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Article

Strain Screening and Conditions Optimization in Microalgae-Based Monosodium Glutamate Wastewater (MSGW) Treatment

1
School of Life Sciences, Ludong University, Yantai 264025, China
2
Department of Economic Management, Yantai Engineering & Technology College, Yantai 264006, China
*
Author to whom correspondence should be addressed.
Water 2023, 15(9), 1663; https://doi.org/10.3390/w15091663
Submission received: 20 March 2023 / Revised: 7 April 2023 / Accepted: 22 April 2023 / Published: 24 April 2023
(This article belongs to the Section Wastewater Treatment and Reuse)

Abstract

:
The wastewater generated from monosodium glutamate production displays distinctive features of elevated salinity, organic content, as well as nitrogen and phosphorus concentrations, and its indiscriminate disposal poses a significant threat to water quality and can cause detrimental impacts on aquatic ecosystems. The application of microalgae for monosodium glutamate wastewater (MSGW) treatment can result in simultaneous wastewater purification and biomass recovery. In this study, the algae species capable of thriving in diluted MSGW were screened, and the wastewater composition and growth conditions were optimized to obtain high algal biomass and nutrient removal rate. Among the tested species, Chlorella sp. FACHB-30 demonstrated superior potential for MSGW treatment and achieved a maximum specific growth rate of 0.28 d−1 and the highest COD removal rate of 61.50% over a 20-day cultivation period with trace metals supplementation in the wastewater. Moreover, the cultivation of Chlorella sp. FACHB-30 yielded considerable reductions in total phosphate (69.09%), total nitrogen (26.93%), and NH 4 + -N (51.91%) levels in the wastewater. The optimum conditions for achieving maximum algal density and highest nutrient removal were determined as light intensity of 150 μmol m−2s−1, inoculation concentration of 1 × 105 cells mL−1, and an iron concentration of 10−5 mol L−1. Finally, under the optimized conditions, the removal rates of total phosphate, total nitrogen, NH 4 + -N, and COD were determined to be 87.60%, 68.05%, 75.89%, and 77.96%, respectively. The findings of this study highlight the potential for enhancing the nutrient removal efficiency of microalgae-based MSGW treatment through the implementation of a combined approach that involves the selection of tolerant strains, optimization of cultivation conditions, and refinement of wastewater composition.

1. Introduction

China produces almost half of the world’s monosodium glutamate (MSG) every year [1]. The discharge of MSG wastewater (MSGW) into the environment can pose serious threats to aquatic ecosystems and human health, such as eutrophication, oxygen depletion, toxicity, acidification, and odor emission [2,3,4]. Various methods have been proposed for the treatment of MSGW, which can be classified into physicochemical and biological methods [5,6]. Physicochemical methods, such as coagulation–flocculation, adsorption, membrane filtration, and microwave catalysis, can remove pollutants rapidly and efficiently under different environmental conditions, but they also entail high capital and operational costs and generate large amounts of sludge [7,8]. Biological methods, such as aerobic and anerobic treatments, are more environmentally friendly and cost-effective, as they can degrade organic matter and reduce sludge production. However, biological methods are sensitive to various factors that affect the microbial activity, such as pH, temperature, salinity, and oxygen concentration [3,9]. MSGW poses several challenges to traditional microbial purification methods due to its high organic matter and suspended hyphae content, elevated acidity, as well as high levels of ammonia nitrogen and sulfate. These characteristics not only exhibit direct or indirect toxicity towards microorganisms but also contribute to increased purification costs. Therefore, it is urgent to develop an eco-friendly and sustainable biological treatment technology for MSGW.
Compared to traditional microbial wastewater treatment, the use of microalgae in wastewater treatment has many advantages. Microalgae have a short life cycle, no agricultural land occupation, high photosynthesis efficiency accompanied by CO2 fixation, good tolerance to environmental factors, and accumulation of high-value biomass that can be exploited as biofuels, feeds, health products, cosmetics, and plant fertilizer, etc. [10,11,12]. However, mass cultivation of microalgae still requires high costs including freshwater and nutrient consumption during cultivation [13]. Microalgae cultivation combined with wastewater treatment can effectively solve the problem. The nitrogen- and phosphorus-rich MSGW does not contain any hazardous or pathogenic substances. Moreover, previous studies have shown that the utilization of diluted MSGW can be advantageous for microalgal growth, while simultaneously reducing the costs associated with nutrient supplementation during cultivation [14,15]. Meanwhile, the wastewater is purified and even recycled, which makes wastewater as a nutrient source for the cultivation of microalgae a potentially economically viable and environmentally friendly method.
Due to the high concentration of ammonia nitrogen and suspended matter, only a few microalgae can survive and thrive in the undiluted MSGW. This is also a key bottleneck in using wastewater as a nutrient source to cultivate microalgae [16]. Most of the tests were conducted in diluted or simulated wastewater to reduce the toxicity of pollutants. The cultivation of Chlorella sp. FACHB-31 and C. vulgaris FACHB-8 in diluted swine wastewater was found to be feasible, with both species exhibiting high removal rates for total nitrogen (TN), total phosphorus (TP), and NH 4 + -N over a 15-day treatment period [17]. Specifically, C. vulgaris FACHB-8 achieved superior removal rates, with 89.85%, 93.68%, and 97.86% for TN, TP, and NH 4 + -N, respectively. When Scenedesmus obliquus was used to treat the diluted Agro-Zootechnical digestate for 21 days, the NH 4 + -N removal efficiency reached 83% [18]. Wu et al. treated simulated industrial wastewater with Chlamydomonas sp. TAI-2 for 16 days, and the removal rates of NH 4 + -N and PO 4 3 -P reached 100% and 33%, respectively [19]. However, excessive dilution of wastewater often increases the cost of wastewater treatment. Therefore, it is necessary to screen the microalgae species that can grow fast in wastewater with a high nutrient level of MSGW. This demand can be attributed to a combined strategy, that is selecting the tolerant strains, improving the wastewater composition, and optimizing the cultivation conditions. However, limited species and strains of microalgae were screened according to this strategy [4]. Liu et al. [4] explored the growth and main metabolites production of Scenedesmus sp. SDEC-8, Golenkinia sp. SDEC-16, and C. sorokiniana SDEC-18 in seawater medium supplemented with MSGW. Yu et al. [20] further optimized the seawater algae Phaeodactylum tricornutum and Nannochloropsis oceanica in a seawater medium supplemented with MSGW. Other reports mainly concentrate on C. vulgaris or Spirulina subsalsa cultivated with diluted MSGW [15,21,22]. All these studies focus on either strain selection or wastewater composition and growth condition improvement, the combination of the two aspects is rarely reported.
Microalgae are a promising resource for the production of bioactive substances and biofuels [23]. Therefore, treating MSGW with microalgae can achieve both pollution removal and biomass valorization [24]. Instead of regarding MSGW as a waste, it can be considered as a nutrient-rich medium for microalgae cultivation [25]. In this study, we aim to select microalgae strains that can tolerate MSGW and optimize the wastewater composition and growth conditions for maximum biomass production. The findings will support the economic benefits of MSGW utilization and enhance the feasibility and commercial viability of microalgae-based MSGW treatment.

