Factorial Designs Application to Study Enhanced Bioremediation of Soil Artificially Contaminated with Weathered Bonny Light Crude Oil through Biostimulation and Bioaugmentation Strategy ()
1. Introduction
Crude oil is an extremely complex mixture of aliphatic and aromatic hydrocarbons, including volatile components of gasoline, petrol, kerosene, lubricating oil and solid asphaltene residues. In developed and developing countries, contamination of soil and marine environment by crude oil and petroleum products has become a serious problem. The main sources of this contamination can originate from natural oil seepage and human activities including extraction, transportation, utilization of petroleum (crude oil and natural gas), oil field installations, petroleum plants (refining), liquid fuel distribution and storage devices, transportation equipment for petroleum products, airports and illegal drillings in pipe lines [1-3]. The scale of the hazards imposed on the natural environment depends on the surface of the area contaminated by petroleum products, their chemical composition, and the depth at which pollutants occur.
Crude oil causes a variety of risks when released into the environment. It is physically, chemically and biologically harmful to soil because of the presence of many toxic compounds, such as polycyclic aromatic hydrocarbons, benzene and its substituted and cycloalkane rings, in relatively high concentrations. The fate and effects of spilled crude oil and its products in soils have already been the subject of several studies [4-6]. Biodegradation of hydrocarbon compounds is one of the most important processes involved in the weathering and eventual removal of oil from the environment, particularly for its non-volatile components. Thus, potentially biodegradation can be used for recovery of sensitive areas such as contaminated shorelines, marshes, and wetlands.
The term “enhanced bioremediation” encompasses a broad continuum of technologies that differ with respect to their inputs [7-9]. These technologies may involve the addition of electron acceptors or electron donors to stimulate naturally occurring microbial populations (biostimulation) or could be the introduction of specific microorganisms to enhance the biodegradation of the target compound (bioaugmentation). Bioremediation technologies have been developed for soils and coastal areas using the addition of nutrients and microbes [10-13]. However, it is known that biodegradation efficiencies of petroleum hydrocarbons in soil can be limited by physicochemical as well as biological factors, such as nutrients, pH, temperature, moisture, oxygen, soil properties, and contaminant concentration, number and type or species of microorganisms [14-21]. Also, oil spills result in an imbalance in the carbon-nitrogen ratio at the spill site, because crude-oil is essentially a mixture of carbon and hydrogen. This causes a nitrogen deficiency in an oilsoaked soil, which retards the growth of bacteria and the utilization of carbon source(s). Huang et al. [22], Borresen and Rike [23], and Boopathy [24] determined optimum nutrient supplement levels at laboratory incubation experiments.
Application of surfactants to soil contaminated with petroleum hydrocarbons can potentially reduce the interfacial tension, increase its solubility and bioavailability, and thus facilitate their biodegradation [25,26]. Addition of synthetic surfactants to environments contaminated with petroleum hydrocarbons has been studied as a means by which their inhibitory effects on biodegradation were recognized, especially in concentrations above their critical micelle concentration (CMC) values [24, 27]. Currently, available information regarding the effects of biodegradable surfactants’ addition such as Tween 80, Triton-X 100 and Brij 30 on enhanced biodegradation of petroleum hydrocarbons is limited [28-31]. Ongoing research and development seeking to improve methods by minimizing the number of experiments provide information about the direct additive effects of the study variables and interaction effects using design of experiment methods. Recently, this statistical technique has been successfully applied in many fields [22,32-34]. The statistical experiment designs most widely used in optimization experiments are termed response surface designs [22,32-37]. These designs provide information about direct effects, pair wise interaction effects and curvilinear variable effects. However, information on the optimization of biostimulation and/or bioaugmentation factors required for the enhanced bioremediation of petroleum hydrocarbons contaminated environment is still limited.
Therefore, the objective of this work is to study the bioremediation of soil artificially contaminated with “Weathered Bonny Light Crude Oil (WBLCO)” using the addition of NPK fertilizer (nutrient) and, Tween 80 (surfactant) as biostimulation factors and the addition of mixed culture (biomass) as bioaugmentation factor through Response Surface Methodology (RSM) via fullfactorial Box Behnken design in order to evaluate the influence of these biostimulation and/or bioaugmentation factors on the rate of WBLCO degradation and to optimize the factors for maximum crude oil removal.
