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Sanitation is the greatest concern in outdoor cat management but ecological message frames promote biodiversity conservation in Japan

Published online by Cambridge University Press:  04 April 2022

Kota Mameno Open the ORCID record for Kota Mameno [Opens in a new window] ,
Takahiro Kubo Open the ORCID record for Takahiro Kubo [Opens in a new window] ,
Takaaki Suzuki Open the ORCID record for Takaaki Suzuki [Opens in a new window] ,
Takahiro Tsuge Open the ORCID record for Takahiro Tsuge [Opens in a new window]  and
Yasushi Shoji Open the ORCID record for Yasushi Shoji [Opens in a new window]
Kota Mameno*
Affiliation:
Department of Resource and Environmental Economics, Graduate School of Agricultural Science, Tohoku University, 468-1 Aramaki Azaaoba, Aobaku, Sendai, Miyagi, 980-8572, Japan
Takahiro Kubo
Affiliation:
Biodiversity Division, National Institute for Environmental Studies, Tsukuba, Japan School of Anthropology and Conservation, University of Kent, Canterbury, UK Department of Zoology, University of Oxford, Oxford, UK
Takaaki Suzuki
Affiliation:
Research Center for Wildlife Management, Gifu University, Gifu, Japan
Takahiro Tsuge
Affiliation:
Graduate School of Global Environmental Studies, Sophia University, Tokyo, Japan
Yasushi Shoji
Affiliation:
Research Faculty of Agriculture, Hokkaido University, Sapporo, Japan
*
Author for Correspondence: Dr Kota Mameno, Email: kota.mameno@gmail.com
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Summary

Message framing contributes to an increase in public support for invasive species management. However, little is known about people’s preferences for the multiple objectives of management within different contexts relating to the challenges and benefits of invasive species management. We examine Japanese citizens’ preferences for the goals of free-roaming unowned cat (Felis catus) management in three contextual frames by applying experimentally controlled information and the best–worst scaling technique. Our results indicate that the ecological frame highlighting the ecological impacts of free-roaming unowned cats on native ecosystems significantly increases Japanese citizens’ concern about cat predation, although the frame did not change the preference ranking of goals. There are differences in the effects of message framing depending on cat ownership. The best–worst scaling technique shows that Japanese citizens prefer to maintain a sanitary environment, followed by the prevention of zoonotic diseases. Although the ranking of sanitary environmental management does not depend on cat ownership, the ranking of the other goals differs depending on cat ownership. The findings highlight the importance of strategic message framing and its prioritization in encouraging public support for invasive species management.

Keywords

best–worst scalingferal cat managementinformation provisionnon-native speciesnudgesocial prioritization
Type
Research Paper
Information
Environmental Conservation , Volume 49 , Issue 2 , June 2022 , pp. 122 - 129
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of Foundation for Environmental Conservation

Introduction

Invasive species exert significant pressures on native ecosystems worldwide. Biodiversity conservation has been the primary reason for invasive species management since the Convention on Biological Diversity (United Nations 1992). However, invasive species management has several benefits beyond biodiversity conservation (Roberts et al. Reference Roberts, Cresswell and Hanley2018, Hanley & Roberts Reference Hanley and Roberts2019), such as in human health and well-being (Halfmann et al. Reference Halfmann, Hatta, Chiba, Maemura, Fan and Takeda2020) and on the local economy (McNeely Reference McNeely2001, McNeely et al. Reference McNeely, Mooney, Neville, Schei and Waage2001). Despite these benefits, invasive species management remains controversial; for example, the lethal management of species tends to raise ethical concerns (Lauber et al. Reference Lauber, Knuth, Tantillo and Curtis2007, Perry & Perry Reference Perry and Perry2008).

Free-roaming unowned cats (Felis catus; hereinafter ‘outdoor cats’) are an illustrative example of an invasive species. Outdoor cat management has significantly contributed to improved biodiversity conservation (e.g., Lowe et al. Reference Lowe, Browne, Boudjelas and De Poorter2000), public health (e.g., Toukhsati et al. Reference Toukhsati, Phillips, Podberscek and Coleman2012) and human well-being (e.g., Halfmann et al. Reference Halfmann, Hatta, Chiba, Maemura, Fan and Takeda2020). Management may also enhance cat welfare because outdoor cats face hazards such as parasites and infectious diseases, traffic accidents and injury from living in car engines or storm drains (e.g., Loyd et al. Reference Loyd, Hernandez, Abernathy, Shock and Marshall2013, Seo et al. Reference Seo, Ueda and Tanida2021). In contrast, outdoor cat management can have a negative impact on human well-being. Interactions with free-roaming and unowned cats can relieve people’s stress and improve human health (e.g., Barker & Wolen Reference Barker and Wolen2008, Levy & Crawford Reference Levy and Crawford2004). Cats can also contribute to killing pests such as mice.

