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Loaded at: https: //mdpi/article/10.3390/ijerph192012995/s1, Figure S1: The illustration on the modeled photochemical reactor; Figure S2: Effects of initial pollutant concentration on photodegradation behaviors of (a) MO and (b) BPA; Figure S3: Photodegradation rate of BPA with quenchers (isopropanol, NaN3 and sorbic acid) within the presence in the suspensions derived from (a) River Biofilm and (b) Pond Biofilm. Experimental conditions: [MO]0 = 2 mg/L, [Biofilm] = 696 mg/L, pH = six.eight (10 mM phosphate buffer); Figure S4: Photodegradation behaviors of BPA inside the presence of diverse biofilm fractions, i.e., raw biofilm with a content of 696 mg/L, exactly the same content of raw biofilm soon after EPS extraction, as well because the extracted EPS ( 14 mgC/L TOC). C0 [BPA] = two mg/L; Figure S5: Photodegradation price of BPA with quenchers (isopropanol, NaN3 and sorbic acid) in the presence from the EPS derived from (a) River Biofilm and (b) Pond Biofilm. Experimental conditions: [MO]0 = two mg/L, [EPS content] = 14 mgC/L, pH = six.eight (ten mM phosphate buffer); Table S1: The water qualities in the sampling web-sites for River Biofilm and Pond Biofilm; Table S2: Direct photodegradation prices of pollutants at a concentration of 2 mg/L; Table S3: Effects of initial pollutant concentration to photodegradation behaviors; Table S4: The compositions of EPS derived from periphytic biofilms (EPS content material: 50 mgC/L); Table S5: Spectral parameters of EPS derived from periphytic biofilms; Table S6: The roles of distinct fractions in biofilms on the direct photodegradation rates in the course of photodegrading MO. Author Contributions: Conceptualization, L.Docetaxal supplier W.Mevastatin manufacturer (Longfei Wang) and Y.PMID:23710097 L.; methodology, H.Y.; validation, L.W. (Lingling Wang); formal analysis, L.W. (Lingling Wang) and G.Z. (Guangshu Zeng); investigation, L.W. (Longfei Wang); information curation, Y.L.; writing–original draft preparation, H.Y.; writing–review and editing, L.W. (Longfei Wang). All authors have read and agreed for the published version with the manuscript. Funding: This investigation was funded by the open project fund of State Key Laboratory of Applied Microbiology Southern China (grant number SKLAM001-2020), the National All-natural Science Foundation of China (grant quantity 52170159 and 21976038); the Basic Research Funds for the Central Universities (grant number B210202054); the Chinese college students innovation and entrepreneurship training (grant quantity 202010294007); the Priority Academic Program Improvement of Jiangsu Greater Education Institutions, plus the Top-Notch Academic Applications Project of Jiangsu Higher Education Institutions (TAPP). Institutional Assessment Board Statement: Not applicable. Informed Consent Statement: Not applicable. Information Availability Statement: The data presented in this study are readily available at this short article and Supplementary Supplies. Conflicts of Interest: The authors declare no conflict of interest.
The official journal on the Japan Atherosclerosis Society as well as the Asian Pacific Society of Atherosclerosis and Vascular DiseasesOriginal ArticleJ Atheroscler Thromb, 2022; 29: 881-893. of Dietary Education Program for the Japan Diet program on Cholesterol Efflux Capacity: A Randomized Controlled TrialAriko Umezawa 1, Chizuko Maruyama 1, 2, Yasuhiro Endo three, Yumiko Suenaga three, Yuri Shijo 1, Noriko Kameyama 2, Aisa Sato 1, Ai Nishitani 4, Makoto Ayaori five, Masako Waki 6, Tamio Teramoto four, 7 and Katsunori Ikewaki three,1Division of Food and Nutrition, Graduate College of Human Sciences and Desig.