AIRBORNE ALGAE: THEIR PRESENT STATUS AND RELEVANCE1

Ongoing climatic changes coupled with various natural processes and the outcomes of human activities are not only loading the atmosphere with diverse kinds of biological particles but also changing their prevalence and spatial distribution. Despite having considerable ecological and economic significance, including their possible impact on human health, airborne algae are the least‐studied organisms in both aerobiological and phycological studies. The present review has been written to bring together all available information, including a brief survey of the literature, the ecology of airborne algae, mechanisms involved in their aerosolization, the role of environmental factors in shaping the structure and composition of aero‐algal flora, and other significant information associated with airborne algae. This review provides information on methodological approaches and related problems, along with suggestions for areas of future research on airborne algae.     

Using selective media to assess aerosolization damage and ultraviolet germicidal irradiation susceptibility of Serratia marcescens

This study determined whether selective media, McConkey agar (MC) and minimal salt glucose agar (MA) are suitable for monitoring aerosolization damage of airborne Serratia marcescens in our laboratory aerosol exposure system and assessed the relationship between bacterial culturability in these media and ultraviolet germicidal irradiation (UVGI) susceptibility of the bacteria. Two types of bacterial cultures were prepared. The first culture was taken from bacteria growing on Tryptic soy agar (TSA) as complete medium (fresh culture), which provided nearly 100% of MC/MA tolerant bacteria, while the second one was prepared from freezing the fresh culture (frozen culture), which produced 55 and 81% of MC and MA tolerant bacteria, respectively. We monitored bacterial culturability in TSA, MC and MA from these cultures in the nebulizer reservoir and bioaerosls collected on a six-stage Andersen cascade bio-impactor. The results indicated that both concentration and percentage of MC/MA tolerant bacteria maintained at a similar level during nebulization. For the bioaerosols, although the concentration recovered in the media from the fresh culture was higher than that from the frozen culture, the percentage of MC/MA tolerant bacteria was similar to that before aerosolization. We concluded that MC and MA are not suitable for monitoring aerosolization damage of the bacteria. Moreover, culturability of the bacteria in MC and MA has no effect on their survival after aerosolization. With respect to the bacterial susceptibility to UVGI, MC/MA sensitive and tolerant population as well as the fresh and frozen cultures showed the same susceptibility.     

A nested real-time PCR assay has an increased sensitivity suitable for detection of viruses in aerosol studies

Aims:  Influenza is commonly spread by infectious aerosols; however, detection of viruses in aerosols is not sensitive enough to confirm the characteristics of virus aerosols. The aim of this study was to develop an assay for respiratory viruses sufficiently sensitive to be used in epidemiological studies.
Method:  A two-step, nested real-time PCR assay was developed for MS2 bacteriophage, and for influenza A and B, parainfluenza 1 and human respiratory syncytial virus. Outer primer pairs were designed to nest each existing real-time PCR assay. The sensitivities of the nested real-time PCR assays were compared to those of existing real-time PCR assays. Both assays were applied in an aerosol study to compare their detection limits in air samples.
Conclusions:  The nested real-time PCR assays were found to be several logs more sensitive than the real-time PCR assays, with lower levels of virus detected at lower Ct values. The nested real-time PCR assay successfully detected MS2 in air samples, whereas the real-time assay did not.
Significance and Impact of the Study:  The sensitive assays for respiratory viruses will permit further research using air samples from naturally generated virus aerosols. This will inform current knowledge regarding the risks associated with the spread of viruses through aerosol transmission.     

Aerosolization as novel sanitizer delivery system to reduce food-borne pathogens

AIMS: As a preliminary experiment on new sanitizer delivery tools, the efficacy of aerosolized sanitizer on food-borne pathogens was investigated in larger model chamber system. METHODS: Peroxyacetic acid and hydrogen peroxide were aerosolized in a model system against artificially inoculated target micro-organisms on laboratory media. Cultures of four different food-borne pathogens were inoculated and affixed onto three different heights (bottom, wall and ceiling), and three different orientations (face-down, vertical and face-down) inside a commercial semi-trailer cabinet (14.6 x 2.6 x 2.8 m). Sanitizer was aerosolized into 2 microm droplet size fog and treated for 1 h at ambient temperature. RESULTS: Populations of Bacillus cereus, Listeria innocua, Staphylococcus aureus, and Salmonella typhimurium were reduced by an average of 3.09, 7.69, 6.93 and 8.18 log units per plate respectively. Interestingly, L. innocua, Staph. aureus, and Salm. typhimurium showed statistically not different (P >/= 0.05) reduction patterns relative to height and orientation that were never expected in a spraying system. CONCLUSIONS: Aerosolized sanitizers diffuse like gaseous sanitizers. SIGNIFICANCE AND IMPACT OF THE STUDY: Aerosolization has great potential for use in commercial applications.     

Surrounded by mycobacteria: nontuberculous mycobacteria in the human environment

A majority of the Mycobacterium species, called the nontuberculous mycobacteria (NTM), are natural inhabitants of natural waters, engineered water systems, and soils. As a consequence of their ubiquitous distribution, humans are surrounded by these opportunistic pathogens. A cardinal feature of mycobacterial cells is the presence of a hydrophobic, lipid-rich outer membrane. The hydrophobicity of NTM is a major determinant of aerosolization, surface adherence, biofilm-formation, and disinfectant- and antibiotic resistance. The NTM are oligotrophs, able to grow at low carbon levels [>50 μg assimilable organic carbon (AOC) l⁻¹], making them effective competitors in low nutrient, and disinfected environments (drinking water). Biofilm formation and oligotrophy lead to survival, persistence, and growth in drinking water distribution systems. In addition to their role as human and animal pathogens, the widespread distribution of NTM in the environment, coupled with their ability to degrade and metabolize a variety of complex hydrocarbons including pollutants, suggests that NTM may be agents of nutrient cycling.