Your search keyword '"Park, Hyeona"' showing total 4 results

1. Preservation and reactivation strategies for quorum quenching media to combat membrane biofouling.

Author

Iqbal, Tahir, Park, Hyeona, Shah, Syed Salman Ali, Kim, Jinwoo, Mameda, Naresh, Lee, Kibaek, and Choo, Kwang-Ho

Subjects

*FOULING, *CELL culture, *CELL survival, *CONFORMANCE testing, *FOULING organisms, *DEHYDRATION

Abstract

Microbial quorum quenching (QQ), which addresses biofouling resistant to physical and chemical methods, presents a compelling solution. Enhancements in sustainability are imperative to ensure its long-term stability. This study explores QQ media preservation for extended use. Three media types were tested over 150 days: fresh BH4 cells, preserved/reactivated BH4 cells, and BH4 cell extracts. Initial QQ activities ranged in the appropriate levels from 1.08 to 1.24 h−1. Preservation in 50 mM Tris-HCl at 4 °C showed that media with whole cells retained approximately 60 % activity after 60 days, unlike cell extract media, which lost all activity. However, the dehydration and reactivation of BH4 cell media fully recovered the initial QQ activity while maintaining it for 150 days. In MBR tests, reactivated QQ media performed as effectively as those prepared with freshly cultured BH4 cells, delaying membrane fouling by 2-fold. Revitalizing QQ media in combination with chlorine-based chemically enhanced backwashing (CEB) further delayed fouling by 2.5 times compared to CEB alone. Reactivated QQ media retained robust activity even after prolonged MBR use. This study showcases the effectiveness of dehydration and reactivation techniques for preserving QQ media, ensuring its reliable long-term storage and utilization. However, further enhancements are necessary to optimize cell viability. [Display omitted] • The extended preservation of diverse quorum quenching (QQ) media was investigated. • Whole BH4 cell QQ media were preserved better than cell extract QQ media. • The reactivation of QQ media preserved after dehydration restored their initial activity. • The reactivated QQ media exhibited the same fouling mitigation efficacy as fresh media. • The combination of QQ and chlorine-based backwash substantially reduced fouling. [ABSTRACT FROM AUTHOR]

Published

2024

2. The impact of sunlight on fouling behaviors and microbial communities in membrane bioreactors.

Author

Park, Hyeona, Shah, Syed Salman Ali, Korshin, Gregory, Angelidaki, Irini, and Choo, Kwang-Ho

Subjects

*FOULING, *MICROBIAL communities, *SUNSHINE, *BIOREACTORS, *MICROBIAL ecology

Abstract

Membrane fouling is a significant obstacle to applying membrane bioreactors (MBRs) for wastewater treatment. Here we report the impact of sunlight irradiation on membrane fouling, biopolymers, signal molecules, and microbial communities in MBRs. The degradation of signal molecules, which induce membrane biofouling, occurred through solar photolysis in batch tests. However, MBR sludge exposed to sunlight exhibited different biological behaviors creating more soluble microbial products (SMP) and signal molecules (particularly autoinducer-2). Cell lysis and deflocculation occurred when the MBR mixed liquor was exposed to sunlight. MBR fouling rates coincided with the temporal concentration profiles of SMP and signal molecules. Sunlight caused drastic changes in the MBR microbial community, stimulating the preferential growth of specific bacteria (e.g., Deinococcus Runella , Flavitalea , Glaiimonas , and Rurimicrobium). The nonmetric multidimensional scaling analysis of the MBR community structures with and without sunlight irradiation showed two distinct microbial community clusters and their reversibility. Network analysis based on Spearman's rank correlations revealed that with sunlight irradiation, fouling rates had significant positive connections with SMP proteins and the Flavitalea genus. The findings of this study demonstrate that sunlight is a considerable factor affecting membrane fouling and microbial ecology in MBRs, needing shade for fouling mitigation and sustainable operation. [Display omitted] • The effects of sunlight on membrane biofouling and microbial ecology were investigated. • The signal molecules in batch reactors degraded well when sunlight irradiation was applied. • Sunlight irradiation of biological mixed liquor exacerbated membrane fouling. • The concentration of soluble organics and autoinducer-2 increased with sunlight irradiation. • Sunlight irradiation caused drastic changes in microbial communities and their networks. [ABSTRACT FROM AUTHOR]

Published

2023

3. Membrane reciprocation and quorum quenching: An innovative combination for fouling control and energy saving in membrane bioreactors.