Because cats are originally human companion animals, effective outdoor cat management requires public support (e.g., Lewis et al. Reference Lewis, Granek and Nielsen-Pincus2019, Shackleton et al. Reference Shackleton, Adriaens, Brundu, Dehnen-Schmutz, Estévez and Fried2019). However, owing to both the positive and negative impacts of outdoor cat management, this leads to difficulty in building consensus regarding outdoor cat management among stakeholders, thereby impeding public support for outdoor cat management, and hence impacting its effectiveness (McNeely Reference McNeely2001, McNeely et al. Reference McNeely, Mooney, Neville, Schei and Waage2001). Moreover, policymaking that disregards public opinion may cause issues in outdoor cat management implementation, such as unforeseen costs, delays and public opposition to invasive species management (Estévez et al. Reference Estévez, Anderson, Pizarro and Burgman2015, Crowley et al. Reference Crowley, Hinchliffe and McDonald2017). Therefore, policies and strategies for outdoor cat management must consider ways to build support for conservation based on citizens’ preferences; thus, policymaking should depend not only on natural scientific evidence but also on social scientific evidence (McNeely Reference McNeely2001).

Recently, the application of message-framing strategies has attracted attention as a means of encouraging public support for conservation (Fernández-Llamazares & Cabeza Reference Fernández-Llamazares and Cabeza2018, Reddy et al. Reference Reddy, Wardropper, Weigel, Masuda, Harden and Ranjan2020). In practice, such an application has the advantage of achieving better outcomes without regulating individual choices (Kusmanoff et al. Reference Kusmanoff, Fidler, Gordon, Garrard and Bekessy2020). According to Kusmanoff et al. (Reference Kusmanoff, Fidler, Gordon, Garrard and Bekessy2020), message framing highlights various aspects of an issue and its context and influences people’s choices and behaviours by providing information. For example, alternatively framing climate change as a public health or national security issue rather than an environmental one could increase citizens’ support for measures to address climate change (Myers et al. Reference Myers, Nisbet, Maibach and Leiserowitz2012), as people could recognize the issue as substantively different through the framing approach (Druckman Reference Druckman2001). Moreover, framing the message in terms of public concerns rather than management concerns could theoretically contribute to increasing public engagement with conservation (Entman Reference Entman1993, Rhee Reference Rhee1997). Empirical studies have revealed that message framing concerning the health and safety benefits of keeping cats indoors has encouraged cat owners to keep cats inside (MacDonald et al. Reference MacDonald, Milfont and Gavin2015, McLeod et al. Reference McLeod, Hine, Bengsen and Driver2017). However, other studies have argued that more careful messaging should be developed to avoid unintended consequences (e.g., Wald & Peterson Reference Wald and Peterson2020). Walsh (Reference Walsh2021) noted that effective message framing requires appropriate targeting strategies that adjust messages to take into account, for example, people’s backgrounds and original interests.

In Japan, outdoor cats have been managed in limited areas, such as biodiversity hotspots and local areas in which the local government and non-profit organizations are working vigorously on the outdoor cat issue. Thus, Japan has many areas where outdoor cats are not managed. Moreover, although most Japanese cat owners living in urban areas keep their owned cats inside (Hall et al. Reference Hall, Adams, Bradley, Bryant, Davis and Dickman2016), there are many stray and feral cats (i.e., free-roaming unowned cats), especially in non-management areas. However, there has recently been a growing awareness of the issues associated with outdoor cats in Japan, especially on islands (e.g., Mameno et al. Reference Mameno, Kubo and Suzuki2017, Mitsui et al. Reference Mitsui, Kubo and Yoshida2018, Glen & Hoshino Reference Glen and Hoshino2020), and zoning management has been the primary strategy applied for outdoor cat management (Mameno et al. Reference Mameno, Kubo and Suzuki2017, Ministry of the Environment 2018). In non-residential areas of isolated biodiversity conservation hotspots, environmental managers attempt to eradicate outdoor cats, as they are a significant threat to rare and endemic native species. However, there is no consensus on how to manage Japanese outdoor cats for biodiversity conservation, even at World Heritage sites (Ministry of the Environment 2020). Moreover, although outdoor cats in non-hotspot areas may affect biodiversity maintenance (Lepczyk et al. Reference Lepczyk, Mertig and Liu2004), few outdoor cats are managed to conserve biodiversity in urban and residential areas. In these areas, outdoor cats are actively managed to improve human well-being, as local residents desire the prevention of soiling of the environment with cat excreta (Mameno et al. Reference Mameno, Kubo and Suzuki2017). These unowned outdoor cats in residential areas are generally managed using the trap–neuter–return (TNR) method. However, the issues caused by returned cats raise controversy between cat owners and non-owners in Japan (Mameno et al. Reference Mameno, Kubo and Suzuki2017); for example, returned outdoor cats contribute to the degradation of the sanitary environment, spread disease and depredate native wildlife. Additionally, TNR may be undesirable for cat welfare (Seo et al. Reference Seo, Ueda and Tanida2021). For example, many outdoor cats have health problems such as alopecia, gingivitis, anaemia and feline immunodeficiency virus (FIV) in Japan. Therefore, an outdoor cat management strategy is needed that includes effective communication and applies a message-framing strategy in Japan.

