Approach on environmental health indicators for monitoring the health impact of climate change.
Curseu, Daniela ; Popa, Monica ; Sirbu, Dana Manuela 等
1. INTRODUCTION
During the last years, the concern for climate change and the
associated risks has grown continuously. In Fourth Assessment Report of
the Intergovernmental Panel on Climate Change (IPPC), Working Group II
states clearly that climate change is contributing to the global burden
of disease and premature deaths (IPCC, 2007). The World Health
Organization (WHO) estimates that the global burden of disease from
climate change had exceeded 150000 excess deaths per year (WHO, 2003).
To develop public health adaptation strategies and to project the
impacts of climate change on human health, indicators of vulnerability
and preparedness along with accurate surveillance data on
climate-sensitive health outcomes are needed.
For this reason, we aimed in present study to identify
environmental health indicators that could serve as important tools for
environmental health practitioners and policy makers responsible to
anticipate, assess and reduce the adverse health impacts of climate
change. The analysis is primarily based on a limited literature review
of climate change and health, with particular attention to the
identification of outcomes and actions related to climate change that
could inform about the development of a "suite" of climate
change environmental health indicators. The indicators discussed in this
paper include not only climate-sensitive health outcomes but also
environmental, population vulnerability, and mitigation and adaptation
indicators.
2. ENVIRONMENTAL HEALTH INDICATORS
2.1 Environmental indicators Air quality
The main greenhouse gases (GEGs) released by human activities are
carbon dioxide, methane, nitrous oxide, chlorofluorocarbons (CFCs), and
halons. How much emissions of greenhouse gases add to the potential for
global warming depends on how long they remain in the atmosphere before
being removed or breaking down into other compounds and on how well they
absorb the heat radiated by the earth. These two factors are combined in
the Global Warming Potential (GWP) for each gas, which is used as a
weighting factor for emissions of that gas. The weighted summation of
the annual discharge of [CO.sub.2], [CH.sub.]4, [N.sub.2.]O, and the use
of CFCs and halons, expressed in CO2 equivalents, forms the indicator
for climate change. [CO.sub.2] equivalents are obtainable from
Environmental Protection Agency, whereas starting with 2007 Romanian
government has issued a series of national laws to begin GEGs
monitoring.
A warmer climate and thermal extremes temperatures associated with
air mass stagnation events may increase exposure to urban air pollution
and will affect regional and local air pollution concentrations. This
has the potential to aggravate pre-existing respiratory and
cardiovascular conditions, but it is difficult to determine which
proportion of increase of air pollutants is attributable to elevated
warming from climate change and which is due to anthropogenic sources.
Meteorological data
Both high temperatures and humidity increase an individual's
risk of heat illness. Increasing temperatures directly raise body
temperature, and increased humidity slows cooling of the body by
decreasing sweat evaporation. For this reason we consider the following
indicators are important to be track: the temperature--maximum
temperature, minimum temperatures, and apparent temperature (or heat
index, which combines humidity and temperature, and is important in
looking at mortality effects) and the wind speed (because the air mass
stagnation events are favorable for acute air pollution in urban). Daily
information on temperature, relative humidity, and wind speed are easily
obtainable from the National Institute of Meteorology, but there are few
difficulties in linking weather and health outcome data on the same
spatial and temporal scales. Health effects are more evident when
extreme weather events occur. Meteorological events are classified as
"extreme" on the basis of three criteria: rarity (i.e., that
occur with relatively low frequency/rate); intensity (i.e.,
characterized by relatively small or large values compared to the norm);
and severity (i.e., that result in large socio-economic losses).
Indicators of direct climate effects include regional annual heatwaves
and precipitation levels. Heatwave is defined as a period of at least
five days, each of which has a maximum temperature of at least
25[degrees]C, including at least three days with a maximum temperature
of at least 30[degrees]C (Huynen, 2001). Precipitation extremes can be
described in different ways: precipitation deficits are often expressed
as the number and duration of dry periods (that can lead to droughts);
high precipitation events expressed as the number of wet days,
consecutive wet days, and the frequency and intensity of heavy
precipitation events (that can result in fast flash floods, or
devastating floods, affecting large catchments and having longer
duration).
2.2 Health indicators
The potential health effects of climate change have been
extensively reviewed. Because of the multifactorial nature of diseases,
a carefully selection of those indicators that are highly sensitive to
climate changes but relatively insensitive to other influences is
important.
The study of the consequences of "extreme events" on
health is of relevance because they are likely to increase in frequency
under conditions of climate warming. Because deaths or illness are
rarelly recorded as heat-related during a heat wave, we recommend focus
primarily on excess mortality and morbidity. Morbidity and mortality data are available from National or Regional Centers for Health
Statistics. Excess mortality can be calculated by comparing the number
of deaths during an extreme event with those during a reference period
that has been matched by day of the week and other potentially
confounding factors, or by using a time-series approach. Also, we
propose the rate of hospitalizations as well as rate of emergency
department visits as useful indicators of heat related health outcomes.
Other indicators can be used to project future health impacts based on
changes in exposure, assuming exposure-response relationships remain
constant over temporal and spatial scales. Thus, it is likely that the
first detectable changes will be changes in the geographic range
(latitude and altitude) of certain vector-borne infectious diseases
and/or in the seasonality of the diseases (Curseu et al., 2010). Gaps in
surveillance data for human cases of environmental infectious diseases
and vectors and reservoirs are related primarily to the lack of
surveillance infrastructure and lapses in communication.