2. Materials and Methods
2.1. Soil Sample and Characterization
An un-impacted soil samples from Ladoke Akintola University of Technology Agricultural Farms, Ogbomoso, were collected from the surface layer of the vadose zone 15 - 30 cm below land surface. The soil samples were air dried, homogenized, passed through a 2-mm (pore size) sieve and stored in a polythene bag at room temperature. Soil samples were characterized for their physicochemical and microbial parameters according to standard methods. Total organic carbon and total nitrogen of soil were determined using Walkley-Black and Macro-Kjeldahl methods respectively [38,39]. Soil pH was determined using pH meter fitted with a combined glass pH and reference electrode [38]. Soil moisture content was determined by evaporation on Whatman filter paper NO 1 (BDH Chemicals England) at 103˚C to 105˚C in an electrical oven. Available phosphorus was determined using Bray NO 1 Method [38,39]. The total hydrocarbon degrading bacteria (THDB) populations was determined by the vapor phase transfer method [40].
The determined soil parameters values are as follows: moisture content: 5.95 ± 0.05 (%); total nitrogen: 0.25 ± 0.04 (%); available phosphorus: 0.12 ± 0.02 (%); potassium: 0.31± 0.05 (%); total organic carbon: 1.21 ± 0.03 (%); pH 5.9 ± 0.2, and total hydrocarbon-degrading bacteria (THDB): 3.7 × 105 cfu-g−1. The hydrocarbon degrading bacterial types isolated from the soil samples were mainly Acinetobacter and Bacillus species. The soil characterization showed that the soil did not fulfill the nutrient (NPK) requirements for an efficient biodegradation process. Therefore, these elements were added in the form of NPK inorganic fertilizer (20:10:10) to provide the proper nutrients required for the bioremediation process as well as bioaugment with Pseudomonas species (binary mixed culture of Pseudomonas aeruginosa and Pseudomonas fluorescence) that has been utilized as potential good degraders of petroleum hydrocarbons [41, 42].
2.2. Chemicals and Microorganisms
The Bonny light crude oil was obtained from Nigerian National Petroleum Corporation, Port-Harcourt, Nigeria. This study employed a biodegradable nonionic surfactant Tween 80 manufactured by Sigma-Aldrich, USA, which has an average molecular weight of 1310 and a critical micelle concentration (CMC) value of 15 mg/l. NPK fertilizer (20:10:10) was purchased from an agrochemical store in Ogbomoso, Nigeria. Hexane solvent (BDH Chemicals, England) used for extraction of oil from soil were bought from a chemical store in Lagos, Nigeria.
Pseudomonas aeruginosa and Pseudomonas fluorescence were obtained from Department of Microbiology, Obafemi Awolowo University, Ile-Ife, Nigeria. Pure culture was maintained on nutrient agar slants at 4˚C. The strains were pre-grown in nutrient broth medium at room temperature (28˚C ± 2˚C) for 24 h and used for crude oil bioremediation studies. The overnight cultures were centrifuged, and the cell pellets was washed with physiological saline water thrice, re-suspended in saline water, homogenized and was used as stock solution. Different dilutions were made from the stock solution. A known volume of these solutions was filtered through 0.45 m filter paper (Millipore, USA) to find out the dry weight of cells. Corresponding absorbance was measured at 440 nm using a spectrophotometer. This information was used to prepare a calibration curve, dry weight versus absorbance. For unknown samples, the absorbance was measured at 440 nm and was converted to dry weight using absorbance versus dry weight calibration curve.
2.3. Microcosms Preparation and Bioremediation Experimentation
To optimize the range of experimentation for 23 fullfactorial Box-Behnken design, the following experiments were performed in earthen pots (used as bioreactors) maintained at room temperature. Soil samples (200 g) were placed in earthen pots (microcosm) and were artificially contaminated with WBLCO to a level of 10% w/w. The crude oil-contaminated soil in each earthen pot was amended with different amounts of NPK fertilizer (2 - 10 g), Tween 80 (5 - 25 mg/l) and binary mixed culture of P. aeruginosa and P. fluorescence (0.2 - 1.0 g/l), respectively. Soil used as control was not amended with any nutrient or microorganisms. In total, 16 microcosms were settled and incubated for 42 days. All bioreactors were mixed manually once per week to enhance oxygenation, and kept moist during the 42 days experimental period. Samples were withdrawn at intervals of one week for residual Total Petroleum Hydrocarbon (TPH) analysis.
2.4. Experimental Design and Data Analysis
The Box-Behnken factorial experimental design employed had three independent variables viz., NPK (20:10: 10) fertilizer, Tween 80 (surfactant) and biomass. Each of the independent amendment variables was studied at three levels of −1, 0, +1 (Table 1), with 17 experimental runs. The levels were selected based on above preliminary study results. The variables optimized were NPK fertilizer in the range of 2 - 6 g, Tween 80, 5 - 15 mg/l and biomass, 0.2 - 0.6 g/l, respectively. Change in TPH (i.e. percent TPH reduction) was considered as experimental response. Efficiency of crude oil removal was assessed after 42 days. Table 2 shows the coded and actual values of factors and levels used in the experimental design. Crude oil-contaminated soil without biostimulation and bioaugmentation was also assayed as a control. The statistical software Design Expert 6.0.8, (Stat-Ease Inc., Minneapolis, USA) was used to evaluate the analysis of variance (P < 0.05) to determine the significance of each term in the fitted equations and to estimate the goodness of fit in each case.