Given the many benefits and challenges of invasive species management, it is necessary to consider people’s preferences for multiple objectives of management within multiple contexts. In this paper, we examine citizens’ preferences for the goals of outdoor cat management in Japan regarding three contextual frames while evaluating the effects of cat ownership on preferences. In addition to the Control (minimum information), the ecological frame highlights information regarding the ecological impacts of outdoor cats on native ecosystems (hereinafter, ‘Ecology’), whereas the risk frame highlights the risks posed by the outdoors to cats’ welfare (hereinafter, ‘Risk’). To elicit preferences, we applied the stated preference approach known as the best–worst scaling (BWS) technique, which was developed in the fields of marketing and economics (Finn & Louviere Reference Finn and Louviere1992, Louviere et al. Reference Louviere, Flynn and Marley2015) and has since been applied to conservation and environmental issues (e.g., Tsuge et al. Reference Tsuge, Nakamura, Usio, Usio and Miyashita2014, Kubo et al. Reference Kubo, Tsuge, Abe and Yamano2018, Tyner & Boyer Reference Tyner and Boyer2020, Shoji et al. Reference Shoji, Kim, Kubo, Tsuge, Aikoh and Kuriyama2021); however, its application to invasive species management has been limited.

Methods

Best–worst scaling design

We applied the BWS technique of Finn and Louviere (Reference Finn and Louviere1992). The objective case (Case 1) of this technique is suitable for our study because, in this case, the alternatives are objects, such as opinions and attitudes (Louviere et al. Reference Louviere, Flynn and Marley2015). The BWS technique elicits citizens’ preferences and uncovers clear differences amongst management goals as participants select the best and worst alternatives amongst multiple-choice answers in questionnaires (Louviere et al. Reference Louviere, Lings, Islam, Gudergan and Flynn2013). For example, consider a choice set of three goals from which a respondent chooses their most and least preferred goals. The choice set comprises Goal A, Goal B and Goal C of invasive management, and the respondent prefers Goal A the most and Goal C the least. In this case, we can obtain information regarding all possible paired comparisons ( $${}_3^{}{C_2}$$ = 3 pairs): Goal A > Goal B, Goal B > Goal C and Goal A > Goal C.

This study focuses on the following four categories of outdoor cat management goals: (1) biodiversity conservation; (2) prevention of zoonotic diseases; (3) maintenance of sanitary environments; and (4) improvement of cat welfare. The biodiversity conservation goal is to prevent cat predation on wildlife; the prevention of zoonotic diseases goal is to protect humans from zoonotic diseases, such as a Toxoplasma gondii infection; the maintenance of sanitary environments goal is to eliminate the issues caused by cat excreta and their dispersing of garbage; and the enhancement of cat welfare goal is to protect cats (including free-roaming pets) from traffic accidents and infections, such as FIV. We assumed a non-correlation with preferences for each goal because most respondents were unaware of the biological relationship between cat faeces and zoonotic disease (e.g., Andiappan et al. Reference Andiappan, Nissapatorn, Sawangjaroen, Khaing, Salibay and Cheung2014). Based on insights from previous studies and the existing methods of cat management strategies in Japan (Mameno et al. Reference Mameno, Kubo and Suzuki2017, Mameno & Kubo Reference Mameno and Kubo2021), we assumed the use of non-lethal options for cat removal in our BWS scenario.

