UV222 disinfection of SARS-CoV-2 in solution

  • Samet, JM et al. Airborne transmission of SARS-CoV-2: what we know. Clin. Infect. Say. https://doi.org/10.1093/cid/ciab039 (2021).

    Article
    PubMed

    Google Scholar

  • Tang, JW et al. Busting myths about airborne transmission of severe acute respiratory syndrome coronavirus (SARS-CoV-2). J.Hosp. Infect. https://doi.org/10.1016/j.jhin.2020.12.022 (2021).

    Article
    PubMed
    PubMed Center

    Google Scholar

  • Goel, S. et al. Resilient and agile engineering solutions to address societal challenges such as the coronavirus pandemic. Mater. Today Chem. 17100300 (2020).

    CASE
    Article

    Google Scholar

  • Pandey, LM Surface engineering of personal protective equipment (PPE) to prevent contagious SARS-CoV-2 infections. Surf. Eng. 36901–907 (2020).

    CASE
    Article

    Google Scholar

  • Gerchman, Y., Mamane, H., Friedman, N. & Mandelboim, M. UV-LED disinfection of coronavirus: wavelength effect. J. Photochem. Photobiol. B Biol. 212112044 (2020).

    CASE
    Article

    Google Scholar

  • Kariwa, H., Fujii, N. & Takashima, I. Inactivation of SARS coronavirus using povidone-iodine, physical conditions and chemical reagents. Dermatology 212119–123 (2006).

    CASE
    Article

    Google Scholar

  • Darnell, MER, Subbarao, K., Feinstone, SM & Taylor, DR Inactivation of the coronavirus that induces severe acute respiratory syndrome, SARS-CoV. J. Virol. Methods 12185–91 (2004).

    CASE
    Article

    Google Scholar

  • Rabenau, HF et al. Stability and inactivation of the SARS coronavirus. Med. Microbiol. Immunol. 1941–6 (2005).

    CASE
    Article

    Google Scholar

  • Pfeifer, GP & Besaratinia, A. UV wavelength-dependent DNA damage and non-melanoma and melanoma human skin cancer. Photochem. Photobiol. Science. 1190–97 (2012).

    CASE
    Article

    Google Scholar

  • Jose, JG & Pitts, DG Wavelength dependence of cataracts in albino mice following chronic exposure. Exp. Eye Res. 41545–563 (1985).

    CASE
    Article

    Google Scholar

  • Bjørklund, G., Dadar, M., Mutter, J. & Aaseth, J. The toxicology of mercury: current research and emerging trends. About. Res. 159545-554 (2017).

    Article

    Google Scholar

  • Buonanno, M. et al. Germicidal efficacy and mammalian skin safety of 222 nm UV light. Radiat. Res. 187483–491 (2017).

    ADS
    CASE
    Article

    Google Scholar

  • Kaidzu, S. et al. Evaluation of acute corneal injury induced by 222 nm and 254 nm ultraviolet light in Sprague-Dawley rats. Free radical. Res. 53611–617 (2019).

    CASE
    Article

    Google Scholar

  • Beck, SE, Wright, HB, Hargy, TM, Larason, TC, and Linden, KG Action spectra for the validation of pathogen disinfection in medium-pressure ultraviolet (UV) systems. Water Res. 7027–37 (2015).

    CASE
    Article

    Google Scholar

  • Beck, SE et al. Comparison of UV-induced inactivation and RNA damage in phage MS2 across the germicidal UV spectrum. Appl. About. Microbiol. 821468-1474 (2016).

    ADS
    CASE
    Article

    Google Scholar

  • Beck, SE, Hull, NM, Poepping, C. & Linden, KG Wavelength-dependent damage of adenoviral proteins across the germicidal UV spectrum. About. Science. Technology. https://doi.org/10.1021/acs.est.7b04602 (2018).

    Article
    PubMed
    PubMed Center

    Google Scholar

  • Eischeid, AC & Linden, KG Molecular indications of protein damage in adenoviruses after UV disinfection. Appl. About. Microbiol. 771145-1147 (2011).

    ADS
    CASE
    Article

    Google Scholar

  • Hull, NM & Linden, KG Synergy of MS2 disinfection by sequential exposure to suitable UV wavelengths. Water Res. https://doi.org/10.1016/j.watres.2018.06.017 (2018).

    Article
    PubMed

    Google Scholar

  • Case, JB, Bailey, AL, Kim, AS, Chen, RE & Diamond, MS Growth, detection, quantification, and inactivation of SARS-CoV-2. Virology 54839–48 (2020).

    CASE
    Article

    Google Scholar

  • Bolton, JR & Linden, KG Standardization of methods for determining fluence (UV dose) in laboratory-scale UV experiments. J. About. Eng. 129209–215 (2003).

    CASE
    Article

    Google Scholar

  • Linden, KG & Darby, JL Estimation of germicidal effective dose of medium pressure UV lamps. J. About. Eng. 1231142–1149 (1997).

    CASE
    Article

    Google Scholar

  • Hull, NM & Linden, KG Synergy of MS2 disinfection by sequential exposure to suitable UV wavelengths. Water Res. 143292–300 (2018).

    CASE
    Article

    Google Scholar

  • CDC. Real-Time RT-PCR Primers and Probes for COVID-19 | CDC. (2020).

  • Peccia, J. & Hernandez, M. UV-induced inactivation rates for Mycobacterium bovis BCG. J. Occup. About. Hyg. 1430–435 (2004).

    Article

    Google Scholar

  • Walker, CM & Ko, G. Effect of ultraviolet germicidal irradiation on viral aerosols. About. Science. Technology. 415460–5465 (2007).

