The public debate about possible adverse health effects
from exposure to electromagnetic fields (EMFs) from cellular phones and
base stations is
one of the risk issues that occupies many political decision makers across
Europe (Burgess 2004). Because scientists cannot exclude the possibility
that EMFs may cause health problems [Independent Expert Group on Mobile
Phones (IEGMP) 2000; National Radiological Protection Board (NRPB) 2003;
Strahlenschutzkommission
(SSK) 2001], the application of the precautionary principle is heatedly
discussed in many countries. For instance, the IEGMP indicated that the
balance of
evidence showed no adverse health effects from exposure to radio frequency
radiation from mobile phone technologies. However, the group still recommended
that “a precautionary approach to the use of mobile phone technologies
be adopted until much more detailed and scientifically robust information
on any health effects becomes available” (IEGMP 2000, p. 3).
Essentially, the precautionary principle recommends that action should
be taken to prevent serious potential harm, regardless of scientific uncertainty
as to the likelihood, magnitude, or cause of that harm. By considering precautionary
measures, political decision makers hope to cope with these public fears
about EMFs. Various courses of action are taken into consideration, including
health-related measures such as exposure minimization strategies or stricter
exposure limits, process-related measures such as better risk communication
and enhancing public participation in base station siting decisions, and
research-related measures (Wiedemann et al. 2001). In various countries,
different options have been chosen, such as participatory site selection
of base stations in the Netherlands, stricter exposure limits in Switzerland,
and better risk communication in the United Kingdom (public access to databases
revealing the sites and technical features of the base stations), as well
as labeling of cellular phones (discussed also in Germany) and general exposure
reduction measures, just to name a few [Bundesamt für Strahlenschutz
(BfS) 2004; NRPB 2005; TCO 2001].
Although the theoretical status and rationality of the precautionary principle
have been discussed in many papers (Commission of the European Communities
2000; Foster et al. 2000; Kriebel et al. 2001; Marchant 2003) and conferences
[Grandjean et al. 2003; Raffensberger and Tickner 1999; World Health Organization
(WHO) 2003], only a few empirical studies analyze the impact of precautionary
measures on risk-related attitudes and beliefs.
Risk Perceptions as Triggers for Precautionary Action
Whether public risk perception should be a stimulus for invoking precautionary
measures in risk management is a sensitive question (Goldstein and Carruth
2004). Opponents to this approach stress the point that risk management should
be based on sound science using the best available scientific evidence. They
assume that perceived risk differs from assessed risk in that it may more
readily be manipulated. In addition, they fear that precautionary measures
may undermine the scientific basis for the established exposure limits. In
their view, precautionary measures for EMFs should be adopted only with great
care.
Proponents argue that public risk perception should be taken into account
in decisions about risk management: When the public is concerned about a
risk, risk managers should address these concerns by invoking additional
protective measures. Furthermore, they underline that societal values and
public willingness to accept a risk are key factors in determining a society’s
level of protection. Thus, public risk perception must be recognized as a
factor in the decision to apply precautionary measures. That is, in addition
to scientific data, knowledge gained from the practical experience of professionals
and risk perceptions of lay people are seen as a valid basis for making decisions
about when to invoke precautionary measures (e.g., Gee and Stirling 2003;
Tickner 2003).
Research Questions
Several studies have investigated the impact of risk communication on risk
perception (e.g., MacGregor et al. 1994; Morgan et al. 1985; Purchase and
Slovic 1999; Schütz and Wiedemann 1995). However, to date, no one--at
least to our knowledge--has addressed empirically the question of whether
the communication of precautionary measures influences risk perceptions and,
if so, in which direction. This is astonishing, especially because risk perceptions
play a prevalent role in the discussion about the necessity of involving
the precautionary principle.
In this article we focus on the issue of how people react to the implementation
of the precautionary principle. The key is the impact of precautionary measures
on risk perceptions. Two opposing hypotheses can be derived from the current
available literature. First, precautionary measures will increase trust in
risk management, and, in turn, increased trust in risk management will be
associated with lower risk perceptions. Second, the alternative hypothesis
points to the possibility that precautionary measures will be considered
a cue that the risk might be real. Here, perceived risk should be amplified.
As discussed above, the reason for invoking the precautionary principle
is scientific uncertainty. Thus, it would be of interest to see whether emphasizing
the uncertainty in scientific knowledge about EMF risks will affect risk
perception. We conducted two experiments to address these questions. In the
first experiment, health-related precautionary measures served as stimuli;
in the second experiment, a process-related precautionary measure was used:
public participation.