Because the results may be affected by the form of the multiple-choice questions of this study, an essential aspect of the BWS questions is determining the design of the questions that are presented to the respondents. In this study, we applied a balanced incomplete block design (BIBD) to compare each goal (for details, see Raghavarao & Padgett Reference Raghavarao and Padgett2005). The BIBD enables each alternative to appear an equal number of times; each alternative is equally compared with each other alternative across all choice sets (Table 1). In applying the BIBD, four choice sets composed of three attributes were constructed. In the BWS questions, respondents were asked to select a single most desirable goal and a single least desirable goal of outdoor cat management (Supplementary Box S1, available online).

Table 1. Conversion from a balanced incomplete block design (BIBD) to the choice sets. Note: ‘A’ appears in three choice sets on the left side of the table (the first, third and fourth choice set). In these three choice sets, ‘A’ is compared two times each against each of the other goals (i.e., ‘B’, ‘C’ and ‘D’).

We randomly assigned the respondents to three groups in order to evaluate the impact of message framing (e.g., McLeod et al. Reference McLeod, Hine, Bengsen and Driver2017, Shannon et al. Reference Shannon, Quinn, Sutcliffe, Stebbing, Dally, Glover and Dunn2019, Mameno et al. Reference Mameno, Kubo, Shoji and Tsuge2020). The Control was not framed, and the respondents answered the BWS questions without any information. Ecology included messages framing the ecological impacts of outdoor cats and Risk included messages framing the risks posed by the outdoors to cats’ welfare. The message provided for Ecology was that outdoor cats pose substantial threats to biodiversity by preying on wildlife, including rare species. The message provided for Risk was that outdoor cats face serious risks, such as traffic accidents, cat fights and viral infections (Table 2).

Table 2. Information that was provided to each group.

BWS = best–worst scaling.

Econometric analysis

We applied the maximum difference (MaxDiff) model for the econometric analysis (Appendix S1; Finn & Louviere Reference Finn and Louviere1992, Tsuge et al. Reference Tsuge, Nakamura, Usio, Usio and Miyashita2014, Louviere et al. Reference Louviere, Flynn and Marley2015, Tyner & Boyer Reference Tyner and Boyer2020). In our analysis, each management goal was included as a dummy variable. Hence, the utility parameter for the ‘sanitary environment’ was set to zero for identification in order to avoid multicollinearity. The estimated results of each coefficient represent valuations relative to the variable of the sanitary environment. Based on the estimated coefficients, we also estimated the choice probability of each management goal (i.e., the ratio of each attribute chosen as the best among the four attributes; see Appendix S1, Equation 3). Given the different preferences between cat owners and non-owners (e.g., Mameno et al. Reference Mameno, Kubo and Suzuki2017), in addition to pooled sample estimation (Model 1), we also estimate the model by dividing it into subsamples of cat owners and non-owners (Models 2 and 3).

Sampling procedure

We posted an online survey in the form of a questionnaire from 17 to 28 November 2016. The survey targets were the nationwide registered prospective respondents of a survey company, which is considered to represent Japan’s general public. We recruited the respondents by considering age, gender and residence and received 1675 valid responses to the BWS questions. Some key characteristics of the different respondent groups are presented in Table 3. The socio-demographics of the respondents who were randomly assigned to Control, Ecology and Risk were approximately the same, and each group’s characteristics were similar to those of the entire sample population of respondents (analysis of variance test: F value = 0.784, p = 0.457; Table 3).

Table 3. Socio-demographic characteristics of respondents.

a Japanese census data refers to the 2020 Japanese census (https://www.e-stat.go.jp). Gender and academic background information from the Japanese census data include data from those aged >60 years.

Results

For the pooled sample (i.e., Model 1: adjusted R2 = 0.0500; Akaike information criterion per the number of observations (AIC/n) = 3.393), the MaxDiff model coefficients for the variables of biodiversity conservation, zoonotic diseases and cat welfare were estimated to be significantly lower than the sanitary environment variable (Fig. 1). The coefficient for biodiversity conservation was higher than that for the welfare of cats but lower than that for zoonotic diseases. Thus, on average, respondents’ preferences for the goal of cat management were as follows: sanitary environment > zoonotic diseases > biodiversity conservation > cats’ welfare (Fig. 1).

Fig. 1. Maximum difference model results of best–worst scaling for outdoor cat management goals. The average utility for each goal in each group is shown; that is, the utility for each goal in the Ecology and Risk groups was calculated by using the interaction term variables of each goal and information about Ecology and Risk, respectively. The error bars represents standard errors. CI = confidence interval.

