Airborne particulate matter (PM), e

Airborne
particulate matter (PM),
especially
complex
dynamic mixture
components
chemical
biological origins
different
properties
In
the past decade, many research projects have investigated the risks
that PM poses to human health and to ecosystems (Samet et al.,
2006), but these studies have typically focused on nonbiological
particles (Colbeck and Lazaridis, 2009). In recent years, research
interest has grown concerning the biological fraction of PM (bioaerosols)
(Jones and Harrison, 2004), and an increasing body of
evidence suggests that the biological fraction may play a critical
role in the effects of PM on human health and on biological systems
(D'Amato et al., 2002; Jaenicke, 2005). Lee et al. (2006) reported
that bioaerosol sources are often located outdoors, therefore, the
influence of these sources on human exposure largely depends on
the fraction of outdoor bioaerosol, which is subjected to indoor
penetration. However, the bacteria in indoor air can originate from
the outdoor environment or from anthropogenic sources such as
the building's occupants and human activities. Many people spend
more than 90% of their time in an indoor environment (Klepeis et
al., 2001). Because children spend a considerable amount of time
in kindergarten (approximately 40 h per week), it is extremely
important to ensure that conditions are appropriate and advantageous
for their health and development. Recently, there has been
great concern about the potential health hazards of biological
components in airborne PM, especially about the levels of allergenic
or toxigenic bacteria and their association with indoor air
quality (Zucker and Muller, 2004; Liao et al., 2010; Hsu et al., 2011).
Gram-negative bacteria that produce endotoxins possess strong
allergens and are associated with respiratory diseases. Endotoxins
can cause acute toxic effects, including fever, malaise, and asthma
(Di Giorgio et al., 1995). In Singapore, an increase in the mortality
rate from asthma was observed in children 5e14 years of age from
0.21 per 100,000 persons in the 1970s to 0.72 per 100,000 persons
in the 1990s (Ng and Tan, 1999). This rising trend has also been
reported in Hong Kong (So et al., 1990). The prevalence of asthma
has increased in Hong Kong over the past two or three decades,
especially in children.
Given their age and susceptibility, young children may be more
likely than adults to suffer from the potential health hazards of
airborne bacteria (Kahan et al., 2005). Pathogenic bacteria in the air
are of particular concern as potential causes of disease in children.
However, no previous studies have investigated the indoor biological
contaminants of inhalable PM2.5, especially in sensitive
groups such as young children 2e6 years of age. Several studies
have been carried out on indoor and outdoor airborne bacteria
using traditional culture-based methods (Fang et al., 2007; Kim and
Kim, 2007; Zhu et al., 2003). The results of several of these studies
showed the diversity of the community of indoor airborne bacteria
in a kindergarten, but the culture-based methods constrained the
identification to a limited number of cultivable species. Thus, we
aimed to use a molecular method to detect the concentration and
community distribution of both cultivable and non-cultivable
bacteria in inhalable PM2.5 samples that affect indoor air quality
and children's health in kindergartens in Hong Kong.
With the development of modern molecular biotechnologies, a
variety of molecular approaches were developed and used to study
bacterial diversity. Among these tools, terminal restriction fragment
length polymorphism (T-RFLP) method was seen as a rapid,
moderate-cost and high throughput molecular tool for assessing
bacterial community structure (Païss
e et al., 2010). T-RFLP used
restriction site polymorphisms in PCR-amplified rRNA genes to