Experiment 1
The first experiment focused on the effect of two independent variables: a)
health-related precautionary measures and b) experts’ uncertainty
about the sufficiency of health protection. Two dependent variables were
used: perceived risk of electrosmog and the perceived quality of scientific
knowledge about health risks from electrosmog.
Table 1
|
Materials and methods. These questions were investigated
in an experimental study using 4
2
factorial design. The first factor was composed of a basic text and three
different precautionary measures (see Table 1). In the “no precaution” condition,
only the basic text was presented. In the three “precaution” conditions,
the basic text and one of the descriptions of precautionary measures were
provided. Those descriptions used phrases that reflect measures and arguments
actually used in regulating the siting of base stations in Germany.
The second factor varied the emphasis of uncertainty. In the “uncertainty” condition,
a sentence that pointed to scientific uncertainty about the sufficiency of
current protection measures was included in the basic text. In the “no
uncertainty” condition, this sentence was missing (see Table 1).
An Austrian ad hoc sample of 246 subjects 18-81 years of age, with a median
age of 24 years (62% female, 38% male), answered a questionnaire that included
one of the eight texts from the experimental conditions. Sampling occurred
in October 2003 among students and employees of the University of Innsbruck,
and subjects were randomly assigned to the experimental conditions. Risk
perceptions and perceived quality of scientific knowledge were collected
with a 7-point rating scale asking, “All in all, how threatened do
you feel about electrosmog?” (1 = “I don’t feel threatened
at all”; 7 = “I feel very threatened”) and, “How
do you rate the scientific knowledge about the health risks of electrosmog?” (1
= “In science the knowledge is quite deficient”; 7 = “Scientific
knowledge is quite good”). Subjects were explicitly instructed to answer
the questions from their own subjective perspective, that is, referring to
their beliefs.
At the beginning of the questionnaire, all participants were asked to indicate
their risk perceptions for the following items (on 7-point rating scales):
bovine spongiform encephalopathy (BSE), nuclear power, smoking, genetically
engineered foodstuffs, climate change, and crime. Because these risk judgments
were made before the introduction of the experimental manipulations, they
can serve as an additional check whether--despite the random assignment of
the subjects to the experimental conditions--there were any differences in
risk perceptions among the experimental groups that might confound the results
of this experiment.
Figure 1. Mean ratings (± SEM) for the four “precautionary
measures” conditions.
|
Results. For risk perception, a two-way analysis of variance
(ANOVA) yielded a statistically significant main effect for the precautionary
measures factor (
F3,238 = 3.954;
p = 0.009) and
a statistically insignificant main effect for the uncertainty factor (
F1,238 =
0.730;
p = 0.394). There was no statistically significant interaction
between the two factors (
F3,238 = 0.343;
p =
0.794). Figure 1 shows the average ratings for each of the four conditions
of the precautionary measures factor. Clearly, the mean for the “no
precaution” condition is much lower than the means for the three “precautionary
measures,” which in turn are all close together.
A separate analysis by means of a post hoc test (Tukey HSD) confirms this
visual impression. It is the “no precaution” condition that is
statistically different (p < 0.05) from “special protection
of sensitive areas” and “precautionary limits,” and marginally
statistically different (p = 0.074) from “exposure minimization.” The
three “precautionary measures” conditions do not differ significantly
from each other.
To determine whether these significant effects were produced by experimental
variation, we conducted separate ANOVAs between the eight experimental treatment
groups (resulting from the two factors “precautionary measures” and “uncertainty”)
for the other risk items appraised before the experimental variation (BSE,
nuclear power, smoking, genetically engineered foodstuffs, climate change,
and crime) as dependent variables. None of these six ANOVAs yielded a statistically
significant effect. This supports the notion that it was in fact the experimental
manipulation that produced the differences in risk perception, and not some
chance effect.
For the second dependent variable, the perceived quality of scientific
knowledge about potential health risks of electrosmog, we found no statistically
significant effect.
Experiment 2
The second experiment focused on the impact of a process-related precautionary
measure on perceived risk of electrosmog, perceived quality of scientific
knowledge and--as an additional variable--trust in public health protection.
As in the first experiment, we also varied the experts’ uncertainty
about the sufficiency of health protection.
Table 2
|
Materials and methods. In this experiment we used a 2
2
factorial design. The first factor was composed of a basic text (identical
to the one given in the first experiment) and the “public participation” precautionary
measure (Table 2). In the “no precaution” condition, only the
basic text was presented. In the “precaution” conditions, the
basic text plus the text about the public precaution measure was provided.
The second factor was identical to the one used in the first experiment:
In the “uncertainty” condition, a sentence that pointed to scientific
uncertainty about the sufficiency of current protection measures was included
in the basic text. In the “no uncertainty” condition, this sentence
was missing (Table 2).