The ecological framing positively impacted preferences for biodiversity conservation and the prevention of zoonotic diseases but negatively impacted preferences for the improvement of cats’ welfare, although the coefficient for the improvement of cats’ welfare was not statistically significant (Table 4). Conversely, the interaction term variables for each alternative and the messages regarding the risk to cats in outdoor environments did not have a statistically significant impact.

Table 4. Estimated results using the conditional logit model. The numbers of respondents (and observations) are 1675 (6700) in Model 1, 544 (2176) in Model 2 and 1131 (4524) in Model 3.

*p < 0.05, **p < 0.01, ***p < 0.001.

The choice probabilities for each management goal demonstrated that the maintenance of a sanitary environment was the most frequently chosen attribute, with c. 39% of respondents selecting it in the Control group (Fig. 2). Conversely, the rate of selection of the biodiversity conservation attribute significantly increased from 20% to 26% with the ecological message framing.

Fig. 2. Rates of choice amongst the four outdoor cat management goals in each group.

Furthermore, Model 2 (adjusted R2 = 0.0169; AIC/n = 3.522) shows that cat owners’ preferences differed from those of the pooled sample and non-owners (Fig. 1). In addition, ecological framing significantly impacted cat owners’ preferences for all goals and risk framing also positively impacted their opinions regarding zoonotic diseases (Table 4). Thus, in the Control and Risk groups, cat owners’ order of choice probabilities for the cat management goal was as follows: sanitary environment > cats’ welfare > biodiversity conservation > zoonotic diseases. Alternatively, in the Ecology group, the order of cat owners’ choice probabilities was sanitary environment > biodiversity conservation = zoonotic disease > cats’ welfare (Fig. 2).

Conversely, concerning the results of the non-owners (i.e., Model 3: adjusted R2 = 0.0881; AIC/n = 3.253), the trend in results was similar to that of the pooled sample (Fig. 1). Ecological framing impacted preferences positively only for biodiversity conservation, and risk framing had no statistically significant impacts on the preferences for all of the goals (Table 4).

Discussion

The messages framing the ecological impacts of outdoor cats affected respondents’ preferences (Table 4). Whether cat owners or not, the respondents in the Ecology group evaluated conservation biodiversity as a more appropriate goal, and the selection of the biodiversity conservation attribute increased by c. 6% (cat owners: 5.8%; non-owners: 6.7%) with the ecological message framing (Fig. 2). Interestingly, the results indicate that ecological message framing has the potential to change the ranking of cat management goals for cat owners. Biodiversity conservation had the second-highest choice probability in the Ecology group. This result is contrary to previous studies suggesting that cat owners tend not to change their attitudes with an ecological framing (e.g., MacDonald et al. Reference MacDonald, Milfont and Gavin2015), which could be attributed to the fact that outdoor cats have recently been recognized as a reason for biodiversity loss in Japan. However, the results are consistent with previous studies that uncovered the positive impacts of the ecological framing on respondents’ preferences regarding invasive species management (Marzano et al. Reference Marzano, Dandy, Bayliss, Porth and Potter2015, McLeod et al. Reference McLeod, Hine, Bengsen and Driver2017, Mameno et al. Reference Mameno, Kubo, Shoji and Tsuge2020, Walsh Reference Walsh2021). Our results indicate that conservation-orientated information significantly increases citizens’ concerns regarding outdoor cat threats to biodiversity.

Table 4 presents another interesting effect of ecological framing. Regarding the results for cat owners, their preference for improved cat welfare significantly dropped by as much as 11% with an ecological framing, although it is noted that the results for the coefficients of each variable are not independent (Fig. 2). Therefore, our study suggests that ecological message framing, especially towards cat owners, should be implemented with care regarding the dimension of animal welfare (MacDonald et al. Reference MacDonald, Milfont and Gavin2015, Glen & Hoshino Reference Glen and Hoshino2020), although such framing is potentially a powerful tool to encourage public awareness of conservation (Vane & Runhaar Reference Vane and Runhaar2016, Mameno et al. Reference Mameno, Kubo, Shoji and Tsuge2020).

On average, the risk framing concerning cats’ welfare outdoors has little effect on respondents’ preferences (Table 4). However, the risk framing has different impacts on the preferences for management goals between cat owners and non-owners. Regarding the results for cat owners, the prevention of zoonotic diseases is positively affected by the risk framing; conversely, the risk framing negatively affects non-owners’ preferences for biodiversity conservation. This indicates that the results of message framing can depend on the targets of the message framing, suggesting that risk framing towards non-owners could unintentionally reduce biodiversity concerns. Therefore, our findings support those of previous studies that indicate the importance of an appropriate targeting strategy (Kusmanoff et al. Reference Kusmanoff, Fidler, Gordon, Garrard and Bekessy2020, Walsh Reference Walsh2021).