2. Materials and Methods

2.1. Microalgal Strains, Culture Conditions, and MSGW Preparation

Six distinct strains of single-celled green algae were used in this study. C. sorokiniana FACHB-275, Chlorella sp. FACHB-3, Chlorella sp. FACHB-9, Chlamydomonas reinhardtii FACHB-479, and Tetradesmus obliquus FACHB-416 strains were acquired from the Freshwater Algae Culture Collection at the Institute of Hydrobiology in China. The strain C. sorokiniana GXNN01 was isolated from a wastewater treatment pond of a cassava starch factory in Nanning City, Guangxi province, China [26]. Algal cultures were initially grown in BG-11 medium [27], at 25 ± 1 °C, in a light incubator GDN-260A (Ningbo, China). The light intensity of 90 μmol m−2 s−1 with a photoperiod cycle of 12:12 h light/dark was provided by LED arrays with 6500 K LED cool daylight above the culture. The culture was manually shaken 2 times a day. At the beginning of experiments, algal cultures in the logarithmic growth phase were collected via centrifugation at 4000× g for 10 min and washed with distilled water as the inoculum. Subsequently, the resulting pellets were resuspended in a 250 mL flask with 150 mL modulated medium.
The MSGW was provided by the Linghua Group Co. Ltd., located in Jining City, Shandong Province. The wastewater was allowed to settle for a period of 24 h before undergoing two rounds of centrifugation at 4000× g for 5 min each, and the supernatant was then filtered through 0.45 μm membrane and stored at −20 °C for later use. The initial MSGW characteristics were as follows: COD, 347,562.5 ± 11,226.83 mg L−1; TN, 46,526.32 ± 4211.40 mg L−1; TP, 2756.15 ± 163.77 mg L−1; NH 4 + -N, 16,281.75 ± 567.47 mg L−1; and pH, 4.01 ± 0.01.

2.2. Experimental Design

2.2.1. Screening of MSGW Dilution Factor for Promoting Microalgal Growth

C. sorokiniana GXNN01 was selected as the model for MSGW dilution factor optimization. In order to identify the optimal dilution factor for cultivating microalgae, MSGW were prepared at varying dilution multiples (500, 600, 700, 800, 900, and 1000). Following the aforementioned cell collection protocol, the resulting cells were introduced into 250 mL Erlenmeyer flasks containing 150 mL of autoclaved MSGW at an initial density of 5 × 105 cells mL−1. The other conditions were given as mentioned above. Each treatment was repeated four times. Cell growth was monitored every 2 days.

2.2.2. Selection of Microalgae Species Suitable for Cultivation in MSGW

According to the above experimental results, the appropriate dilution factor was initially screened. Thereafter, six algae species were selected for the best growth performance in MSGW of 1000-fold dilution. Three media were used: (1) BBM medium [28] as control, (2) MSGW of 1000-fold dilution (1000MSGW), and (3) MSGW of 1000-fold dilution with BBM trace metals solution (1000MSGW + TMs). The cells were cultured in autoclaved media with an initial density of 1 × 105 cells mL−1 and pH adjusted to 7.2. The other conditions were given as mentioned above. For each algal species, four parallel samples were established. Cell growth was monitored every 2 days.
The COD, TN, TP, and NH 4 + -N concentrations were determined before and after the experiments.

2.2.3. Batch Experiments for Optimization of Cultivation Condition

To investigate the optimum cultivation condition for the selected strain suitable for cultivation in MSGW, a series of batch cultivation experiments were carried out. The effect of inoculation densities, initial Fe3+ concentrations, and light intensities on microalgae growth and nutrient removal rate in the 1000MSGW + TMs medium was evaluated by performing cultivation tests under different inoculation densities (5 × 106, 1 × 106, 5 × 105, and 1 × 105 cells mL−1), initial Fe3+ concentrations (1 × 10−4, 1 × 10−5, 1 × 10−6, and 1 × 10−7 mol L−1 in the form of ferric chloride), and light intensities (20, 50, 100, and 150 μmol m−2 s−1). In each cultivation test, one parameter was changed while maintaining the other parameters constant. All the experiments were repeated four times.

2.3. Analytical Methods

2.3.1. Determination of Cell Growth

The collected cultures were observed under a microscope using the Neubauer-improved chamber (Marienfeld, Lauda-Konigshofen, Germany), and the cell growth was recorded. The specific growth rate (μ) during the exponential phase was determined using Equation (1).
μ = lnD 2 lnD 1 / t 2 t 1
where D1 and D2 represent the algal density at two distinct cultivation timepoints, t1 and t2, respectively.
The biomass concentration was determined by subjecting samples of microalgal cells to washing and subsequent drying in an oven set to 105 °C for 3 h.

2.3.2. Determination of COD, TN, TP, and NH 4 + -N

The cultures (5 mL) were taken at the end of the experiments and centrifuged at 9000× g for 10 min. The COD, TN, TP, and NH 4 + -N concentrations of the supernatant were determined according to Chinese national standard, using fast digestion-spectrophotometric method (HJ/T 399-2007), alkaline potassium persulfate digestion UV spectrophotometric method (GB 11894-1989), ammonium molybdate spectrophotometric method (GB 11893-1989), and Nessler’s reagent colorimetric method (GB 7479-1987), respectively.

2.4. Statistical Analysis

The mean and standard deviation (SD) of the four replicates were reported as experimental results. The normality and heterogeneity of variances were assessed using the Kolmogorov–Smirnov test and Levene’s F-test, respectively. The one-way analysis of variance (ANOVA) was used to determine the significant difference between the means, and then the Duncan multiple-range test was performed at the probability level of p < 0.05. All statistical analyses were conducted utilizing IBM SPSS statistics version 20.0 (IBM, Chicago, IL, USA).