2.5. Estimation of Total Petroleum Hydrocarbon
Total Petroleum Hydrocarbon (TPH) was extracted from 10 g of soil with 50 ml of hexane [43]. The extract was dried at room temperature by evaporation of the hexane solvent under a gentle nitrogen stream in a fume hood. After evaporation of the solvent, the amount of residual TPH was determined gravimetrically [43] by reading absorbance at 400 nm using visible range spectrophotometer (Model 6100 PYE UNICAM instruments England) and estimating the concentration from the standards curve, obtained from hexane extracts of fresh Bonny light crude oil at different concentrations.
3. Results and Discussion
3.1. Natural Bioattenuation and Enhanced Bioremediation
After performing 17 runs of the Box-Behnken Design (BBD) and one control, the results of the statistical experiment were analyzed with regard to the coded design matrix. The regression equation shows that the crude oil degradation rate was an experimental function of test variables in coded units. Table 3 shows that on the 42
Table 1. Experimental range and the levels of the variables.
Table 2. Coded and uncoded full-factorial Box-Behnken design for the three independent variables.
day (6th week), crude oil content had decreased in all the earthen pot reactors. In control, natural biodegradation (natural bioattenuation) removed 44.78 percent of petroleum hydrocarbons. The reduction in petroleum hydrocarbon content of earthen pot reactors containing amendments was much higher (Table 3) in the same period.
These results indicate that the addition of biostimulant or biomass increased the rate of biodegradation. A considerable decrease in crude oil reduction was observed in runs 13 to 17, with a relatively high amount of NPK fertilizer, surfactant (Tween 80) and mixed culture (biomass); the residual oil reached 15.13 - 15.35 percent of the initial crude oil concentration. The comparison of crude oil enhanced bioremediation and natural bioattenuation for each run is shown in Figure 1.
At 10% (w/w) crude oil concentrations, run numbers 2 and 4, and runs number 11 and 12 had same remediation condition with different concentration of Tween 80 (surfactant); results shows that addition of surfactant can
Table 3. Experimental design and results for light crude oil removal from contaminated soil.
enhance crude oil degradation. Similar observations have been reported for the use of non-ionic surfactant for the remediation of environment contaminated with petroleum hydrocarbons [28,31,44]. Effect of different concentrations of mixed culture (biomass) augmentation were investigated at the same condition of NPK and Tween 80 (run numbers 6 and 8, and run numbers 10 and 12) and the findings demonstrated that addition of mixed culture (biomass) can enhance the bioremediation process of soil contaminated with crude oil. This is in agreement with other workers observation [37,42]. Relatively run numbers 3 and 4; and run numbers 7 and 8 had same condition with different concentration of NPK; results shows that extra addition of NPK fertilizer (nutrient) extensively improved crude oil biodegradation from 75.66 to 78.43 percent and from 77.04 to 81.96 percent, respectively. A similar observation has been reported [45-48].
One of the major factors that limit hydrocarbon biodegradation is their low availability to microbial cells [37, 49]. In addition, efficiency of bioremediation is a function of the microbial viability in the natural environment
Figure 1. Comparison of percentage total petroleum hydrocarbon reduction due to enhanced bioremediation and natural bioattenuation.
[12]. Factors, such as nitrogen, phosphorus, and microorganism presence, have been reported to affect bioremediation; for example, limiting nitrogen is reported to enhance bioremediation [37,50,51]. Yuting et al. [52] and Mohajeri et al. [37] showed that natural attenuation removed 13 and 9 - 12.6 percent of crude oil after 33 and 60 days incubation, respectively. When the soil was supplemented with nutrients (nitrogen and phosphorus) and biomass, 26.3 and 77 percent of the crude oil was respectively removed. The results suggest that high dose of nutrient amendment can accelerate the initial oil degradation rate and may shorten the period to clean up contaminated environments. The accelerating effect of amendment is stronger when nutrient availability is a limiting factor in the biodegradation of oil [37].
3.2. Second Order Polynomial Regression Model and Statistical Analysis
The experimental data were fitted to a second order polynomial regression model (Equation (1)) containing 3 linear, 3 quadratic and 3 interaction terms [53] using the same experimental design software to derive the equation for crude oil removal from contaminated soil.