Surprisingly, risk framing had little effect on the preferences for the cat welfare enhancement goal (Table 4). These results are probably related to Japan’s unique culture: Japanese people may have already held social norms and beliefs that the outdoors are unsuitable for a cat. In particular, cat owners may recognize the outside as dangerous for cats without any additional information, as the cat welfare enhancement goal represents the second-highest choice probability in the Control group. Therefore, their preferences for the cat welfare goal might not be impacted by information regarding the inherent risks of the outdoor environment. Hall et al. (Reference Hall, Adams, Bradley, Bryant, Davis and Dickman2016) showed that cat owners who keep their cats indoors consider this to be ‘good manners’ in Japan. Furthermore, Japanese people often enjoy directly interacting with cats inside cat cafés; therefore, they enjoy them in indoor spaces.

This study has several limitations. First, it excludes the impacts of invasive species on some industries, such as agriculture and fisheries. Serious impacts of invasive species have been reported in some industries (Lovell et al. Reference Lovell, Stone and Fernandez2006, Zhao et al. Reference Zhao, Wahl and Marsh2006, Paini et al. Reference Paini, Sheppard, Cook, De Barro, Worner and Thomas2016). Our survey design also had some limitations. For example, because of it being an online experimental survey, our sample only included Internet users. Regarding message framing, we could not implement a pre-test, although the provided information was selected based on an Internet and literature review regarding government and public concerns about cats. Therefore, for effective management without conservation conflicts, further research should address the knowledge gaps that remain, including the impacts of other factors, such as social norms (Walsh Reference Walsh2021).

Our study carries management and/or policy implications. Approximately 35–40% of respondents prefer the maintenance of a sanitary environment as the most important goal for outdoor cat management without any message framing; conversely, only 20% of respondents chose biodiversity conservation as the most important goal (Fig. 2). These findings indicate that environmental managers could implement cat management with relative ease when highlighting the maintenance of sanitary environment goals rather than biodiversity conservation; this is because sanitation is of greatest concern for Japanese citizens, and through this managers can easily build consensus on outdoor cat management. However, it should be noted that highlighting the maintenance of sanitary environmental goals may not lead to the eradication of outdoor cats because management can be implemented only when damage to the sanitary environment reaches an unacceptable level (e.g., agricultural damage; Ikeda et al. Reference Ikeda, Asano, Matoba and Abe2004, Suzuki & Ikeda Reference Suzuki and Ikeda2019). Thus, it is necessary to gradually shift management goals and public support towards broader social and natural resource management with stakeholders, such as biodiversity conservation (Lowe et al. Reference Lowe, Browne, Boudjelas and De Poorter2000) and cat welfare enhancement (Seo et al. Reference Seo, Ueda and Tanida2021). Although it is assumed to be difficult for most citizens to accept biodiversity conservation goals in the current situation (i.e., only 20% of the respondents are in agreement with these goals), communication using ecological message framing can significantly increase public support for biodiversity conservation from both cat owners and non-owners, a goal that would require the eradication of all outdoor cats.

Our findings also highlight the challenges of managing outdoor cats due to them being pets with charismatic characteristics (Jarić et al. Reference Jarić, Courchamp, Correia, Crowley, Essl and Fischer2020). Our findings point to citizens’ desire to address problems that are more closely related to themselves, which is similar to the ‘not-in-my-backyard’ phenomenon, such as the problems caused by large carnivores (e.g., Kubo & Shoji Reference Kubo and Shoji2014). Even if cat owners were given risk framing, they were still most concerned about the sanitary environment (Fig. 1). However, a previous study indicated that local residents, especially cat owners, prefer for outdoor cats to live in their neighbourhoods, as they provide a feeling of comfort to local residents (Mameno et al. Reference Mameno, Kubo and Suzuki2017). Thus, people expect outdoor cat issues to be appropriately managed in their neighbourhoods, all while living with nearby outdoor cats. This highlights the paradoxical problem of outdoor cat management.