3. Results

3.1. Microalgae Species Screening Based on Growth Performance and Removal of Nutrients

The growth curve of C. sorokiniana GXNN-01 in diluted MSGW is shown in Figure 1. The results showed that C. sorokiniana GXNN-01 grew better with the increasing dilution multiples, and the best growth performance was obtained at the dilution multiples of 1000. At the end of cultivation, the cell density of 1000-dilution multiples increased to 7.78 × 106 cells mL−1, which had no significant difference from that of 900-dilution multiples (p > 0.05; F value = 31.262). Moreover, the cell densities of other MSGW dilution multiples were low, which indicated that these dilution multiples containing a high concentration of nutrient salts had a certain inhibition effect on the growth of the alga.
Based on the above findings, the growth performance of six microalgae strains in MSGW of 1000-dilution multiples was further explored (Figure 2). According to the growth performance of six strains in different media, four groups can be divided. Group I including FACHB-9 and FACHB-30 showed a growth trend of 1000MSGW + TMs > 1000MSGW > BBM. Group II including GXNN-01 and FACHB-275 showed a growth trend of 1000MSGW + TMs ≈ 1000MSGW > BBM. Group III represented by FACHB-479 had no significant differences among the three media. Group IV represented by FACHB-416 showed a growth trend of 1000MSGW + TMs > BBM > 1000MSGW. FACHB-9 obtained the highest cell density of 2.42 × 107 cells mL−1 after 20 days of culture in the 1000MSGW + TMs. The specific growth rate (μ) of six strains grown in different media is compared (Table 1). The values of 0.27 d−1 and 0.28 d−1 appeared in the FACHB-9 and FACHB-30 groups grown in the 1000MSGW + TMs, respectively, which were significantly higher than other groups.
Figure 3a shows that the removal rate of TP by FACHB-30 was significantly higher than those of the other five species. However, the TP removal rate of FACHB-30 without TMs (56.46 ± 2.92%) was significantly lower than that of the TMs group (69.09 ± 2.57%) (p < 0.05). The removal efficiencies of TN and NH 4 + -N by FACHB-9 and FACHB-30 with or without TMs were significantly higher than those of the other species (p < 0.05). The removal rate of TN by FACHB-9 (30.02 ± 1.12%) was significantly higher than that by FACHB-30 (26.93 ± 0.82%) (p < 0.05). In terms of NH 4 + -N, the removal efficiencies of FACHB-9 and FACHB-30 grown in the 1000MSGW + TMs had no significant differences (p > 0.05) and were significantly higher than those of the other species (p < 0.05). The removal efficiency of COD by FACHB-30 (61.50 ± 3.75%) grown in the 1000MSGW + TMs was significantly higher than those by the other species (p < 0.05).
Wastewater treatment should compromise the specific growth rate and nutrient removal rate. According to the above results, FACHB-30 was selected as the dominant algal species in MSGW treatment, which was further investigated in this study.

3.2. Growth of FACHB-30 under Different Light Intensities

The final cell densities of FACHB-30 at 150 and 100 μmol m−2s−1 up to 2.07 × 107 cells mL−1 and 1.95 × 107 cells mL−1 were significantly higher than those under low light intensities (p < 0.05, Figure 4). Meanwhile, it can be seen from Figure 5 that the removal efficiencies of nutrients were correlated with the values of cell intensities. The highest nutrients removal rates in the four experimental groups all appeared in the light intensity of 150 μmol m−2 s−1. However, there were no significant differences in the removal rates of TP, TN, and NH 4 + -N between the group of 150 and 100 μmol m−2 s−1 (p > 0.05).

3.3. Growth of FACHB-30 under Different Initial Inoculum Concentrations

There were no significant differences among the final cell densities among the groups of 5 × 105, 1 × 106, and 5 × 106 cells mL−1 (p > 0.05). However, these three groups were all significantly higher than the group of 1 × 105 (p < 0.05, Figure 6a). When compared to the specific growth rate, the group of 1 × 105 was significantly higher than other groups (p < 0.05, Figure 6b). The nutrient removal rates did not show a rising trend with increasing initial inoculum concentrations and final cell intensities. The NH 4 + -N and TP removal rates of 5 × 106 were significantly lower than those of other groups (p < 0.05, Figure 7a,c).

3.4. Growth of FACHB-30 under Different Fe3+ Concentrations

As indicated in Figure 8, the growth curves of FACHB-30 were affected by the Fe3+ concentrations in MSGW. The optimum Fe3+ concentration for cell growth was 10−5 mol L−1. The nutrients removal rates coincided well with the change in final cell densities (Figure 9). However, only NH 4 + -N removal rate of 10−5 mol L−1 was significantly higher than those of other concentrations (p < 0.05).

3.5. Comparison of the Nutrient Removal Rate and Biomass Production before and after Optimization

After the optimization of light intensity, iron concentration, and initial inoculum, the removal rates of TP, TN, NH 4 + -N, and COD were significantly increased from 69.10 ± 2.57% to 87.60 ± 1.50%, 26.93 ± 0.82% to 68.05 ± 3.89%, 51.91 ± 1.28% to 75.89 ± 1.82%, and 61.50 ± 3.75% to 77.96 ± 2.95% (p < 0.01, Table 2), respectively. The removal rate of TP after optimization was still the highest among the four parameters. However, the highest increasing rate of TN removal rate up to 152.69% was observed among the nutrients determined. The final biomass concentration was also significantly increased by 18.98% (p < 0.05) and reached 1.423 ± 0.018 g L−1.

4. Discussion

4.1. The Selecting of the Tolerant Strains Grown in the MSGW

Microalgae can grow rapidly under favorable culture conditions with sufficient nutrients. As shown in Figure 1, MSGW contains macronutrients such as nitrogen and phosphorus that are essential for algal growth; however, high levels of nutrient salts in the MSGW diluted 500–800 times prevented cell reproduction. It is likely due to the high concentration of wastewater containing high levels of organic or inorganic compounds, which were toxic to microorganisms [29,30]. Jiang et al. [14] speculated that the stress caused by the high initial concentration of ammonia (≥20 mg L−1 in MSGW diluted 500–800 times in the present study) may be the main reason for the cell growth inhibition [22]. The final cell density of the 1000-times dilution group was higher than that of the 900-times dilution group, although there were no significant differences, indicating that both dilution factors were suitable for successive optimization. For ease of operation, a 1000-times dilution was selected for the screening of the tolerant strains grown in the MSGW.
Different levels of tolerance to the MSGW were observed among the six strains. The growth rates of most Chlorella strains were higher than Chlamydomonas and Tetradesmus strains (Table 1). Chlorella is commonly used for microalgae-based wastewater treatment due to its high adaptability to different types of wastewaters [31,32,33]. Furthermore, Chlorella sp. FACHB-9 and FACHB-30 performed best among the Chlorella strains. Liu et al. [34] also reported the different growth performances of Chlorella strains in swine wastewater. One possible reason is that the traditional Chlorella taxa are dispersed over two classes of chlorophytes, the Trebouxiophyceae and the Chlorophyceae, and certain heterogeneity is observed in the rRNA similarity and biochemical and physiological properties even in the same species [35].
The MSGW plus TMs medium resulted in better growth performance than the MGSW or BBM medium in FACHB-9 and FACHB-30 (Figure 2), which suggested the diluted MSGW did not have enough TMs for the algae to grow. Even though trace metal elements of various kinds are present in MSGW, the concentration of cobalt (Co2+), molybdenum (Mo2+), and manganese (Mn2+) in MSGW diluted 1000 times would be very low, up to 10−9 mg L−1 [36]. However, Co2+ and Mo2+ at a concentration of 10−3 mg L−1 and Mn2+ at a concentration of 10−2 mg L−1 were found to be necessary for the best growth of algae [37,38]. Other reports about wastewater treatment with microalgae also emphasized the importance of the TMs addition to the medium [39,40].

