ABSTRACT
Maintenance hemodialysis patients need to return to hospital 3 times a week for routine hemodialysis treatment. In the case of coronavirus disease 2019 (COVID-19) and regional lockdown, a set of management systems and standardizations has been established in our hemodialysis center, including forward movement of the critical nodes of treatment, specialists pooling program for hemodialysis technology, and dynamic bubble personnel management, to implement dynamic prevention and control strategies, precise management of inpatient wards and closed-loop management of outbreaks. While improving the management of our own hemodialysis center, it is recommended to strengthen multi-center collaboration to build a municipal grid management system for hemodialysis and explore different dialysis strategies for end-stage renal disease to meet the treatment needs and safety management of maintenance hemodialysis patients in lockdown areas under the epidemic.Copyright © 2022, Second Military Medical University Press. All rights reserved.
ABSTRACT
Maintenance hemodialysis patients need to return to hospital 3 times a week for routine hemodialysis treatment. In the case of coronavirus disease 2019 (COVID-19) and regional lockdown, a set of management systems and standardizations has been established in our hemodialysis center, including forward movement of the critical nodes of treatment, specialists pooling program for hemodialysis technology, and dynamic bubble personnel management, to implement dynamic prevention and control strategies, precise management of inpatient wards and closed-loop management of outbreaks. While improving the management of our own hemodialysis center, it is recommended to strengthen multi-center collaboration to build a municipal grid management system for hemodialysis and explore different dialysis strategies for end-stage renal disease to meet the treatment needs and safety management of maintenance hemodialysis patients in lockdown areas under the epidemic.Copyright © 2022, Second Military Medical University Press. All rights reserved.
ABSTRACT
Objective To analyze the epidemiological characteristics of surveillance results of public health emergencies of communicable diseases in Shenzhen from 2016 to 2020. Methods The data of public health emergencies in Shenzhen from 2016 to 2020 were derived from National Public Health Emergency Reporting Management Information System, the occurrence characteristics of epidemic outbreak were analyzed by disease types, regions and institution types, and SPSS 22. 0 was used for statistical analysis. Results The events of COVID-19 reported in 2020 were excluded,a total of 233 public health emergencies of for communicable diseases were reported, with 6 271 cases and 2 deaths were reported in Shenzhen from 2016 to 2020. The attack rate was 3. 87%, and the fatality rate was 0. 03%. The highest prevalence rate was 5. 20% in 2018. There were 164 clustered epidemic events, accounting for 70. 39% of the total information related to public health emergencies, involving 7 types of communicable diseases. Chicken pox (100 incidents,3 565 cases) and infectious diarrhea (41 incidents, 1 491 cases) were the found to be the most common diseases, accounting for 60. 98% and 25. 00% of the total clustered epidemic events, respectively. There were 78. 45% of the clustered events of respiratory communicable diseases occurred in primary schools, and 58. 33% of the clustered events events of intestinal diseases occurred in kindergartens. The difference was statistically significant in the composition ratio of the two kinds of communicable diseases in kindergartens, primary schools, middle schools, high schools, colleges and universities and other places. Conclusion A comprehensive prevention and control strategy should be adopted. The comprehensive control strategies should be formulated from aspects including the reduction of population susceptibility, implementing of early reporting and school suspension measures, monitoring of epidemic strains, and strengthening of personal hygiene protection habits for communicable diseases with high risk among different populations. © 2022, Editorial Department of Medical Pest Control. All rights reserved.
ABSTRACT
The COVID-19 pandemic imposes a severe challenge to the health care providers and patients in dental clinics as the dental procedures produce abundant airborne materials. Although dental practices use a multi-layered protective procedure to reduce the potential danger from dental aerosols, it is still beneficial to suppress the aerosol generation from the origin as much as possible. Reducing the aerosol generation (especially the droplets of smaller diameters) from the very beginning will ease the burden on all subsequent layers of protection. In this work, we first provide a relatively complete picture of the structure of the spray produced by the air turbine handpiece. We found that the spray consists of two domains: one is the canopy shaped centrifugal zone and the other is a dense ballistic spray core. The droplets from the centrifugal zone are much smaller than those of the spray core and, hence, are more prone to stay in the air. The location of the centrifugal zone also makes it more challenging to be contained by the mouth or rubber dam. To suppress the atomization of the centrifugal zone, we used the food-additive carboxymethylcellulose sodium (CMC-Na) water solutions of different concentrations. The data show that the viscoelastic property of the 0.5 wt. % CMC-Na water solution can effectively suppress the aerosol generation of the centrifugal zone. (C) 2022 Author(s).