This study also contributes to the methodological development of social conservation science. Our results demonstrate that the BWS technique can contribute to our understanding of the social prioritization of biodiversity-related issues, which has recently been instrumental for effective conservation with limited human and financial resources (Wilson et al. Reference Wilson, McBride, Bode and Possingham2006, Beger et al. Reference Beger, McGowan, Treml, Green, White and Wolff2015). We present clear differences in citizens’ evaluations of management goals by applying the BWS technique (Fig. 1). Regarding non-owners, there was a particularly large difference amongst the alternatives that closely involve human lives (e.g., sanitary environments and zoonotic diseases) and the other alternatives, such as biodiversity conservation and animal welfare enhancement. The BWS findings can be applied to the management of other invasive species that pose risks to human health, such as mongooses, raccoons and fire ants. For example, the eradication of the mongoose is required in order to achieve biodiversity conservation at a natural World Heritage site in Japan. In this case, messages regarding human health benefits could contribute to enhancing public support for mongoose management because mongooses have a negative impact on biodiversity as well as human health (Shiokawa et al. Reference Shiokawa, Llanes, Hindoyan, Cruz-Martinez, Welcome and Rajeev2019). Alternatively, cat owners are more concerned about cat welfare than biodiversity and zoonotic diseases; as such, these results also indicate that the BWS technique clearly demonstrates varying preferences between cat owners and non-owners. In other words, the BWS technique was able to clarify the need for communication strategies tailored to each target. This implies that further studies using the research framework and methods that this study applied could lead to greater understating of these differences and improve the efficiency of outdoor cat management around the world. Cat management and public perceptions of outdoor cats vary between countries, meaning that tailor-made policymaking might be required in each country. Managing cats’ urination and defaecation, for example, is not an evident concern in the UK (Crowley et al. Reference Crowley, Cecchetti and McDonald2019), and disease-related risks tend to be of less concern than the risks to biodiversity in the USA (Gramza et al. Reference Gramza, Teel, VandeWoude and Crooks2016). In New Zealand, cat owners are more concerned about feral cat issues regarding biodiversity conservation and diseases to humans than those relating to feral cats being a nuisance to humans (Bassett et al. Reference Bassett, McNaughton, Plank and Stanley2020).

Conclusion

We highlight the importance of carefully developing strategic message framing concerning invasive species management in order to win public support and minimize conflict (Kusmanoff et al. Reference Kusmanoff, Fidler, Gordon, Garrard and Bekessy2020, Wald & Peterson Reference Wald and Peterson2020, Walsh Reference Walsh2021). The findings support evidence from Belgium and Israel that the development of strategic communications towards each target is required to achieve effective outdoor cat management (Finkler & Terkel Reference Finkler and Terkel2012, Ruyver et al. Reference Ruyver, Abatih, Villa, Peeters, Clements, Dufau and Moons2021). Our results show that ecological message framing can potentially contribute to increasing public support for biodiversity conservation-related aspects of outdoor cat management from both cat owners and non-owners. This study also demonstrates that the BWS technique can contribute to social conservation science by revealing clear differences in citizens’ preferences for multiple cat management goals. We believe that our study contributes to improving efficient invasive species management with limited budgets and human resources.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S0376892922000108.

Acknowledgements

We thank Professor K Kuriyama for supporting our survey and Professor F Nakamura, Professor H Kakizawa and Associate Professor T Aikoh for their helpful comments. We also express our gratitude for the helpful comments of the editors and anonymous reviewers on the early drafts of this manuscript.

Author contributions

KM: conceptualization (equal); data curation (lead); formal analysis (lead); investigation (equal); methodology (equal); visualization (lead); funding acquisition (supporting); writing – original draft (lead); TK: conceptualization (equal); investigation (equal); methodology (supporting); project administration (supporting); supervision (supporting); funding acquisition (supporting); writing – review and editing (lead). TS: conceptualization (equal); formal analysis (supporting); funding acquisition (supporting); writing – original draft (supporting). TT: investigation (equal); formal analysis (supporting); methodology (equal); resources (equal); writing – review and editing (supporting). YS: conceptualization (supporting), funding acquisition (lead), investigation (equal), methodology (equal), project administration (lead), supervision (lead), writing – review and editing (supporting).

Financial support

KM gratefully acknowledges the financial support received from the SOMPO Environment Foundation (Grant Program for Doctoral Course Students). This work was financially supported by the Environmental Economics and Policy Study, Ministry of the Environment, Japan (research on economic evaluation of natural and environmental policy in Japan) and the Japan Society for the Promotion of Science (JSPS KAKENHI grant numbers 15H02867 and 20K12311).

Conflict of interest

The authors declare that they have no known competing financial interests or personal relationships that could have influenced the work reported in this study.

Ethical standards

None.