4.2. Optimizing the Conditions for the Maximum Biomass Production and Nutrient Removal Rates

4.2.1. Light Intensity

Light intensity and biomass increase had a positive correlation in FACHB-30 (Figure 4). Generally, there is a certain level of light that is best for microalgae to grow [41]. The optimal light level for microalgae growth can vary in wastewater since it has low light penetration and harmful substances. Kiran and Mohan [42] reported an optimum light intensity of 100 µmol m−2s−1 when using C. sorokiniana to treat dairy wastewater, which was similar to the present study of 100–150 µmol m−2s−1. However, Qu et al. [43] found that the best light intensity for growing Parachlorella kessleri in real swine wastewater was 600 µmol m−2s−1.
There was also a positive correlation between light intensity and nutrient removal rate. However, low light intensity (20 μmol m−2 s−1) reduced the removal rates of TN and NH 4 + -N more than those of TP and COD compared to high light intensity (Figure 5). The reason may be that high light intensity induced photosynthesis-related protein synthesis, and more nitrogen is required under high light [44,45].

4.2.2. Initial Inoculum Concentration

Although the groups with high inoculum concentration had the advantage in the final cell density, the inoculum concentration of 1 × 105 cells mL−1 was the highest from the perspective of specific growth rate (Figure 6), which may be due to the competition between light and nutrients among cells with the increase in inoculum concentration. Studies have shown that the biomass tended to decline when the inoculum concentration exceeded a certain value [46]. In this study, it was also observed that the inoculum of 5 × 106 cells mL−1 had yellowing and precipitation in the process of culture. In terms of nutrient removal rate, when the inoculum concentration reached 5 × 106 cells mL−1, the removal rate did not increase significantly with the increase in the inoculum concentration (Figure 7). A high inoculum concentration may shorten the lag phase and accelerate the growth of microalgae in MSGW, but it may also reduce light availability and photosynthesis due to cell shading. This is consistent with the nutrient removal rate that depends on light intensity as indicated by Figure 5. Wang et al. [47] and Lao et al. [48] also reported that the nutrient removal rate did not increase with the increasing inoculum concentration in the wastewater.

4.2.3. Fe3+ Concentrations

Iron plays an important role in regulating the growth and community composition of phytoplankton. It is ferric iron that is absorbed and utilized by algae. In the laboratory culture experiment, Park et al. found that iron could promote the growth rate of marine Chlorella, and the content of intracellular chlorophyll was also increased. Studies have shown that with the increase in iron concentration, algae will show a rapid growth trend and also increase the absorption of N and P [49]. High iron concentration enhances algal photosynthesis by increasing the synthesis of proteins and enzymes related to the light reaction and Calvin cycle, which results in more ATP and NADPH production and a higher carbon fixation rate. However, compared with the Fe3+ concentration of 10−4 mol L−1, FACHB-30 at 10−5 mol L−1 had the highest final cell density and nutrient removal rate among the four groups (Figure 8 and Figure 9), probably because excessive iron would produce a large amount of reactive oxygen species [50], which caused oxidative damage to the photosynthetic membrane of the cells [51,52]. The optimal Fe3+ concentration for maximizing biomass production of C. pyrenoidosa during municipal wastewater treatment was determined to be 2.88 × 10−5 mol L−1 [53]. The expression levels of accD and rbcL genes, encoding acetyl-CoA carboxylase (ACC) and ribulose bisphosphate carboxylase large chain (RuBisCO), respectively, reached the highest level in C. vulgaris under the iron concentration of 9 × 10−5 mol L−1 [54].
The nutrient removal rate also correlated well with the iron concentration. However, low iron concentration (10−7 mol L−1) reduced the removal rates of TN and NH 4 + -N more than those of TP and COD compared to high iron concentration (Figure 9). The reason may be the same as the light intensity as mentioned above. Because high iron concentration also induces photosynthesis-related protein synthesis [54], more nitrogen is required for the operation of photosynthesis.

4.3. Comparison of Other Research for the MSGW Treatment

The optimization of light intensity, iron concentration, and initial inoculum resulted in a 27% to 153% increase in the removal rates of all nutrients, as illustrated in Table 2. The most significant improvement after optimization was observed in the TN removal rate, with the optimization of light conditions being the primary contributing factor (Figure 5). This finding is consistent with the report of Rani and Maróti [55], who demonstrated that the nitrate removal of green microalgae from synthetic wastewater was dependent on light color as well as light intensity. After optimization, the maximum biomass could reach 1.423 g L−1, which is comparable to the highest biomass reported in many studies about the MSGW treatment. The cultivation of P. tricornutum with MSGW mixed in seawater resulted in the highest biomass of 0.93 g L−1 [20]. Jiang et al. [22] achieved the highest biomass of 2.862 g L−1 when treating MSGW with S. subsalsa, while they reported a maximum biomass of 1.46 g L−1 when using C. vulgaris in a separate study [21]. In short, further optimization of conditions still has the potential to increase the current biomass production.

5. Conclusions

Based on the criteria of growth and nutrient removal, Chlorella sp. FACHB-30 was identified as the most suitable strain for the MSGW treatment among the screened candidates. The optimal MSGW purification effect of microalgae was observed when the light intensity reached 150 µmol m−2 s−1, the inoculum concentration started at 1 × 105 cells mL−1, and the initial Fe3+ concentration in the wastewater was 10−5 mol L−1. Through conditions optimization, the removal rates of TP, TN, NH 4 + -N, and COD increased from 69.10% to 87.60%, 26.93% to 68.05%, 51.91% to 75.89%, and 61.50% to 77.96%, respectively. The present study demonstrates that the nutrient removal efficiency of microalgae-based wastewater treatment can be significantly improved by applying a combined strategy of selecting tolerant strains, improving wastewater composition, and optimizing cultivation conditions. The findings of this study can serve as a valuable reference for future research and development aimed at enhancing the efficacy of microalgae-based treatment of MSGW.

