Ozone use in surface disinfection: an integrative review

Objective: To analyze the scientific evidence regarding the effectiveness of using ozone to disinfect surfaces based on an integrative literature review.Methods: A search was carried out in the SciELO, MEDLINE, LILACS, PubMed, Science Direct databases. Eleven articles published January 2010 to August 2021 were analyzed. All employed the experimental laboratory research model and achieved different levels of disinfection by O3, however, with varied surfaces and products tested, in addition to different methodological procedures.Results: The majority had an inhibition rate by O3 equal to or greater than 90%, thus proving the effectiveness of this agent as a surface disinfectant, even with variations in parameter values such as concentration and exposure time, in all selected articles, even those that did not prove the effectiveness of O3.Conclusion: This review shows the inhibitory power that O3 has on different pathogens, even if there are variables in the factors used for this purpose, highlighting it in front of other disinfectants. Thus, it corroborates the composition of surface disinfection protocols and decision-making among managers and committees about sanitizing technologies.

Disease X Testing: The results of an international external quality assessment exercise

The United Nations Secretary-General Mechanism (UNSGM) for investigation of the alleged use of chemical and biological weapons is the only established international mechanism of this type under the UN. The UNGSM may launch an international investigation, relying on a roster of expert consultants, qualified experts, and analytical laboratories nominated by the member states. Under the framework of the UNSGM, we organized an external quality assurance exercise for nominated laboratories, named the Disease X Test, to improve the ability to discover and identify new pathogens that may cause possible epidemics and to determine their animal origin. The "what-if" scenario was to identify the etiological agent responsible for an outbreak that has tested negative for many known pathogens, including viruses and bacteria. Three microbes were added to the samples, Dabie bandavirus, Mammarenavirus, and Gemella spp., of which the last two have not been taxonomically named or published. The animal samples were from Rattus norvegicus, Marmota himalayana, New Zealand white rabbit, and the tick Haemaphysalis longicornis. Of the 11 international laboratories that participated in this activity, six accurately identified pathogen X as a new Mammarenavirus, and five correctly identified the animal origin as R. norvegicus. These results showed that many laboratories under the UNSGM have the capacity and ability to identify a new virus during a possible international investigation of a suspected biological event. The technical details are discussed in this report.Copyright © 2022

High-efficiency preparation technology of sulforaphane: an overview

Sulforaphane is an isothiocyanate metabolite of cruciferous plants, which obtain antioxidant, anticancer and anti-COVID-19 functions. However, due to its unstable structure, it is easy to de-composite, thus the utilization of sulforaphane is difficult. With the advancement of the preparation of sulforaphane, the purpose of inhibiting sulforaphane inactivation and improving its utilization is expected to be realized. The existing preparation technologies are mainly myrosinase enzymatic hydrolysis, microbial transformation and chemical synthesis. Myrosinase enzymatic hydrolysis mainly utilizes endogenous myrosinase, exogenous myrosinase and heterologously expressed myrosinase. Myrosinase enzymatic hydrolysis technology not only obtain the advantage of high preparation efficiency, but also obtain the disadvantage that the activity of myrosinase cannot be stabilized. Microbial transformation mainly utilizes the function of microorganisms to convert glucosinolates to sulforaphane, and obtain the advantages of easy control of reaction conditions and low cost. Chemical synthesis mainly includes de novo synthesis and semi-synthesis, and semi-synthesis is the most widely used method at present. Chemical synthesis obtains the advantages of easy control of reaction conditions, but chemical synthesis techniques have the problems of high risk and low yield. This research reviews the preparation technology of sulforaphane, aiming to provide a reference for the efficient utilization of sulforaphane and its product development.

Use of ozonation technology to combat viruses and bacteria in aquatic environments: problems and application perspectives for SARS-CoV-2.

COVID-19 is a global health threat with a large number of confirmed cases and deaths worldwide. Person-to-person transmission through respiratory droplets and contact with aerosol-infected surfaces are the main ways in which the virus spreads. However, according to the updated literature, the new coronavirus (SARS-CoV-2) has also been detected in aqueous matrices, with the main route of transmission being feces and masks from patients diagnosed with the disease. Given the emergence of public health and environmental protection from the presence of lethal viruses and bacteria, this review article aims to report the major challenges associated with the application of ozonation in water contaminated with viruses and bacteria, in order to clarify whether these communities can survive or infect after the disinfection process and if it is efficient. Available data suggest that ozonation is able to increase the inactivation effect of microorganisms by about 50% in the logarithmic range, reducing infectivity. In addition, the evidence-based knowledge reported in this article is useful to support water and sanitation safety planning and to protect human health from exposure to cited contaminants through water.