2.3 Population vulnerability indicators
Eriksen and Kelly (2007) assessed the credible vulnerability
indicators for climate adaptation policy and concluded that the
vulnerability of a population depends on factors such as population
density, age structure of the population, pre-existing health status and
the quality and availability of public health care, as well as level of
economic development, food availability, income level and distribution.
Data on the first four of these usually are available at aggregate level
from routine sources of demographic and health statistics. Socioeconomic
data often are available in fairly crude form, but it is easier to
obtain markers that have direct bearing on the health impact of
interest. Recommended indicators include the percentage of elderly,
those in poverty, infants, and populations affected by chronic diseases
(especially cardiovascular and respiratory disease) or receiving drug
treatment, the obese and disabled, as well as pregnant and nursing
women.
2.4 Mitigation and adaptation indicators
Use of renewable energy sources can be an alternative to this
problem (Popa et al., 2008). Evans et al. (2009) have given some
sustainability indicators for some renewable technologies. The ranking
according to the corresponding indicator suggests electricity production
from wind is the most sustainable followed by hydropower and then solar
and geothermal were found to rank the lowest from the four
non-combustion renewable energy technologies (Evans et al., 2009).
Proposed mitigation indicators are use of renewable energies, and
vehicle miles traveled. Adaptation is just as important as mitigation to
reduce short-term and longer term health risks. Adaptation indicators
are needed to measure the status of public health efforts to avoid,
prepare for, and effectively respond to the risks of climate change.
Proposed adaptation indicators include community access to cooling
centers during heat waves, early warning systems, surveillance systems
that collect data on the human health effects of climate change, and a
public health workforce trained in climate change research,
surveillance, or adaptation.
3. CONCLUSION
There is evidence that climate change has already affected human
health through direct and indirect pathways. In order to evaluate these
impacts, we presented surveillance indicators that include not only
climate-sensitive health outcomes but also environmental, population
vulnerability, and mitigation and adaptation indicators of climate
change.
The health indicators must allow the enhanced surveillance of
climate sensitive diseases in order to detect and respond to health
impact of climat change. Developing these indicators is vital for
evaluation program, health service planning, and communication. For
example, tracking the number of visits at emergency department as well
as the rate of hospitalization during heatwave may assist public health
professionals to design targeted adaptation and response options for
their specific regional requirements.
From the perspective of users of surveillance databases, it is
essential that relevant existing databases be easily identified, that
appropriate indicators be provided, and that processing of the data be
done at a level suitable for investigators in multidisciplinary
projects. Data gaps are especially critical for some environmental and
population vulnerability indicators. Also, no domestic surveillance
database exists for deaths and injuries for extreme weather events.
Understanding the capacity of a population to adapt to new climate
conditions is also essential in order to achieve a more realistic
assessment of the potential health impacts of climate change.
In conclusion, the indicators proposed in this paper are not an end
in themselves. We hope that, if they are used with wisdom and restraint,
they will serve as tools that can build support for needed actions.
4. ACKNOWLEDGEMENTS
The paper was realized in frame of the National Research Grant
IGLOB 42-117 PN- II 2008.
5. REFERENCES
Curseu, D.; Popa, M.; Sirbu, D. & Stoian, I. (2010). Potential
impact of climat change on pandemic influenza risk. In: Global Warming:
Engineering Solution. Dincer, I., Midilli, A., Hepbasli, A. &
Karakoc, T.H. (Eds.), pp. 643-657, Springer, ISBN 978-1-4419-1016-5,
Milton Keynes UK
Evans, A.; Strezov, V. & Evans, T. (2009). Assessment of
sustainability indicators for renewable energy technologies. Renewable
and Sustainable Energy Reviews Vol.13, No.5, (June 2009) pp. 1082-1088,
ISSN: 1364-0321
Eriksen, S.H. & Kelly, P.M. (2007). Developing Credible
Vulnerability Indicators for Climate Adaptation Policy Assessment.
Mitigation and Adaptation Strategies for Global Change, Vol. 12, No. 4
(May 2007) Springer Netherlands, pp. 495-524, ISSN 1381-2386
Huynen, M.M.T.E. et al. (2001). The impact of cold spells and
heatwaves on mortality rates in the Dutch population. Environmental
Health Perspectives Vol.109 No.5 (May 2001) pp. 463-70 ISSN: 0091-6765
Popa, M.S.; Contiu, G.; Precup, M. (2008). Unconventional
Technologies and Competitive Engineering in the 21th Century, In
Proceedings of Tools and Methods of Competitive Engineering (TMCE)
Symposium, Horvath & Rusak (Eds.), Vol. II, pp.1075-1086, ISBN
978-90-5155044-3, April 2008, Izmir, Turkey, published by Delft Univ. of
Technology, Netherlands
*** IPCC. (2007). Climate change 2007. Impacts, adaptation, and
vulnerability, Contribution of Working Group II to the Fourth Assessment
Report of the Intergovernmental Panel on Climate Change, Parry, M.L.,
Canziani, O.F., Palutikof, J.P., van der Linden, P.J.(Eds.) ISBN 978
0521 70597-4 New York:Cambridge University Press
*** WHO (2003). Climate change and human health: risks and
responses. McMichael,A. J. et al. eds. Geneva 2003 ISBN 924156248X