Author Contributions

Conceptualization, Y.Z., Q.S., and H.Q.; methodology, Y.Z. and H.Q.; software, Q.S.; validation, Y.Z. and H.Q.; formal analysis, Y.Z., H.W., and C.W.; investigation, Y.Z. and H.Q.; resources, S.T. and H.Q.; data curation, Q.S.; writing—original draft preparation, Y.Z. and H.Q.; writing—review and editing, Y.Z., J.Z., and H.Q.; visualization, Q.S.; supervision, H.Q.; project administration, S.T. and H.Q.; funding acquisition, H.Q. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China (grant No. 32072997), Talent Induction Program for Youth Innovation Teams in Colleges and Universities of Shandong Province (2022-2024), Major Applied Technology Innovation Project of Ludong University (2022), the open project of Rongcheng Marine Industrial Technology Research Institute, Ludong University (KF20180003), Major Agricultural Application Technology Innovation Project of Shandong Province (SD2019YY010), and Natural Science Foundation of Shandong Province (ZR2020QC042).

Data Availability Statement

Not applicable.

Acknowledgments

The authors express their gratitude to Qingrong Huang and Yanhua Wang for their valuable assistance in experimental preparation.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

References

  1. Dong, L.; Li, Y.; Wang, P.; Feng, Z.; Ding, N. Cleaner production of monosodium glutamate in China. J. Clean. Prod. 2018, 190, 452–461. [Google Scholar] [CrossRef]
  2. Chen, H.; Wei, Y.; Liang, P.; Wang, C.; Hu, Y.; Xie, M.; Wang, Y.; Xiao, B.; Du, C.; Tian, H. Performance and microbial community variations of a upflow anaerobic sludge blanket (UASB) reactor for treating monosodium glutamate wastewater: Effects of organic loading rate. J. Environ. Manag. 2020, 253, 109691. [Google Scholar] [CrossRef] [PubMed]
  3. Yang, Q.; Yang, M.; Zhang, S.; Lv, W. Treatment of wastewater from a monosodium glutamate manufacturing plant using successive yeast and activated sludge systems. Process Biochem. 2004, 40, 2483–2488. [Google Scholar] [CrossRef]
  4. Liu, M.; Yu, Z.; Jiang, L.; Hou, Q.; Xie, Z.; Ma, M.; Yu, S.; Pei, H. Monosodium glutamate wastewater assisted seawater to increase lipid productivity in single-celled algae. Renew. Energy 2021, 179, 1793–1802. [Google Scholar] [CrossRef]
  5. Singh, S.; Refeha, P.D.; Arun, A.B.; Huang, Y.M.; Shen, F.T.; Young, C.C. Wastewater from monosodium glutamate industry as a low cost fertilizer source for corn (Zea mays L.). Biomass Bioenergy 2011, 35, 4001–4007. [Google Scholar] [CrossRef]
  6. Chen, W.J.; Su, W.T.; Hsu, H.Y. Continuous flow electrocoagulation for MSG wastewater treatment using polymer coagulants via mixture-process design and response-surface methods. J. Taiwan Inst. Chem. Eng. 2012, 43, 246–255. [Google Scholar] [CrossRef]
  7. Jin, R.; Zhang, Q.; Liu, J.; Yang, B.; Wu, K.; Zheng, P. Performance and stability of the partial nitrification process for nitrogen removal from monosodium glutamate wastewater. Sep. Purif. Technol. 2013, 103, 195–202. [Google Scholar] [CrossRef]
  8. Li, H.; Yu, J.; Gong, Y.; Lin, N.; Yang, Q.; Zhang, X.; Wang, Y. Perovskite catalysts with different dimensionalities for environmental and energy applications: A review. Sep. Purif. Technol. 2023, 307, 122716. [Google Scholar] [CrossRef]
  9. Liu, J.; Yue, Q.; Gao, B.; Ma, Z.; Zhang, P. Microbial treatment of the monosodium glutamate wastewater by Lipomyces starkeyi to produce microbial lipid. Bioresour. Technol. 2011, 106, 69–73. [Google Scholar] [CrossRef]
  10. Cheng, P.; Chu, R.; Zhang, X.; Song, L.; Chen, D.; Zhou, C.; Yan, X.; Cheng, J.J.; Ruan, R. Screening of the dominant Chlorella pyrenoidosa for biofilm attached culture and feed production while treating swine wastewater. Bioresour. Technol. 2020, 318, 124054. [Google Scholar] [CrossRef]
  11. Rizwan, M.; Mujtaba, G.; Memon, S.A.; Lee, K.; Rashid, N. Exploring the potential of microalgae for new biotechnology applications and beyond: A review. Renew. Sustain. Energy Rev. 2018, 92, 394–404. [Google Scholar] [CrossRef]
  12. Chew, K.W.; Yap, J.Y.; Show, P.L.; Suan, N.H.; Juan, J.C.; Ling, T.C.; Lee, D.J.; Chang, J.S. Microalgae biorefinery: High value products perspectives. Bioresour. Technol. 2017, 229, 53–62. [Google Scholar] [CrossRef] [PubMed]
  13. Raheem, A.; Prinsen, P.; Vuppaladadiyam, A.K.; Zhao, M.; Luque, R. A review on sustainable microalgae based biofuel and bioenergy production: Recent developments. J. Clean. Prod. 2018, 181, 42–59. [Google Scholar] [CrossRef]
  14. Jiang, L.; Sun, J.; Nie, C.; Li, Y.; Jenkins, J.; Pei, H. Filamentous cyanobacteria triples oil production in seawater-based medium supplemented with industrial waste: Monosodium glutamate residue. Biotechnol. Biofuels 2019, 12, 1–16. [Google Scholar] [CrossRef] [PubMed]
  15. Ji, Y.; Hu, W.; Li, X.; Ma, G.; Song, M.; Pei, H. Mixotrophic growth and biochemical analysis of Chlorella vulgaris cultivated with diluted monosodium glutamate wastewater. Bioresour. Technol. 2014, 152, 471–476. [Google Scholar] [CrossRef]
  16. Wang, S.; Wang, X.; Miao, J.; Tian, Y. Tofu whey wastewater is a promising basal medium for microalgae culture. Bioresour. Technol. 2018, 253, 79–84. [Google Scholar] [CrossRef]
  17. Chen, Z.; Xiao, Y.; Liu, T.; Yuan, M.; Liu, G.; Fang, J.; Yang, B. Exploration of microalgal species for nutrient removal from anaerobically digested swine wastewater and potential lipids production. Microorganisms 2021, 9, 2469. [Google Scholar] [CrossRef] [PubMed]
