| Autor: |
Wen-Shuo Kuo, Jiu-Yao Wang, Chia-Yuan Chang, Jui-Chang Liu, Shao, Yu-Ting, Yen-Sung Lin, So, Edmund Cheung, Ping-Ching Wu |
| Rok vydání: |
2020 |
| DOI: |
10.6084/m9.figshare.12262934 |
| Popis: |
Additional file 1: Figure S1. Growth curves for bacteria and water-soluble a C60(OH)46- or b C60(OH)21-treated-bacteria. Table S1. Stability of well-prepared water-soluble fullerenol in physiological environments. Figure S2. Field desorption mass spectrometry spectra of fullerenol. Table S2. The amount of ROS generated from by a TPE (211.2 nJ pixel−1, 800 scans; Ex, 760 nm) to water-soluble fullerenol (3 or 6 μg mL−1) was conducted in the dark and monitored. Figure S3. Functional characterization of synthesized water-soluble C60(OH)21. Figure S4. Field desorption mass spectrometry spectra of fullerenol. Table S3. The amount of ROS generated from by a TPE (211.2 nJ pixel−1, 800 scans; Ex, 760 nm) to water-soluble fullerenol-treated-Bacillus subtilis (B. subtilis; 3 or 6 μg mL−1) was conducted in the dark and monitored. Figure S5. Viability (%) was quantified according to the determined viable count of material-treated B. subtilis through a CFU assay conducted using short excitation with a TPE power of 211.2 nJ pixel−1 with 800 scans (approximately 3.2621 s of total effective exposure time; Ex, 760 nm). Figure S6. The number of surviving material-treated-bacteria was determined by CFU counting assay. Figure S7. The temperature dependence of material as a function of irradiaiton time with a TPE power of 211.2 nJ pixel−1 (Ex, 760 nm). Table S4. The radiative and non-radiative decay rates of water-soluble fullerenol. |
| Databáze: |
OpenAIRE |
| Externí odkaz: |
|