SARS-CoV-2 detection and inactivation in water and wastewater: review on analytical methods, limitations and future research recommendations.

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has been detected in wastewater. Wastewater-based epidemiology (WBE) is a practical and cost-effective tool for the assessment and controlling of pandemics and probably for examining SARS-CoV-2 presence. Implementation of WBE during the outbreaks is not without limitations. Temperature, suspended solids, pH, and disinfectants affect the stability of viruses in wastewater. Due to these limitations, instruments and techniques have been utilized to detect SARS-CoV-2. SARS-CoV-2 has been detected in sewage using various concentration methods and computer-aided analyzes. RT-qPCR, ddRT-PCR, multiplex PCR, RT-LAMP, and electrochemical immunosensors have been employed to detect low levels of viral contamination. Inactivation of SARS-CoV-2 is a crucial preventive measure against coronavirus disease 2019 (COVID-19). To better assess the role of wastewater as a transmission route, detection, and quantification methods need to be refined. In this paper, the latest improvements in quantification, detection, and inactivation of SARS-CoV-2 in wastewater are explained. Finally, limitations and future research recommendations are thoroughly described.

Inactivation characteristics of a 280 nm Deep-UV irradiation dose on aerosolized SARS-CoV-2.

A non-filter virus inactivation unit was developed that can control the irradiation dose of aerosolized viruses by controlling the lighting pattern of a 280 nm deep-UV (DUV)-LED and the air flowrate. In this study, the inactivation properties of aerosolized SARS-CoV-2 were quantitatively evaluated by controlling the irradiation dose to the virus inside the inactivation unit. The RNA concentration of SARS-CoV-2 remained constant when the total irradiation dose of DUV irradiation to the virus exceeded 16.5 mJ/cm2. This observation suggests that RNA damage may occur in regions below the detection threshold of RT-qPCR assay. However, when the total irradiation dose was less than 16.5 mJ/cm2, the RNA concentration monotonically increased with a decreasing LED irradiation dose. However, the nucleocapsid protein concentration of SARS-CoV-2 was not predominantly dependent on the LED irradiation dose. The plaque assay showed that 99.16% of the virus was inactivated at 8.1 mJ/cm2 of irradiation, and no virus was detected at 12.2 mJ/cm2 of irradiation, resulting in a 99.89% virus inactivation rate. Thus, an irradiation dose of 23% of the maximal irradiation capacity of the virus inactivation unit can activate more than 99% of SARS-CoV-2. These findings are expected to enhance versatility in various applications. The downsizing achieved in our study renders the technology apt for installation in narrow spaces, while the enhanced flowrates establish its viability for implementation in larger facilities.

Antibiotic resistance of Klebsiella pneumoniae against the background of the COVID-19 pandemic: experience of the multidisciplinary hospital

Frequency of bacterial co-infections among patients with COVID-19 is not high, and over-prescribing of antibiotics may contribute the selection of resistant strains of enterobacteria and gram-negative non-fermenting bacteria. The aim of the study was to assess the local features of antibiotic resistance of K. pneumoniae and its genetic mechanisms against background of the COVID-19 infection pandemic. Material and methods. There was selected 37 carbapenem-resistant K. pneumoniae strains isolated in 2016, 2017 and 2020 from hospitalized patients, including 15 strains, isolated from patients with COVID-19 infection. Minimal inhibitory concentrations (MICs) of meropenem and colistin were determined by broth microdilution method. Determination of MICs of eravacycline, ceftazidime/avibactam, meropenem/vaborbactam, imipenem/relebactam was performed using Sensititre diagnostic system on EUMDROXF plates. Susceptibility to 11 combinations of 2 antibiotics was detected by modified method of multiply combination bactericidal testing. For 4 K. pneumoniae strains high-throughput sequencing was performed, followed with the subsequent search for determinants of antibiotic resistance and virulence, assessment of plasmid profiles. Results. All strains were resistant to meropenem (MIC50 32 mg/l, MIC90 128 mg/l) and produced KPC and OXA-48 carbapenemases. Strains isolated in 2016-2017 were susceptible to colistin (MIC <=2 mg/l), in 2020 only 26.7% of the strains retained their susceptibility (MIC50 64 mg/l, MIC90 256 mg/l). Susceptibility to combinations of two antibiotics with colistin included reduced from 84.6-100% in 2016-2017 till 26.6-66.7% in 2020. The strains isolated in 2020 retained their susceptibility to ceftazidime/avibactam (MIC <=1 mg/l). 5 strains resistant to cefiderocol with a MIC 8 mg/l were identified. Strains 2564 and 3125 isolated in 2020 from sputum of patients with COVID-19 infection belonged to different sequence-types (ST12 and ST23) and contained the blaOXA-48 carbapenemase gene, additionally strain 2564 contained the blaKPC-27carbapenemase gene. Resistance to colistin was caused by inactivation of the mgrB genes due to insertion of IS1 and IS5-like transposons. Conclusion. The performed genetic studies demonstrate a diversity of mechanisms of antibiotic resistance in K. pneumoniae leading to the formation of resistance including to antibiotics that haven't been used in Belarus till now.Copyright © 2021 Geotar Media Publishing Group. All Rights Reserved.