  18. Franchino, M.; Comino, E.; Bona, F.; Riggio, V.A. Growth of three microalgae strains and nutrient removal from an agro-zootechnical digestate. Chemosphere 2013, 92, 738–744. [Google Scholar] [CrossRef]
  19. Li, F.W.; Pei, C.C.; Ai, P.H.; Chi, M.L. The feasibility of biodiesel production by microalgae using industrial wastewater. Bioresour. Technol. 2012, 113, 14–18. [Google Scholar]
  20. Yu, S.; Yu, Z.; Hou, Q.; Pei, H. Seawater with added monosodium glutamate residue (MSGR) is a promising medium for the cultivation of two commercial marine microalgae. Water 2022, 14, 975. [Google Scholar] [CrossRef]
  21. Jiang, L.; Ji, Y.; Hu, W.; Pei, H.; Nie, C.; Ma, G.; Song, M. Adjusting irradiance to enhance growth and lipid production of Chlorella vulgaris cultivated with monosodium glutamate wastewater. J. Photochem. Photobiol. B Biol. 2016, 162, 619–624. [Google Scholar] [CrossRef]
  22. Jiang, L.; Pei, H.; Hu, W.; Ji, Y.; Han, L.; Ma, G. The feasibility of using complex wastewater from a monosodium glutamate factory to cultivate Spirulina subsalsa and accumulate biochemical composition. Bioresour. Technol. 2015, 180, 304–310. [Google Scholar] [CrossRef]
  23. Aron, N.; Khoo, K.S.; Chew, K.W.; Veeramuthu, A.; Show, P.L. Microalgae cultivation in wastewater and potential processing strategies using solvent and membrane separation technologies. J. Water Process Eng. 2020, 39, 101701. [Google Scholar] [CrossRef]
  24. Abdallah, A.; Samir, A.S.; Hassan, R.; Ibrahim, E.-A.E.; Reham, E.; Shih-Hsin, H.; Tamer, E.; Shengnan, L.; El-Sheekh, M.M.; Schagerl, M. Microalgae-based wastewater treatment: Mechanisms, challenges, recent advances, and future prospects. Environ. Sci. Ecotechnol. 2023, 13, 100205. [Google Scholar]
  25. Do, C.V.T.; Pham, M.H.T.; Pham, T.Y.T.; Dinh, C.T.; Bui, T.U.T.; Tran, T.D. Microalgae and bioremediation of domestic wastewater. Curr. Opin. Green Sustain. Chem. 2022, 34, 100595. [Google Scholar] [CrossRef]
  26. Qiao, H.; Wang, G.; Zhang, X. Isolation and characterization of Chlorella sorokiniana GXNN01 (chlorophyta) with the properties of heterotrephic and microaerobic growth. J. Phycol. 2009, 45, 1153–1162. [Google Scholar] [CrossRef] [PubMed]
  27. Stanier, R.Y.; Kunisawa, R.; Mandel, M.; Cohen-Bazire, G. Purification and properties of unicellular blue-green algae (order Chroococcales). Bacteriol. Rev. 1971, 35, 171–205. [Google Scholar] [CrossRef]
  28. Graham, J.E.S.; Hutchinson, T.C. The role of temperature and heterotrophism in determining crude oil toxicity. Water Qual. Res. J. 1975, 10, 73–83. [Google Scholar] [CrossRef]
  29. Singh, S.; Rekha, P.D.; Arun, A.B.; Hameed, A.; Singh, S.; Shen, F.-T.; Young, C.-C. Glutamate wastewater as a culture medium for Azospirillum rugosum production and its impact on plant growth. Biol. Fertil. Soils 2011, 47, 419–426. [Google Scholar] [CrossRef]
  30. Jia, C.; Kang, R.; Zhang, Y.; Zhang, Y.; Cong, W. Degradation and decolorization of monosodium glutamate wastewater with Coriolus versicolor. Biodegradation 2007, 18, 551–557. [Google Scholar] [CrossRef]
  31. You, K.; Ge, F.; Wu, X.; Song, K.; Yang, Z.; Zhang, Q.; Liu, Y.; Roger, R.; Zheng, H. Nutrients recovery from piggery wastewater and starch wastewater via microalgae-bacteria consortia. Algal Res. 2021, 60, 102551. [Google Scholar] [CrossRef]
  32. Li, K.; Liu, Q.; Fang, F.; Luo, R.; Lu, Q.; Zhou, W.; Huo, S.; Cheng, P.; Liu, J.; Addy, M.; et al. Microalgae-based wastewater treatment for nutrients recovery: A review. Bioresour. Technol. 2019, 291, 121934. [Google Scholar] [CrossRef]
  33. Song, Y.; Wang, L.; Qiang, X.; Gu, W.; Ma, Z.; Wang, G. The promising way to treat wastewater by microalgae: Approaches, mechanisms, applications and challenges. J. Water Process Eng. 2022, 49, 103012. [Google Scholar] [CrossRef]
  34. Liu, X.; Hong, Y.; Zhao, G.; Zhang, H.; Zhai, Q.; Wang, Q. Microalgae-based swine wastewater treatment: Strain screening, conditions optimization, physiological activity and biomass potential. Sci. Total Environ. 2021, 807, 151008. [Google Scholar] [CrossRef] [PubMed]
  35. Huss, V.A.R.; Frank, C.; Hartmann, E.C.; Hirmer, M.; Kloboucek, A.; Seidel, B.M.; Wenzeler, P.; Kessler, E. Biochemical taxonomy and molecular phylogeny of the fenus Chlorella sensu lato (chlorophyta). J. Phycol. 1999, 35, 587–598. [Google Scholar] [CrossRef]
  36. Cheng, S.; Cut, Y.; Liu, Y.; Xia, F.; Ding, S. The effect of heavy metal or metal elements pollution on biological treatment and comprehensive utilization for monosodium glutamate wastewater. Environ. Chem. 1995, 05, 454–459. [Google Scholar]
  37. Chen, M.; Tang, H.; Ma, H.; Holland, T.C.; Ng, K.Y.S.; Salley, S.O. Effect of nutrients on growth and lipid accumulation in the green algae Dunaliella tertiolecta. Bioresour. Technol. 2010, 102, 1649–1655. [Google Scholar] [CrossRef]
  38. Sun, Y.; Huang, Y. Effect of trace elements on biomass, lipid productivity and fatty acid composition in Chlorella sorokiniana. Braz. J. Bot. 2017, 40, 871–881. [Google Scholar] [CrossRef]
  39. Tuantet, K.; Janssen, M.; Temmink, H.; Zeeman, G.; Wijffels, R.H.; Buisman, C.J.N. Microalgae growth on concentrated human urine. J. Appl. Phycol. 2014, 26, 287–297. [Google Scholar] [CrossRef]
  40. Wang, H.; Liu, Z.; Cui, D.; Liu, Y.; Yang, L.; Chen, H.; Qiu, G.; Geng, Y.; Xiong, Z.; Shao, P.; et al. A pilot scale study on the treatment of rare earth tailings (REEs) wastewater with low C/N ratio using microalgae photobioreactor. J. Environ. Manag. 2023, 328, 125593. [Google Scholar] [CrossRef]
