegradation of petroleum hydrocarbons was enhanced by up to 96% after the addition of biosolids and N and P rich inorganic fertilizers to diesel contaminated soils [73]. Likewise, commercial fertilizers were used to remediate diesel oil in the Antarctic seas. Furthermore, higher concentrations of N and P sources can cause eutrophication, thereby enhancing algal growth and ultimately reducing the dissolved O2 concentration in the water [72]. Separate from nutrient content numerous other factors can greatly affect the degradation rate of polyaromatic hydrocarbons under natural environmental conditions, for example, physical mixing, use of biostimulation agents, mechanical tilling, manual removal, and C sources. It was observed that factors including the intensity of physical mixing, the pretreatments, and the accessibility of alternative carbon sources effected the degradation potential of microbes after Exxon Valdez oil spill [74]. Temperature has also a considerable effect on degradation potential of microbes, because it affects the viscosity, water solubility, and composition of oil. Furthermore, it also affects the metabolism of hydrocarbons and composition of microorganisms [70]. Subsequent to the spillage at Chedabucto Bay the effect of temperature on the degradation of bunker C fuel oil was studied, with temperature ranging from 5 to 28 °C, using mixed microbial cultures and it was found that 41–85% benzene soluble components disappeared after incubation of 7 days at 15 °C, however, 21–52% degradation was obtained after 14 days of incubation at 5 °C [75]. It was found that nutrient stock is essential for degradation by microorganisms under all environmental conditions. The degradation of the contaminant after 17 weeks was almost three times higher at 20 °C and eight times higher at 6 °C when compared to nutrient‐deficient sands [76]. On the other hand, temperature exhibited limited influence on petroleum degradation in Antarctic seawater samples in a laboratory microcosm study, where commercial fertilizer improved bioremediation [71]. Biostimulation aided with biosurfactants enhanced the rate of biodegradation [55, 77, 78]. Biostimulation using N and P fertilizer together with biosurfactants facilitated naturally occurring microbes to adapt better and faster to the oil spill contamination, confirming a relatively shorter lag phase and faster degradation rates [72]. The most promising strategy to enhance the rate of degradation is the use of a combination of biostimulation, bioaugmentation, and biosurfactants [79]. However, any such planned intervention must be followed by ecotoxicity and quality studies of the contaminated site to ascertain that it has regained its natural biological activity and integrity [58, 80]. Thus, toxicity tests and measuring microbial activity must be carried out for monitoring purposes during and after bioremediation of contaminated soils [81].
1.3.3 Bioaugmentation Versus Biostimulation
Application of bioaugmentation or biostimulation techniques for bioremediation processes significantly depends upon the prevailing environmental conditions. Hamdi et al. [80] found that the efficiency of a remediation process depends on the added microorganisms, rather than the nutrient content [80]. Bento et al. [82] compared bioremediation of diesel oil by natural attenuation, biostimulation, and bioaugmentation. Of the three bioremediation techniques, i.e. natural attenuation, biostimulation, and bioaugmentation used to degrade diesel oil, the best results were revealed by bioaugmentation after inoculation of microbes selected from the polluted site. Evidently, native microorganisms have more possibility to endure and procreate when they are reintroduced into the site, as compared to foreign strains [23, 82]. However, several reports suggest that the use of native cultures were not particularly effective in the removal rates of hydrocarbons however, stimulation was very effective in such a case [83]. For native and foreign microorganisms, biostimulation provides suitable nutrients and encouraging conditions. Thus, biostimulation becomes a feasible method in those cases where microorganisms adapt due to exposure to hydrocarbons at polluted sites. Eventually, the population, which has adapted to the conditions, exhibits high bioremediation rates and, consequently, biostimulation is more appropriate in such cases [61, 84]. However, natural acclimatization by the indigenous microbial population often requires a longer time period due to an extended lag phase leading to prolonged bioremediation processes [85]. Bioaugmentation and biostimulation techniques are now developing as complementary techniques due to the various limitations when they are applied separately. Hamdi et al. [80] amended PAH contaminated soil using both bioaugmentation and biostimulation and achieved higher PAH dissipation rates, remarkably for anthracene and pyrene, than those observed in unamended PAH‐spiked soils.