    ADS
    CASE
    Article

    Google Scholar

  • Jordan, P., Werth, HM, Shelly, M. & Mark, H. Effects of relative humidity on ultraviolet-induced inactivation of airborne bacteria. Aerosol Sci. Technology. 35728–740 (2001).

    Article

    Google Scholar

  • Kowalski, W. Handbook of Ultraviolet Germicidal Irradiation: UVGI for Air and Surface Disinfection. Handbook of Ultraviolet Germicidal Irradiation: UVGI for Air and Surface Disinfection (Springer, 2009) https://doi.org/10.1007/978-3-642-01999-9.

  • Tseng, C.-C. & Li, C.-S. Inactivation of virus-containing aerosols by ultraviolet germicidal irradiation. Aerosol Sci. Technology. 391136-1142 (2005).

    ADS
    CASE
    Article

    Google Scholar

  • Raeiszadeh, M. & Adeli, B. Critical Review of UV Disinfection Systems Against the COVID-19 Outbreak: Applicability, Validation, and Safety Considerations (2020) https://doi.org/10.1021/acsphotonics.0c01245.

  • Pendyala, B., Patras, A., Pokharel, B. & D’Souza, D. Genomic modeling as an approach to identify surrogates for use in experimental validation of SARS-CoV-2 and HuNoV inactivation by treatment UV-C. Front. Microbiol. 112406 (2020).

    Article

    Google Scholar

  • Lo, CW et al. UVC disinfects SARS-CoV-2 by inducing damage to the viral genome with no apparent effects on viral morphology and proteins. Science. representing 111–11 (2021).

    Article

    Google Scholar

  • Buonanno, M., Welch, D., Shuryak, I. & Brenner, DJ Far-UVC light (222 nm) safely and effectively inactivates airborne human coronaviruses. Science. representing ten1–8 (2020).

    Article

    Google Scholar

  • Blatchley, Emergencies et al. Far UV-C radiation: an emerging tool for pandemic control. Crit. Rev. About. Science. Technology. 01–21 (2022).

    Article

    Google Scholar

  • Ma, B., Gundy, PM, Gerba, CP, Sobsey, MD & Linden, KG UV inactivation of SARS-CoV-2 across the UVC spectrum: KrCl excimer, mercury vapor and light emitting diode (LED) sources. Appl. About. Microbiol. 87e01532-21 (2021).

    ADS
    Article

    Google Scholar

  • Heßling, M., Hönes, K., Vatter, P. & Lingenfelder, C. Doses of ultraviolet irradiation for coronavirus inactivation—Review and analysis of coronavirus photoinactivation studies. GMS Hyg. Infect. Control 15Doc08 (2020).

    PubMed
    PubMed Center

    Google Scholar

  • Kitagawa, H. et al. Effectiveness of 222 nm ultraviolet light on disinfection of surface contamination by SARS-CoV-2. A m. J. Infect. Control 0(2020).

  • Bivins, A. et al. Persistence of SARS-CoV-2 in water and wastewater. About. Science. Technology. Lett. seven937–942 (2020).

    CASE
    Article

    Google Scholar

  • Ye, Y., Ellenberg, RM, Graham, KE, and Wigginton, KR Survivability, separation, and recovery of enveloped viruses from untreated municipal wastewater. About. Science. Technology. 505077–5085 (2016).

    ADS
    CASE
    Article

    Google Scholar

  • Liu, D., Thompson, JR, Carducci, A. & Bi, X. Potential secondary transmission of SARS-CoV-2 via sewage. Science. About. 749142358 (2020).

    ADS
    CASE
    Article

    Google Scholar

  • Rodríguez, RA, Bounty, S. & Linden, KG Quantitative long-range PCR to determine inactivation of adenovirus 2 by ultraviolet light. J.Appl. Microbiol. 1141854–1865 (2013).

    Article

    Google Scholar

  • Beck, SE, Hull, NM, Poepping, C. & Linden, KG Wavelength-dependent damage of adenoviral proteins across the germicidal UV spectrum. About. Science. Technology. 52223-229 (2018).

    ADS
    CASE
    Article

    Google Scholar

  • Chang, J. et al. Cell entry mechanisms of SARS-CoV-2. proc. Natl. Acad. Science. UNITED STATES. 11711727–11734 (2020).

    CASE
    Article

    Google Scholar

  • Rocky, N. et al. UV disinfection of human norovirus: assessment of infectivity using a genome-wide PCR-based approach. About. Science. Technology. 542851–2858 (2020).

    ADS
    CASE
    Article

    Google Scholar

  • Ye, Y., Chang, PH, Hartert, J. & Wigginton, KR Reactivity of enveloped viral genome, proteins and lipids with free chlorine and UV254. About. Science. Technology. 527698–7708 (2018).

    ADS
    CASE
    Article

    Google Scholar

  • Wigginton, KR et al. UV radiation induces site-specific and genome-mediated cleavage in viral proteins. ChimBioChem 13837–845 (2012).

    CASE
    Article

    Google Scholar

  • Wigginton, KR & Kohn, T. Mechanisms of virus disinfection: The role of virus composition, structure, and function. Running. Notice. Ferrule. 284–89 (2012).

    CASE
    Article

    Google Scholar

  • Wigginton, KR, Pecson, BM, Sigstam, T., Bosshard, F. & Kohn, T. Mechanisms of virus inactivation: impact of disinfectants on virus function and structural integrity. About. Science. Technology. 4612069–12078 (2012).

    ADS
    CASE
    Article

    Google Scholar

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