  41. Kathirvel, B.; Thangavel, M.; Rene, R.E.; Sabarathinam, S.; Lan, C.N.T.; Arivalagan, P. Impact of cultivation conditions on the biomass and lipid in microalgae with an emphasis on biodiesel. Fuel 2021, 284, 119058. [Google Scholar]
  42. Boda, R.K.; Venkata Mohan, S. Photosynthetic transients in Chlorella sorokiniana during phycoremediation of dairy wastewater under distinct light intensities. Bioresour. Technol. 2021, 340, 125593. [Google Scholar]
  43. Qu, W.; Zhang, C.; Zhang, Y.; Ho, S.-H. Optimizing real swine wastewater treatment with maximum carbohydrate production by a newly isolated indigenous microalga Parachlorella kessleri QWY28. Bioresour. Technol. 2019, 289, 121702. [Google Scholar] [CrossRef] [PubMed]
  44. Feng, L.; Raza, M.A.; Li, Z.; Chen, Y.; Khalid, M.H.B.; Du, J.; Liu, W.; Wu, X.; Song, C.; Yu, L.; et al. The influence of light intensity and leaf movement on photosynthesis characteristics and carbon balance of soybean. Front. Plant Sci. 2019, 9, 1952. [Google Scholar] [CrossRef]
  45. Serena, S.; Fernie, A.R.; Peter, G.; Dario, L.; Torsten, M.; Belen, N.; Ekkehard, N.H. Chloroplasts are key players to cope with light and temperature stress. Trends Plant Sci. 2022, 27, 577–587. [Google Scholar]
  46. Li, S.F.; Fanesi, A.; Martin, T.; Lopes, F. Biomass production and physiology of Chlorella vulgaris during the early stages of immobilized state are affected by light intensity and inoculum cell density. Algal Res. 2021, 59, 102453. [Google Scholar] [CrossRef]
  47. Wang, P.; Shao, Y.; Geng, Y.; Rubina, M.; Yang, W.; Li, M.; Sun, X.; Wang, H.; Chen, G. Advanced treatment of secondary effluent from wastewater treatment plant by a newly isolated microalga Desmodesmus sp. SNN1-13. Front. Microbiol. 2023, 14, 1111468. [Google Scholar] [CrossRef] [PubMed]
  48. Lau, P.S.; Tam, N.F.Y.; Wong, Y.S. Effect of algal density on nutrient removal from primary settled wastewater. Environ. Pollut. 1995, 89, 59–66. [Google Scholar] [CrossRef]
  49. Park, S.; Ahn, Y.; Park, Y.-T.; Ji, M.-K.; Choi, J. The effect of mixed wastewaters on the biomass production and biochemical content of microalgae. Energies 2019, 12, 12183431. [Google Scholar] [CrossRef]
  50. Kampfenkel, K.; Van Montagu, M.; Inze, D. Effects of iron excess on nicotiana plumbaginifolia plants (implications to oxidative stress). Plant Physiol. 1995, 107, 725–735. [Google Scholar] [CrossRef]
  51. Gallego, S.M.; Benavídes, M.P.; Tomaro, M.L. Effect of heavy metal ion excess on sunflower leaves: Evidence for involvement of oxidative stress. Plant Sci. 1996, 121, 151–159. [Google Scholar] [CrossRef]
  52. Marsh, H.V.; Evans, H.J.; Matrone, G. Investigations of the role of iron in chlorophyll metabolism. II. effect of iron deficiency on chlorophyll synthesis. Plant Physiol. 1963, 38, 638–642. [Google Scholar] [CrossRef] [PubMed]
  53. Han, W.; Jin, W.; Ding, W.; Lu, S.; Song, K.; Chen, C.; Qin, C.; Chen, Y.; Tu, R.; Zhou, X. Effects of nutrient composition, lighting conditions, and metal ions on the growth and lipid yield of the high-lipid-yielding microalgae (Chlorella pyrenoidosa) cultivated in municipal wastewater. J. Environ. Chem. Eng. 2021, 9, 106491. [Google Scholar] [CrossRef]
  54. Atefeh, K.; Vida, T.; Ali, Z.M.; Eghrari, G.S.; Abdolhamid, A.S. Augmenting the expression of accD and rbcL genes using optimized iron concentration to achieve higher biomass and biodiesel in Chlorella vulgaris. Biotechnol. Lett. 2020, 42, 2631–2641. [Google Scholar]
  55. Vaishali, R.; Gergely, M. Light-dependent nitrate removal capacity of green microalgae. Int. J. Mol. Sci. 2023, 24, 77. [Google Scholar]
Figure 1. The growth curves of Chlorella sorokiniana GXNN-01 at different MSGW dilution multiples.
Figure 1. The growth curves of Chlorella sorokiniana GXNN-01 at different MSGW dilution multiples.
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Figure 2. Growth curves of six microalgae cultured in three media during 20 days: (a) Chlorella sorokiniana GXNN-01, (b) Chlorella sorokiniana FACHB-275, (c) Chlorella sp. FACHB-30, (d) Chlorella sp. FACHB-9, (e) Chlamydomonas reinhardtii FACHB-479, and (f) Tetradesmus obliquus FACHB-416.
Figure 2. Growth curves of six microalgae cultured in three media during 20 days: (a) Chlorella sorokiniana GXNN-01, (b) Chlorella sorokiniana FACHB-275, (c) Chlorella sp. FACHB-30, (d) Chlorella sp. FACHB-9, (e) Chlamydomonas reinhardtii FACHB-479, and (f) Tetradesmus obliquus FACHB-416.
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Figure 3. Nutrients removal rates of six microalgae after 20 days of culture: (a) total phosphorus, (b) total nitrogen, (c) ammonia nitrogen, and (d) COD. The bars (mean ± SD of four replicates) with different letters (uppercase for 1000MSGW + TMs and lowercase for 1000MSGW) are significantly different (p < 0.05).
Figure 3. Nutrients removal rates of six microalgae after 20 days of culture: (a) total phosphorus, (b) total nitrogen, (c) ammonia nitrogen, and (d) COD. The bars (mean ± SD of four replicates) with different letters (uppercase for 1000MSGW + TMs and lowercase for 1000MSGW) are significantly different (p < 0.05).
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Figure 4. Growth curves during 20 days of culture under different light intensities.
Figure 4. Growth curves during 20 days of culture under different light intensities.