Estimation of Inactivation time for the SARS-CoV-2 virus from the UV biometer in South Korea.

The coronavirus disease 2019 (COVID-19) is a result of the infection by "severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), and has caused various social and economic effects over the globe. As the SARS-CoV-2 is effectively inactivated by the exposure to the UV-B radiation (shorter than 315 nm), the exposure time for inactivation of the SARS-CoV-2 was estimated using the broadband UV observation instrument over 11 observation sites in South Korea. For the limitation of the UV biometer, which has limited spectral information, the coefficient for conversion from the erythemal UV (EUV) to the radiation for virus inactivation was adopted before estimating the inactivation time. The inactivation time of SARS-CoV-2 is significantly dependent on seasonal and diurnal variations due to the temporal variations of surface incident UV irradiance. The inactivation times in summer and winter were around 10 and 50 min, respectively. The inactivation time was unidentified during winter afternoons due to the weak spectral UV solar radiation in winter. As the estimation of inactivation time using broadband observation includes the uncertainty due to the conversion coefficient and the error due to the solar irradiance, the sensitivity analysis of the inactivation time estimation was also conducted by changing the UV irradiance.

Immunogenicity of Sars-Cov-2 Vaccines by Vaccine Type in Randomised Clinical Trials

Background: Currently five SARS-CoV-2 vaccines are approved in North America (FDA) and Europe (EMA). Across the world other vaccines have been developed but not approved in high-income countries. Of the approved vaccines, 2 are mRNA vaccines, 2 are viral vectored vaccines, and 1 is a protein subunit vaccine. As immunogenicity markers are increasingly being used by regulatory agencies as surrogate markers for vaccine efficacy to inform authorization decisions, this meta-analysis compared the size of immunogenicity responses response elicited by the different COVID-19 vaccine types (mRNA, protein subunit, inactivated virus, viral vectors) and approved and unapproved COVID-19 vaccines. Method(s): Systematic review of trial registers and databases identified RCTs for SARS-CoV-2 vaccines. Risk of bias analysis was conducted using the Cochrane Risk of Bias tool. High risk of bias studies were excluded from analysis. Meta-analysis of seroconversion rates and geometric antibody titers (GMT) for neutralising (NAb) and anti-spike antibodies was conducted, each compared with a placebo using random effects model Cochrane-Mantel Haenszel Tests. Result(s): All studies assessed immunogenicity of COVID-19 vaccines on healthy non-immunocompromised adults between the age of 18 and 59. Statistically significant difference was identified between the different vaccine types for NAb GMT, anti-spike GMT, NAb seroconversion, and anti-spike seroconversion (P< 0.00001 for all). Conversely, no statistical significant difference was identified between approved and unapproved vaccines for NAb seroconversion (P=0.39), Nab GMT (P=0.36), anti-spike seroconversion (P=0.07), and antispike GMT (P=0.54). mRNA vaccines had the best immunogenicity results for NAb seroconversion, GMT, and anti-spike seroconversion. Viral vector vaccines had the lowest results for NAb seroconversion and GMT, while inactivated viruses had the lowest result for anti-spike seroconversion and mRNA vaccines for anti-spike GMT. High heterogeneity was observed across the different studies. Conclusion(s): This metanalysis of 35 randomised trials in 33,813 participants showed approved and unapproved vaccines to be comparable in postvaccination GMT values and seroconversion for both NAb and anti-spike. However, while comparing COVID-19 vaccines by vaccine types, statistically significant differences are observed. Variations in study designs, populations enrolled, and infection prevalence during trial duration could have influenced results.