1.4 Conclusion
Bioremediation is a more ecofriendly and economical technique as compared to chemical or physical removal of toxic pollutants from the contaminated soil or water. However, certain contradictory results for bioaugmentation and biostimulation have been obtained, these two techniques of bioremediation hold the potential of exemplifying in‐situ bioremediation. These techniques are very distinct from each other but are used as complementary techniques for the decontamination of oil spills and other severely contaminated sites. The necessary requirements for bioremediation processes like the presence of competent microbes, nutrients, and suitable environmental conditions must be determined by laboratory and field trials. It has been clearly indicated that bioaugmentation and biostimulation are extremely efficient in‐situ remediation techniques. However, data prediction depends mainly upon the environmental conditions and thus finding appropriate microorganisms and suitable environmental conditions for each polluted site is perhaps the best solution.
References
1 1 Travis, A.S. (2002). Contaminated earth and water: a legacy of the synthetic dyestuffs industry. Ambix 49: 21–50.
2 2 Ostroumov, S.A. (2003). Anthropogenic effects on the biota: towards a new system of principles and criteria for analysis of ecological hazards. Rivista di Biologia 96: 159–169.
3 3 Labie, D. (2007). Developmental neurotoxicity of industrial chemicals. Medical Sciences (Paris) 23: 868–872.
4 4 Robinson, T., McMullan, G., Marchant, R. et al. (2001). Remediation of dyes in textile effluent: a critical review on current treatment technologies with a proposed alternative. Bioresource Technology 77: 247–255.
5 5 Felsot, A.S., Racke, K.D., and Hamilton, D.J. (2003). Disposal and degradation of pesticide waste. Reviews of Environmental contamination and Toxicology 177: 123–200.
6 6 Lodolo, A., Gonzalez‐Valencia, E., and Miertus, S. (2001). Overview of remediation technologies for persistent toxic substances. Archives of Industrial Hygien and Toxicology 52: 253–280.
7 7 Scullion, J. (2006). Remediating polluted soils. Naturwissenschaften 93: 51–65.
8 8 Shannon, M.J. and Unterman, R. (1993). Evaluating bioremediation: distinguishing fact from fiction. Annual Review of Microbiology 47: 715–738.
9 9 Snellinx, Z., Nepovim, A., Taghavi, S. et al. (2002). Biological remediation of explosives and related nitroaromatic compounds. Environmental Science and Pollution Research International 9: 48–61.
10 10 Lovley, D.R. (2003). Cleaning up with genomics: applying molecular biology to bioremediation. Nature Reviews Microbiology 1: 35–44.
11 11 Diaz, E. (2004). Bacterial degradation of aromatic pollutants: a paradigm of metabolic versatility. International Microbiology 7: 173–180.
12 12 Parales, R.E. and Haddock, J.D. (2004). Biocatalytic degradation of pollutants. Current Opinion in Biotechnology 15: 374–379.
13 13 Nojiri, H. and Tsuda, M. (2005). Functional evolution of bacteria in degradation of environmental pollutants. Tanpakushitsu Kakusan Koso 50: 1505–1509.
14 14 Janssen, D.B., Dinkla, I.J., Poelarends, G.J. et al. (2005). Bacterial degradation of xenobiotic compounds: evolution and distribution of novel enzyme activities. Environmental Microbiology 7: 1868–1882.
15 15 Zhang, J., Zhang, H., Li, X. et al. (2006). Soil microbial ecological process and microbial functional gene diversity. Ying Yong Sheng Tai Xue Bao 17: 1129–1132.
16 16 Arai, H., Ohishi, T., Chang, M.Y. et al. (2000). Arrangement and regulation of the genes for