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Figure 5. Nutrient removal rates after 20 days of culture under different light intensities: (a) total phosphorus, (b) total nitrogen, (c) ammonia nitrogen, and (d) COD. The bars (mean ± SD of four replicates) with different letters are significantly different (p < 0.05).
Figure 5. Nutrient removal rates after 20 days of culture under different light intensities: (a) total phosphorus, (b) total nitrogen, (c) ammonia nitrogen, and (d) COD. The bars (mean ± SD of four replicates) with different letters are significantly different (p < 0.05).
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Figure 6. (a) Growth curves during 20 days of culture under different inoculum concentrations and (b) specific growth rates on the 20th day compared with the first day with different inoculum concentrations. The bars (mean ± SD of four replicates) with different letters are significantly different (p < 0.05).
Figure 6. (a) Growth curves during 20 days of culture under different inoculum concentrations and (b) specific growth rates on the 20th day compared with the first day with different inoculum concentrations. The bars (mean ± SD of four replicates) with different letters are significantly different (p < 0.05).
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Figure 7. Nutrients removal rates under different initial inoculum conditions: (a) total phosphorus, (b) total nitrogen, (c) ammonia nitrogen, and (d) COD. The bars (mean ± SD of four replicate) with different letters are significantly different (p < 0.05).
Figure 7. Nutrients removal rates under different initial inoculum conditions: (a) total phosphorus, (b) total nitrogen, (c) ammonia nitrogen, and (d) COD. The bars (mean ± SD of four replicate) with different letters are significantly different (p < 0.05).
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Figure 8. Growth curves during 20 days of culture under different Fe3+ concentrations.
Figure 8. Growth curves during 20 days of culture under different Fe3+ concentrations.
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Figure 9. Nutrients removal rates under different Fe3+ concentration conditions: (a) total phosphorus, (b) total nitrogen, (c) ammonia nitrogen, and (d) COD. The bars (mean ± SD of four replicates) with different letters are significantly different (p < 0.05).
Figure 9. Nutrients removal rates under different Fe3+ concentration conditions: (a) total phosphorus, (b) total nitrogen, (c) ammonia nitrogen, and (d) COD. The bars (mean ± SD of four replicates) with different letters are significantly different (p < 0.05).
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Table 1. The specific growth rates (d−1) of six microalgae on the 20th day compared with the first day when growing in the BBM, 1000MSGW, and 1000MSGW + TMs. Values (mean ± SD of four replicates) in the same row with different lowercase letters indicate significant differences (p < 0.05).
Table 1. The specific growth rates (d−1) of six microalgae on the 20th day compared with the first day when growing in the BBM, 1000MSGW, and 1000MSGW + TMs. Values (mean ± SD of four replicates) in the same row with different lowercase letters indicate significant differences (p < 0.05).
Specific Growth Rate (d−1)Microalgae Species
Chlorella sorokiniana GXNN-01Chlorella sorokiniana FACHB-275Chlorella sp. FACHB-30Chlorella sp. FACHB-9Chlamydomonas reinhardtii
FACHB-479
Tetradesmus obliquus
FACHB-416
BBM0.1756 ± 0.0129 bc0.1852 ± 0.0102 ab0.1728 ± 0.0099 bcd0.2031 ± 0.0083 a0.1572 ± 0.0057 d0.1604 ± 0.0054 cd
1000MSGW0.1956 ± 0.0068 d0.2245 ± 0.0039 c0.2564 ± 0.0005 b0.2685 ± 0.0007 a0.1625 ± 0.0045 e0.1297 ± 0.0023 f
1000MSGW + TMs0.1899 ± 0.0071 c0.2155 ± 0.0019 b0.2660 ± 0.0046 a0.2823 ± 0.0035 a0.1609 ± 0.0138 d0.1857 ± 0.0028 c
Table 2. Comparison of removal rate and biomass concentration before and after optimization. Values (mean ± SD of four replicates) within the same row with asterisk labeled are significantly different (the Student t test, ** p < 0.01; * p < 0.05).
Table 2. Comparison of removal rate and biomass concentration before and after optimization. Values (mean ± SD of four replicates) within the same row with asterisk labeled are significantly different (the Student t test, ** p < 0.01; * p < 0.05).
ParametersBefore OptimizationAfter OptimizationIncreasing Rate
The removal rate of TP (%)69.10 ± 2.57 **87.60 ± 1.50 **26.77%
The removal rate of TN (%)26.93 ± 0.82 **68.05 ± 3.89 **152.69%
The   removal   rate   of   NH 4 + -N (%)51.91 ± 1.28 **75.89 ± 1.82 **46.19%
The removal rate of COD (%)61.50 ± 3.75 **77.96 ± 2.95 **26.76%
Biomass concentration (g L−1)1.196 ± 0.087 *1.423 ± 0.018 *18.98%
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Zhuang, Y.; Su, Q.; Wang, H.; Wu, C.; Tong, S.; Zhang, J.; Qiao, H. Strain Screening and Conditions Optimization in Microalgae-Based Monosodium Glutamate Wastewater (MSGW) Treatment. Water 2023, 15, 1663. https://doi.org/10.3390/w15091663

AMA Style

Zhuang Y, Su Q, Wang H, Wu C, Tong S, Zhang J, Qiao H. Strain Screening and Conditions Optimization in Microalgae-Based Monosodium Glutamate Wastewater (MSGW) Treatment. Water. 2023; 15(9):1663. https://doi.org/10.3390/w15091663

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Zhuang, Yanmin, Qingling Su, Haowen Wang, Chengzong Wu, Shanying Tong, Jumei Zhang, and Hongjin Qiao. 2023. "Strain Screening and Conditions Optimization in Microalgae-Based Monosodium Glutamate Wastewater (MSGW) Treatment" Water 15, no. 9: 1663. https://doi.org/10.3390/w15091663

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