Emerging membrane technologies and disinfection methods for efficient removal of waterborne pathogens during the COVID-19 pandemic and post-pandemic

Viruses and other microorganisms can enter water sources from different routes and cause pollution and irreparable damage. So, cost-effective and efficient systems for providing safe water are necessary. Efficient filtration systems based on antimicrobial materials have received a lot of attention in this regard. A wide range of materials play an important role in the production of efficient water filtration systems. Metal and metal oxide particles with anti-viral and antimicrobial properties comprising Cu, Cu2O, Ag, TiO2, and ZnO play a valuable role in the preparation of water filtration systems. Biopolymers such as cellulose or carbon nanomaterials like graphene or its derivatives have been reported to provide safe water. In this review, we summarize the use of diverse materials in the preparation of efficient filtration-based systems like membranes and paper filters for water treatment. Pathogen-containing water samples were effectively disinfected using the prepared water disinfection systems.Copyright © 2023 The Royal Society of Chemistry.

Glycolytic stress deteriorates 229E virulence to improve host defense response.

Viral infection treatment is a difficult task due to its complex structure and metabolism. Additionally, viruses can alter the metabolism of host cells, mutate, and readily adjust to harsh environments. Coronavirus stimulates glycolysis, weakens mitochondrial activity, and impairs infected cells. In this study, we investigated the efficacy of 2-DG in inhibiting coronavirus-induced metabolic processes and antiviral host defense systems, which have not been explored so far. 2-Deoxy-d-glucose (2-DG), a molecule restricting substrate availability, has recently gained attention as a potential antiviral drug. The results revealed that 229E human coronavirus promoted glycolysis, producing a significant increase in the concentration of fluorescent 2-NBDG, a glucose analog, particularly in the infected host cells. The addition of 2-DG decreased its viral replication and suppressed infection-induced cell death and cytopathic effects, thereby improving the antiviral host defense response. It was also observed that administration of low doses of 2-DG inhibited glucose uptake, indicating that 2-DG consumption in virus-infected host cells was mediated by high-affinity glucose transporters, whose levels were amplified upon coronavirus infection. Our findings indicated that 2-DG could be a potential drug to improve the host defense system in coronavirus-infected cells.

Ergonomics-oriented operation, maintenance and control of indoor air environment for public buildings

In response to the construction process of Healthy China. it is rather important to create a safe, healthy and energy-efficient indoor environment for public buildings. The public building space is often densely populated, with a large flow of people and many types of air pollution, which presents non-uniform dynamic distribution characteristics. This brings great challenges to the control of indoor air safety, especially during the pandemic period of COVID-19. Excessive ventilation may not only cause large energy waste. but also lead to cross-contamination and even a cluster of infection. In this paper, an operation and maintenance (O&M) control system for indoor air safety is developed based on the core concepts and basic methods of human ergonomics. In this system, one of the important human environmental variables is focused for control, i.e.. indoor air pollution level. Especially after the outbreak of COVID-19. droplets and droplet nuclei from respiration are the most significant air pollution categories required for mitigation. Towards the efficient control of air pollution in large public buildings. it should further take into account the interaction of human, equipment and machines (i.e., ventilation_ air purification and disinfection and intelligent control system) and building environment. Firstly, on the basis of the online monitoring of indoor air pollution concentration and personnel flow, the non-uniform dynamic distribution of indoor pollutants and personnel can be obtained by using the non-uniform and low-dimensional rapid prediction models and computer vision processing. Then, the optimal setting results of ventilation parameters (e.g., ventilation modes, supply air rate. etc.) can be outputted by the environmental control decision system. Finally, based on a combination of monitoring sensors, controllers and actuator hardware equipment (at the location of fans or dampers), the intelligent regulation and control of ventilation system can be realized, aimed at minimizing energy consumption and reducing pollutant concentration and exposure level. Meanwhile, the air purification and disinfection system (especially for the disinfection of virus particles) are operated under the condition of the ventilated environment, which can serve as a powerful auxiliary to the maintenance of indoor air safety. The workflow and effect of the O&M control system are demonstrated by an engineering application case of the front hall in the International Convention and Exhibition Center. The results indicate that the non-uniform and low-dimensional rapid prediction model for pollutant concentration is effective for the ventilation control with the average prediction difference of 11.9%. The implementation of the intelligent ventilation system can reduce the risk of human infection to less than 4%. and its energy-saving ratio for the ventilation can be as high as about 45%. Through optimizing the layout strategies of disinfection devices based on the intelligent ventilation control, the space accessibility of negative oxygen ions can be well accepted, to further increase the removal efficiency of air pollution. The calculated value of space disinfection rate is more than 99%, which can further reduce the risk of infection by 1-2 orders of magnitude. This study can provide an important reference for the promotion and upgrading of O&M control system for indoor air safety.

