[Evaluation of the protective performance of a positive pressure bio-protective clothing against viral aerosol].

OBJECTIVE: To evaluate the protective performance of a positive pressure bio-protective clothing against viral aerosol. METHODS: The suspension of indicating virus phage Phi-X174 was made for viral aerosol generating in a hermetic cabin. The diameter of viral aerosol particles were measured with a aerodynamics size analyzer. By adjusting the inner humidity of the cabin, the protective efficiency of the positive pressure bio-protective clothing against viral aerosol in high and low windshield conditions was determined with Andersen six-stage air sampler sampling and plage forming unit (PFU) counting, respectively. RESULTS: The mass median diameter of Phage Phi-X174 aerosol particles was about 0.922 µm and the background concentration is beyond 2 × 104 particles/m³. The protective efficiency of the clothing against phage Phi-X174 aerosol particles was above 99.9% under different test conditions with the range of viral aerosol concentration between 0 - 23 PFU/m³. Airflow (P = 0.84), environment humidity conditions (P = 0.33) and sampling time (P = 0.07) did not affect the protective efficiency statistically. CONCLUSION: The positive pressure bio-protective clothing provided a relatively high efficiency against phage Phi-X174 aerosol regardless of airflow rate, environment humidity and sampling time.

[A methodological study on testing and evaluating of filtration efficiency of canister against microbial aerosol].

OBJECTIVE: To establish a testing and evaluating method for filtration efficiency of the canister against microbial aerosol. METHODS: Serratia marcescens aerosol served as model of bacterial aerosol, Bacillus subtilis var niger aerosol as model of spores aerosol, bacteriophage f(2) aerosol as model of viral aerosol. Employing the microbial aerosol testing platform was established in lab, models of microbial aerosol generated artificially were sampled quantitatively by air samplers before and after filtrating by canisters, respectively. Filtration efficiency was determined by the concentration of microbial aerosol in the air sample before and after filtrating. The four canisters of 1-1, 1-2, 1-3, 1-4 were tested for the filtration efficiency against Serratia marcescens, Bacillus subtilis var niger and phage f(2) aerosol. The two canisters of 543 and 544 canisters equipped with active carbon were tested for the filtration efficiencies against Serratia marcescens aerosol. RESULTS: The filtration efficiency of 1-1, 1-2, 1-3 canisters against Serratia marcescens, Bacillus subtilis var niger and phage f(2) aerosol was 100.000%. The filtration efficiency of 1-4 canister filtration efficiency against Bacillus subtilis var niger spores aerosol was 99.997% and efficiency of the other two aerosol was 100.000%. The filtration efficiency of the two canisters of 543 and 544 to those attached with active carbon against Serratia marcescens aerosol was 100.000%. CONCLUSION: The testing method might be used to evaluate the protective performance of the canister against microbiological aerosol. The effect of the canisters (including those equipped with active carbon) against microbiological aerosol should be reliable.

Inhalation Study of Mycobacteriophage D29 Aerosol for Mice by Endotracheal Route and Nose-Only Exposure.

BACKGROUND: Lytic mycobacteriophage D29 has the potential for tuberculosis treatment including multidrug-resistant strains. The aims of this study are to investigate deposition and distribution of aerosolized phage D29 particles in naive Balb/C mice, together with pharmacokinetics and evaluation of acute lung injury. METHODS: Pharmacokinetics and BALF (bronchoalveolar lavage fluids) were analyzed after administration of phage D29 aerosols by endotracheal route using Penn-century aerosolizer; Collison 6-jet and Spinning top aerosol nebulizers (STAG) were used to generate phage aerosols with different particle size distributions in nose-only inhalation experiments. After exposure, deposited amounts of phage D29 particles in respiratory tracts were measured, and deposition efficiencies were calculated. A typical path deposition model for mice was developed, and then comparisons were made between predictions and experimentally measured results. RESULTS: Approximately 10% of aerosolized phages D29 reached lung of mouse for pulmonary delivery, and were completely eliminated until 72 h after administration. In contrast, about 0.1% of intraperitoneal injected phages reached the lung, and were almost eliminated at 12 h time point. The inflammation was hardly observed in lung according to the results of BALF analysis. The CMADs (count median aerodynamic diameters) of generated aerosol by Collison and STAG nebulizer were 0.8 µm and 1.5 µm, respectively. After nose-only exposure, measured deposition efficiencies in whole respiratory tract for 0.8 and 1.5 µm phage particles were below 1% and 10%, respectively. Predictions of the computer deposition model compared fairly well with experimentally measured results. CONCLUSIONS: This is the first systematic study of phage D29 aerosol respiratory challenge in laboratory animals. It provides evidence that aerosol delivery of phage D29 is an effective way for treating pulmonary infections caused by Mycobacterium tuberculosis. This research will also provide important data for future inhalation experiments.

[Concentration and Particle Size Distribution of Microbiological Aerosol During Haze Days in Beijing].

In this study, we evaluated the bacterial, fungal aerosol concentration, and particle size distribution using microbiological aerosol sampler, and analyzed the particles count concentration of PM1.0, PM2.5, PM5.0 and PM10.0 using aerodynamic particle sizer during clear and haze days in Beijing during Jan 8th, 2013 to Feb 4th, 2013. The concentration of bacterial, fungal aerosol, air particulate matter and aerosol distribution were compared between haze days and clear days. Our results indicated that the proportion of fungal particles smaller than 5 micron, which could deposit in lungs or deeper regions, was much higher than bacterial particles. The biological concentration of bacteria and fungi were higher in clear days than in haze days, and there was no statistic difference of the microbiological aerosol distribution. The concentration of air particulate matter were higher in haze days than in clear days, PM10 was the main particulate matters both in clear days and haze days.