Abstract:During the Coronavirus pandemic, the world counted on conventional sanitizing products that involved unsafe toxic chemicals. Ultraviolet Germicidal Irradiation or ultraviolet disinfection is introduced in many sanitizing applications, as it splits the DNA/RNA, forcing microorganisms unable to spread. For that, ultraviolet disinfection technology is presented in this project to replace the old nonenvironmental practices. Far-ultraviolet type C is a small part of the ultraviolet spectrum, with wavelengths from 2… Show more
“…[34] Through an experiment done on NCTC clone cell sheets, it was discovered that KrCl lamps of UV 222 nm are more friendly than conventional UV lights. [35] The study indicates that UV 222 nm exposure had minimal to no effect on the survival of the cells at the lower level of the sheet. This demonstrates that it can be utilized in regions where people are moving.…”
Section: Introductionmentioning
confidence: 90%
“…This was done using a narrow frequency band of EMR (Electro-magnetic Radiation) that was discovered to be human-safe at 222 nm wavelengths in a narrow part of the electromagnetic spectrum [34]. Through an experiment done on NCTC clone cell sheets, it was discovered that KrCl lamps of UV 222 nm are more friendly than conventional UV lights [35]. The study indicates that UV 222 nm exposure had minimal to no effect on the survival of the cells at the lower level of the sheet.…”
The COVID-19 pandemic has brought attention to the necessity of an adequate disinfection system to fight dangerous and contagious diseases. Current cleaning procedures are frequently laborious and time-consuming. Researchers are investigating the use of cutting-edge technologies to safeguard the worldwide populace against the spread of viruses and other illnesses to address this issue. A UV-222 nm light-based disinfection system has been suggested as a possible remedy in this regard to counteract the impacts of viruses and maintain a clean and secure environment. The implementation of UV-222 nm light-based disinfection systems and their prospective influence on healthcare technology are the main topics of this article. The technology can address issues with the spread of viruses and bacteria in a variety of contexts, including car headlights, public lighting, interior lights in homes, and other sterilising techniques. Additionally, the high-way geometry of UVC sterilisation has been theoretically formulated and investigated. Healthcare professionals, medical physicists, biomedical and clinical engineers, and other associated groups are the target audience for this article. In order to enhance patient safety, disease surveillance, and management, the study discusses the potential advantages of UV-222 nm light-based disinfection systems. We also talk about the ethical, moral, and legal ramifications of using such technology. In conclusion, this research offers a fresh viewpoint on UV-222 nm light-based disinfection systems and their prospective influence on medical technology. In order to improve patient care and safety, we hope that this conversation will promote additional research and development in the area of healthcare technology
“…[34] Through an experiment done on NCTC clone cell sheets, it was discovered that KrCl lamps of UV 222 nm are more friendly than conventional UV lights. [35] The study indicates that UV 222 nm exposure had minimal to no effect on the survival of the cells at the lower level of the sheet. This demonstrates that it can be utilized in regions where people are moving.…”
Section: Introductionmentioning
confidence: 90%
“…This was done using a narrow frequency band of EMR (Electro-magnetic Radiation) that was discovered to be human-safe at 222 nm wavelengths in a narrow part of the electromagnetic spectrum [34]. Through an experiment done on NCTC clone cell sheets, it was discovered that KrCl lamps of UV 222 nm are more friendly than conventional UV lights [35]. The study indicates that UV 222 nm exposure had minimal to no effect on the survival of the cells at the lower level of the sheet.…”
The COVID-19 pandemic has brought attention to the necessity of an adequate disinfection system to fight dangerous and contagious diseases. Current cleaning procedures are frequently laborious and time-consuming. Researchers are investigating the use of cutting-edge technologies to safeguard the worldwide populace against the spread of viruses and other illnesses to address this issue. A UV-222 nm light-based disinfection system has been suggested as a possible remedy in this regard to counteract the impacts of viruses and maintain a clean and secure environment. The implementation of UV-222 nm light-based disinfection systems and their prospective influence on healthcare technology are the main topics of this article. The technology can address issues with the spread of viruses and bacteria in a variety of contexts, including car headlights, public lighting, interior lights in homes, and other sterilising techniques. Additionally, the high-way geometry of UVC sterilisation has been theoretically formulated and investigated. Healthcare professionals, medical physicists, biomedical and clinical engineers, and other associated groups are the target audience for this article. In order to enhance patient safety, disease surveillance, and management, the study discusses the potential advantages of UV-222 nm light-based disinfection systems. We also talk about the ethical, moral, and legal ramifications of using such technology. In conclusion, this research offers a fresh viewpoint on UV-222 nm light-based disinfection systems and their prospective influence on medical technology. In order to improve patient care and safety, we hope that this conversation will promote additional research and development in the area of healthcare technology
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.