Dependence of SARS-CoV-2 (COVID-19) inactivation ability on the crystallinity level of transparent Cu2O thin films

The inactivation ability of SARS-CoV-2 (COVID-19) was examined using two types of transparent Cu2O thin films with different crystallinities on a Na-free glass substrate. The low-crystallinity Cu2O thin film, which was fabricated by irradiating 254 nm ultraviolet (UV)-light with an intensity of 6.72 mW cm(-2) onto a spin-coated precursor film involving Cu2+ complexes at room temperature, exhibited an outstanding COVID-19 inactivation ability to reduce 99.999% of the virus after 1 h of incubation. The X-ray diffraction results of the UV-irradiated thin film indicated a cubic Cu2O lattice with a small crystallite size of 2 +/- 1 nm. Conversely, the high-crystallinity Cu2O thin film with a crystallite size of 16 +/- 3 nm, obtained by heating a spin-coated precursor film containing another Cu2+ complex, showed a negligibly low inactivation activity at the same level as the Na-free glass substrate. The eluted concentrations of Cu ions from both Cu2O thin films were analyzed after immersion in Dulbecco's modified Eagle's medium (DMEM) for 0.25-2 h. The eluted Cu-ion concentration of 1.16 ppm was observed for the UV-irradiated thin film by DMEM immersion after 1 h, but that of 0.04 ppm was observed for the heat-treated thin film. This indicated that an important factor of virus inactivation on Cu2O thin films is highly related to the elution of Cu ions that occurred from the surface in the medium.

Functional Textile Materials for Blocking COVID-19 Transmission.

The outbreak of COVID-19 provided a warning sign for society worldwide: that is, we urgently need to explore effective strategies for combating unpredictable viral pandemics. Protective textiles such as surgery masks have played an important role in the mitigation of the COVID-19 pandemic, while revealing serious challenges in terms of supply, cross-infection risk, and environmental pollution. In this context, textiles with an antivirus functionality have attracted increasing attention, and many innovative proposals with exciting commercial possibilities have been reported over the past three years. In this review, we illustrate the progress of textile filtration for pandemics and summarize the recent development of antiviral textiles for personal protective purposes by cataloging them into three classes: metal-based, carbon-based, and polymer-based materials. We focused on the preparation routes of emerging antiviral textiles, providing a forward-looking perspective on their opportunities and challenges, to evaluate their efficacy, scale up their manufacturing processes, and expand their high-volume applications. Based on this review, we conclude that ideal antiviral textiles are characterized by a high filtration efficiency, reliable antiviral effect, long storage life, and recyclability. The expected manufacturing processes should be economically feasible, scalable, and quickly responsive.

Polyethylene glycol sensitization in patients with recurrent urticaria: Something to consider before the administration of the mRNA COVID-19 vaccine

Background: Polyethylene glycol (PEG) and polysorbate are two commonly used excipients in cosmetics, therapeutics, and processed foods. They are used not just to stabilize and preserve but also to influence the pharmacokinetics and bioavailability of the active ingredients of these products. Numerous reports have described patients with recurrent urticaria self-reporting multiple unrelated products hypersensitivities. We aim to describe a case series of sensitization to PEG in patients with recurrent urticaria and its implications to the currently available COVID-19 vaccines in Malaysia. Method(s): Data of all patients during the peak vaccination period (March 2021 -May 2021) who had positive intradermal test to surrogate PEG and polysorbate 80 were retrieved and analyzed. They were tested with PEG 4000 (macrogol), PEG 400 (Systane Ultra eye drop) and polysorbate 80 (Tween 80). Result(s): A total of eight patients were skin test positive to PEG and/ or polysorbate 80. The mean age was 35.1 +/- 10.5 years. Only one patient was male. Everyone reported history of multiple product reactions with recurrent urticaria as the major symptom. Majority (75%) had multiple unrelated products hypersensitivities. Four of them had urticarial reactions after the first dose of mRNA vaccine. Two patients were skin test negative to the lower molecular weight PEG 400. Cross sensitization between PEG 4000 and polysorbate 80 was 100%. All patients were subsequently inoculated with two doses of inactivated virus COVID-19 vaccine without any serious sequalae. Conclusion(s): The validity of skin testing towards PEG is not yet clear. Nonetheless it is a promising tool in diagnosing PEG sensitization in selected patients reporting recurrent urticaria with multiple unrelated products. Pretesting of this select group may be considered before the inoculation of PEG-containing COVID-19 vaccine.