Author

Kim, Jinwoo, Bae, Eunjin, Park, Hyeona, Park, Hyung-June, Shah, Syed Salman Ali, Lee, Kibaek, Lee, Jaewoo, Oh, Hyun-Suk, Park, Pyung-Kyu, Shin, Yong Cheol, Moon, HeeWan, Naddeo, Vincenzo, and Choo, Kwang-Ho

Subjects

*FOULING, *BIOREACTORS, *WASTEWATER treatment, *MICROBIAL communities

Abstract

• Membrane reciprocation paired with quorum quenching (QQ) combats fouling. • Service time is boosted six-fold through membrane reciprocation and QQ methods. • Synergy reduces physically reversible resistance, enhancing membrane performance. • QQ curbs biofouling, degrading signal molecules but maintaining microbial community. • The combined approach saves > 80 % of energy and minimizes membrane fouling. Membrane bioreactors (MBRs) play a crucial role in wastewater treatment, but they face considerable challenges due to fouling. To tackle this issue, innovative strategies are needed. This study investigated the effectiveness of membrane reciprocation and quorum quenching (QQ) to control fouling in MBRs. The study compared MBRs using membrane reciprocation (30 rpm) and QQ (injecting media containing 100 or 200 mg/L BH4) with conventional MBRs employing different air-scouring intensities. The results demonstrated that combining membrane reciprocation (30 rpm) with QQ (200 mg/L BH4) significantly extended the service time of MBRs, making it approximately six times longer than conventional methods. Moreover, this approach reduced physically reversible resistance. The reduction in signal molecules related to biofouling due to QQ showcased its critical role in controlling biofouling, even under high shear caused by membrane reciprocation. However, the impact of QQ on microbial community structure appeared relatively insignificant when compared to factors such as operation time, aeration intensity, and membrane reciprocation. By combining membrane reciprocation and QQ, the study achieved a remarkable 81 % energy saving compared to extensive aeration (103 s−1 in velocity gradient), in addition to the extended service time. Importantly, this combined antifouling approach did not negatively affect microbial characteristics and wastewater treatment, emphasizing its effectiveness in MBRs. Overall, the findings of this study offer valuable insights for developing synergistic fouling control strategies in MBRs, significantly improving the energy efficiency of the wastewater treatment process. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

4. Exploring novel quorum quenching strain: Enhanced disrupting autoinducer-2 bacterial communication to combat biofouling in membrane bioreactor for wastewater treatment.

Author

Park, Hyeyeon, Jang, Jun-U, Park, Jeongmi, Park, Hyeona, Choo, Kwang-Ho, Jeon, Jongho, Yeo, Hyeonuk, Lee, Chung-Hak, and Lee, Kibaek

Subjects

*FOULING, *WASTEWATER treatment, *ESCHERICHIA coli, *QUORUM sensing, *GRAM-positive bacteria

Abstract

[Display omitted] • Pantoea sp. PL-1 inhibits biofilm in AI-2 QS strains, hindering DPD concentration. • PL-1 degrades DPD more efficiently (15 times) than Acinetobacter sp. DKY-1. • Applying PL-1 in an MBR showed 40% more biofilm reduction than DKY-1. • PL-1 alters microbial communities, potentially suppressing EPS production genes. • Hydrophilic, low molecule of PL-1′s AI-2 QQ substance needs crucial exploration. Prior investigations concerning quorum quenching (QQ), which hinders quorum sensing (QS) in microbial communication, concentrated predominantly on N -acylhomoserine lactones (AHLs), which are communicated merely by gram-negative bacteria. However, to combat biofouling more effectively, particularly biofilm-related issues, it is important to explore the inhibition of autoinducer-2 (AI-2), a universal signal (interspecies communication) employed by both gram-negative and gram-positive bacteria. This study aimed to isolate and identify novel strains capable of more effectively inhibiting AI-2 signaling for use in engineering fields. The results revealed that the newly isolated strain Pantoea sp. PL-1 demonstrated remarkable efficacy in attenuating AI-2 signals, leading to a substantial reduction in the AI-2 precursor (S)-4,5-dihydroxy-2,3-pentandione (DPD) in both its pellet (with a DPD removal efficiency of 90.8 % after 180 min, with a rate constant of k = 0.8 h−1) and supernatant form (66.9 %, k = 0.37 h−1). Interestingly, the findings indicate that strain DKY-1, a strain previously reported to exhibit AI-2 QQ activity, only reduced DPD levels in its supernatant form (extracellular activity), while both the pellet and the supernatant of strain PL-1 demonstrated AI-2 QQ activity, indicating both intracellular and extracellular QQ activity. Adding the PL-1 supernatant to co-cultures of two AI-2 QS strains, E. coli K12 and P. mirabilis , successfully reduced DPD by 40 % and 70 %, respectively, without impeding their growth. Additionally, when assessing the impact of PL-1 to minimize membrane biofouling in a membrane bioreactor, it demonstrated superior performance compared to the DKY-1 strain, with a 40 % improvement. The AI-2 QQ compound of PL-1 has been identified as highly hydrophilic and low-molecular-weight, and its exact properties have not yet been fully elucidated. Therefore, uncovering its identity may be an important goal for future research. [ABSTRACT FROM AUTHOR]

Published

2024