(1)
where is the value of the fixed response at the centre point of the design; are linear coefficients; are quadratic coefficients; are the interaction effect coefficients regression terms, respectively; A, B and C are the levels of independent amendment variables The significance of each coefficient in the equation was determined by F-test and P-values. F-test indicated that all the factors and interactions considered in the experimental design are statistically significant (P < 0.05) at the 95 percent confidence level. The regression equation obtained after analysis of variance gives the level of total petroleum hydrocarbon reduction (crude oil removal) as a function of the different amendment variables: NPK, Tween 80, and mixed culture (biomass). All terms regardless of their significance are included in the following Equation (2):
(2)
where A is NPK concentration, B is Tween concentration; C is mixed culture concentration.
To test the fit of the model, the regression equation and determination coefficient (R2) were evaluated (Table 4). The model F-value of 1176.12 implies the model is significant. There is only a 0.01 percent chance that a model F-value, this large could occur due to noise alone. The low probability value (<0.0001) indicates that the model is significant. The value of the determination coefficient (R2 = 0.9993) being a measure of goodness of fit to the model indicates a high degree of correlation between the observed value and predicted values. The determination coefficient (R = 0.9996), suggests that more than 99.96 percent of the variance is attributable to the variables and indicated a high significance of the model. Thus, 0.04 percent of the total variance cannot be explained by the model. The fitted model is considered adequate if the F-test is significant (P < 0.05). The analysis of variances
Table 4. Analysis of variance for the quadratic response surface model fitting to the biodegradation data of WBLCO.
(ANOVA) quadratic regression model demonstrated that the model was highly significant, as was evident from the very low probability (P < 0.0001) of the F-test and insignificant result from the Lack of Fit model (P = 0.1339). The Lack of Fit test is performed by comparing the variability of the current model residuals to the variability between observations at replicate settings of the factors. The Lack of Fit F-value of 3.40 implies the Lack of Fit is not significant relative to the pure error. There is a 13.39 percent chance that a Lack of Fit F-value this large could occur due to noise.
The Lack of Fit is designed to determine whether the selected model is adequate to describe the observed data, or whether a more complicated model should be used. The Predicted R-Squared value of 0.9921 is in reasonable agreement with the Adjusted R-Squared value of 0.9985. Adequate Precision measures the signal to noise ratio. A ratio > 4 is desirable. The ratio of 95.765 obtained in this research indicates an adequate signal. This model can be used to navigate the design space. The coefficient of variation (CV) as the ratio of the standard error of estimate to the mean value of the observed response is a measure of reproducibility of the model, generally a model can be considered reasonably reproducible if its CV is not greater than 10 percent. Hence, the low variation coefficient value (CV = 0.17 percent) obtained indicates a high precision and reliability of the experiments.
The coefficient of the model (parameter estimation) and the corresponding P-values are presented in Table 5. The significance of regression coefficients was considered, ignoring those with an insignificant effect on the response at a significance level of 95 percent. The Pvalues of the regression coefficients suggest that among the test variables, linear, quadratic and interaction effects of NPK fertilizer, Tween 80 and mixed culture (biomass) are highly significant. The insignificant effects (factors and interactions) with P-values higher than 0.05, were ignored. In this study, A, B, C, A2, B2, C2, AB, AC and
Table 5. Coefficient of the model for light crude oil biodegradation.
BC are significant model terms.
Thus, statistical analysis of all the experimental data showed that NPK fertilizer, Tween 80 and mixed culture (biomass) concentration had a significant effect on TPH reduction (crude oil removal) during the study. Moreover, it is observed that NPK fertilizer (nutrients) exerted more pronounced linear effect (higher coefficient values) on crude oil removal (TPH reduction). That is, crude oil removal was mostly and positively influenced by NPK fertilizer (nutrients) followed by mixed culture (biomass) and Tween 80 (surfactant). The strong influence of nutrients on petroleum hydrocarbons removal has been clearly shown before in the previous works of Mohajeri et al. [37]. The quadratic effect of the independent amendment variables on the rate of crude oil removal was significant but negative.
Figure 2(a) shows the predicted versus actual plot of kerosene biodegradation. Actual values were determined for a particular run, and the predicted values were calculated from the approximating function used for the model. Figure 2(b) shows the studentized residuals and normal percent probability plot. Residual shows the difference between the observed value of a response measurement and the value that is fitted under the theorized model. Small residual values indicate that model prediction is accurate. The Cooks distance and studentized residuals illustrate the normal distribution and constant variance of the residuals, the goodness of fit, linearity of the fitted model, and the independence. Figure 2(c) shows Cook’s distance plot; according to this plot there were no points that were potentially powerful due to their location in the factor.