Epigenetic features, methods, and implementations associated with COVID-19

The infection and life cycle of severe acute respiratory syndrome coronavirus 2 are widely studied, yet multiple gaps exist in the knowledge that affects therapeutic developments against coronavirus disease 2019 (COVID-19). Predominantly caused by a respiratory virus, COVID-19 is not restricted to the respiratory tract but affects multiple organs of the body including the cardiovascular, neurological, immunological, and renal systems. COVID-19 affects all age groups, although the elderly population inherently presenting with multiple comorbidities are disproportionately affected. The majority of the patients experience mild symptoms, although moderate, severe, and critical symptoms occur in a smaller group of patients. Interestingly, the effects of the disease can be acute or chronic and present an ongoing health care challenge. Epigenetic mechanisms of COVID-19 (DNA methylation, histone posttranslational modifications, histone citrullination, etc.) are an emerging field and present enormous potential toward the medical management of COVID-19. Angiotensin converting enzyme 2, an important protein in the cardiovascular system, is a receptor for viral entry into cells, and the epigenetic processes that regulate this protein have been widely studied. Identification of the epitranscriptomic profile has led to the identification of putative biomarkers for disease diagnosis and trials of novel epidrugs for targeted therapy. © 2023 Elsevier Inc. All rights reserved.

Disinfecting Efficacy of an Ozonated Water Spray Chamber: Scientific Evidence of the Total and Partial Biocidal Effect on Personal Protective Equipment and in Vitro Analysis of a Viral Experimental Model

Due to the high recurrence of microbial infections, developing new technologies for preventing the dissemination of pathogens is essential, especially to prevent infection in humans. Thus, devices for the decontamination of surfaces reduce not only the spread of pathogens in the environment, but provide greater security and protection for communities. Ozone (O3) is a substance capable of reducing or eliminating several types of microorganisms owing to its biocidal capacity, including when it is dissolved in water. The objective of this study was to develop an instant decontamination device using ozonated water. To confirm its biocidal action and verify the device's efficacy, the reduction of the microbial load of important pathogens on personal protective equipment (PPE) was assessed. In addition, in order to confirm the biocidal action of ozonated water against SARS-CoV-2, in vitro tests on a viral model of Gammacoronavirus were performed. The results showed the efficacy of ozonated water in the disinfection device at concentration ranges of 0.3–0.6 mg/L and 0.7–0.9 mg/L of ozonated water, with growth reductions above 2 log10 for both concentration ranges tested and inactivation fractions above 60% (0.3–0.6 mg/L) and 80% (0.7–0.9 mg/L), with a high proportion of the tested PPE showing 100% microbial reduction. In vitro results for the evaluation of ozonated water in a viral model showed a 99.9% reduction percentage in the concentration range of 0.3 to 0.5 mg/L and a 99% reduction in the concentration range of 0.6 to 0.8 mg/L, with a 5.10 log EDI50/mL and 6.95 log EDI50/mL reduction, respectively. The instant decontamination system developed in this study proved effective for microbial reduction, and we confirmed the potential of ozonated water as a biocidal agent. Therefore, the proposed decontamination device could be considered as a tool for reducing contamination on surfaces using ozonated water.

Inactivation of Pathogenic Microorganisms on Polymeric Materials through Ozonation

Ozone-based technologies have been evaluated to inactivate the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) on surfaces. However, the vast diversity of information makes it difficult to establish common ground for determining the best practices for using this technology. The objective of this work is to evaluate the success of N95 mask decontamination by ozonation, determining the specific parameters for process control. To quantify the effectiveness of the process, a disinfection protocol was initially developed based on two bacterial species (Escherichia coli and Staphylococcus pseudintermedius), followed by another disinfection assay using the murine hepatitis coronavirus (MHV-3), in a laboratory-scale prototype. Ozone is an effective candidate for use against SARS-CoV-2 or other viruses to disinfect personal protection equipment (PPE). © 2023 Wiley-VCH GmbH.