Three 7-point rating scales were used to collect the ratings for the dependent
variables (risk perception, trust in health protection, and quality of scientific
knowledge). The wording of the scales was as follows: Risk assessment: “All
in all, how threatened do you feel about electrosmog?” (1 = “I
don’t feel threatened at all”; 7 = “I feel very threatened”);
trust: “How much do you trust that the health protection of the public
is ensured?” (1 = “no at all”; 7 = “completely”);
state of the scientific knowledge: “How do you rate the knowledge about
the health effects of electrosmog?” (1 = “the knowledge is quite
deficient”; 7 = “the knowledge is quite good”).
Eighty-four Austrian subjects, recruited in March 2004 among students and
employees of the University of Innsbruck, participated in this experiment.
Subjects were randomly assigned to one of the four experimental conditions
(19-45 years of age; median age, 23 years; 76% female, 24% male). Each subject
received a sheet showing the respective text of the experimental condition
and the three response scales on risk perception, scientific knowledge, and
trust. Subjects were asked to read the text and then to give their ratings
on the three scales. Again, subjects were explicitly instructed to answer
the questions from their own subjective perspective, that is, referring to
their beliefs.
Figure 2. Mean ratings (± SEM) for the two “precautionary
measures” conditions for each of the three dependent variables.
*p < 0.05.
|
Results. For each of the three dependent variables,
we conducted a separate two-way ANOVA. For both “risk perception” and “perceived
quality of scientific knowledge,” we found no statistically significant
main effect for the precautionary measures factor. However, for “trust
in health protection,” the ANOVA yielded a statistically significant
main effect for the precautionary measure factor (
F1,80 =
5.533;
p = 0.021).
Figure 2 shows, for each of the three dependent variables,
the average ratings for the two conditions of the precautionary measures
factor. For
trust, the ratings were lower in the precaution condition. As in the first
experiment, there was no statistically significant main effect of the “uncertainty” factor
for any of the dependent variables.
Discussion
The results of our first experiment strongly support the second hypothesis
stated above: that precautionary measures will be considered a cue that a
risk might be real and increase perceived risk. In experiment 1, the mean
responses for “feeling threatened” were higher in the three “precaution” conditions
than in the “no precaution” condition. Note that also in the
second experiment (using the “public participation” as the precautionary
measure), the results are in the same direction: Under the “precaution” condition,
the mean ratings for “feeling threatened” were higher than under
the “no precaution” condition--however, the difference did not
reach statistical significance.
The second experiment indicates that “public participation” precautionary
measures do not increase trust in public health protection. This result speaks
against the first hypothesis, which states that precautionary measures will
increase trust in risk management, and, in turn, that increased trust in
risk management will be associated with lower risk perceptions.
One may argue that, although statistically significant, the reported effects
are small and thus may not be of practical relevance. But no matter how small
the effects are, they are contrary to the expectations of policy makers who
hope to calm public fears about EMFs by implementing precautionary measures.
The second variable manipulated in the two experiments was the scientific
uncertainty about the sufficiency of current protection measures. This manipulation
did not affect any of the dependent variables (perceived risk, scientific
knowledge, trust in public health protection). This is surprising because
it is this uncertainty that actually provides the reason for applying the
precautionary principle. So one would have expected an effect--at least for
the “scientific knowledge” variable. One can only speculate why
this was the case. Perhaps the experimental manipulation was simply not strong
enough.
Conclusions
Precautionary measures implemented with the intention of reassuring the
public about EMF risk potentials seem to produce the opposite effect. They
may amplify EMF-related risk perceptions and trigger concerns. Referring
to the WHO definition of health [“a state of complete physical, mental
and social well-being and not merely the absence of disease or infirmity” (WHO
1948)], it seems that precautionary measures themselves can be precarious
because they might impair well-being.
The results of the two experiments support the warnings in the WHO background
document (WHO 2000) on cautionary policies “that such policies be adopted
only under the condition that scientific assessments of risk and science-based
exposure limits should not be undermined by the adoption of arbitrary cautionary
approaches.” We tend to add that any precautionary policy should consider
possible countervailing risks such as increasing fear and unnecessarily spreading
anxieties. These adverse impacts of precaution should be brought to the attention
of policy makers.
Of course, these results need to be confirmed in further experiments before
drawing practical conclusions for cautionary policies. They also pose a number
of questions for further research. For instance, why did the uncertainty
condition (i.e., the reference to scientific uncertainty about the sufficiency
of current protection measures) have no effect on risk perception, trust,
or scientific knowledge? And even more important, are there any conditions
under which application of precautionary measures will increase trust in
risk management, which in turn will result in lower risk perceptions?