References

Andiappan, H, Nissapatorn, V, Sawangjaroen, N, Khaing, SL, Salibay, CC, Cheung, MMM et al. (2014) Knowledge and practice on Toxoplasma infection in pregnant women from Malaysia, Philippines, and Thailand. Frontiers in Microbiology 5: 291.CrossRefGoogle ScholarPubMed
Barker, SB, Wolen, AR (2008) The benefits of human–companion animal interaction: a review. Journal of Veterinary Medical Education 35: 487495.CrossRefGoogle ScholarPubMed
Bassett, IE, McNaughton, EJ, Plank, GD, Stanley, MC (2020) Cat ownership and proximity to significant ecological areas influence attitudes towards cat impacts and management practices. Environmental Management 66: 3041.CrossRefGoogle ScholarPubMed
Beger, M, McGowan, J, Treml, EA, Green, AL, White, AT, Wolff, NH et al. (2015) Integrating regional conservation priorities for multiple objectives into national policy. Nature Communications 6: 8208.CrossRefGoogle ScholarPubMed
Crowley, SL, Cecchetti, M, McDonald, RA (2019) Hunting behaviour in domestic cats: an exploratory study of risk and responsibility among cat owners. People and Nature 1: 1830.CrossRefGoogle Scholar
Crowley, SL, Hinchliffe, S, McDonald, RA (2017) Conflict in invasive species management. Frontiers in Ecology and the Environment 15: 133141.CrossRefGoogle Scholar
Druckman, JN (2001) The implications of framing effects for citizen competence. Political Behavior 23: 225256.CrossRefGoogle Scholar
Entman, RM (1993) Framing: toward clarification of a fractured paradigm. Journal of Communication 43: 5158.CrossRefGoogle Scholar
Estévez, RA, Anderson, CB, Pizarro, JC, Burgman, MA (2015) Clarifying values, risk perceptions, and attitudes to resolve or avoid social conflicts in invasive species management. Conservation Biology 29: 1930.CrossRefGoogle ScholarPubMed
Fernández-Llamazares, Á, Cabeza, M (2018) Rediscovering the potential of Indigenous storytelling for conservation practice. Conservation Letters 11: e12398.CrossRefGoogle Scholar
Finkler, H, Terkel, J (2012) The contribution of cat owners’ attitudes and behaviours to the free-roaming cat overpopulation in Tel Aviv, Israel. Preventive Veterinary Medicine 104: 125135.CrossRefGoogle Scholar
Finn, A, Louviere, JJ (1992) Determining the appropriate response to evidence of public concern: the case of food safety. Journal of Public Policy & Marketing 11: 1225.CrossRefGoogle Scholar
Glen, AS, Hoshino, K (2020) Social and logistical challenges in managing invasive predators: insights from islands in Japan and New Zealand. Pacific Conservation Biology 26: 344352.CrossRefGoogle Scholar
Gramza, A, Teel, T, VandeWoude, S, Crooks, K (2016) Understanding public perceptions of risk regarding outdoor pet cats to inform conservation action. Conservation Biology 30: 276286.CrossRefGoogle ScholarPubMed
Halfmann, PJ, Hatta, M, Chiba, S, Maemura, T, Fan, S, Takeda, M et al. (2020) Transmission of SARS-CoV-2 in domestic cats. New England Journal of Medicine 383: 592594.CrossRefGoogle ScholarPubMed
Hall, CM, Adams, NA, Bradley, JS, Bryant, KA, Davis, AA, Dickman, CR et al. (2016) Community attitudes and practices of urban residents regarding predation by pet cats on wildlife: an international comparison. PLoS ONE 11: e0151962.CrossRefGoogle Scholar
Hanley, N, Roberts, M (2019) The economic benefits of invasive species management. People and Nature 1: 124137.CrossRefGoogle Scholar
Ikeda, T, Asano, M, Matoba, Y, Abe, G (2004) Present status of invasive alien raccoon and its impact in Japan. Global Environmental Research 8: 125131.Google Scholar
Jarić, I, Courchamp, F, Correia, RA, Crowley, SL, Essl, F, Fischer, A et al. (2020) The role of species charisma in biological invasions. Frontiers in Ecology and the Environment 18: 345353.CrossRefGoogle Scholar
Kubo, T, Shoji, Y (2014) Spatial tradeoffs between residents’ preferences for brown bear conservation and the mitigation of human–bear conflicts. Biological Conservation 176: 126132.CrossRefGoogle Scholar
Kubo, T, Tsuge, T, Abe, H, Yamano, H (2018) Understanding island residents’ anxiety about impacts caused by climate change using best–worst scaling: a case study of Amami islands, Japan. Sustainability Science 14: 131138.CrossRefGoogle Scholar
Kusmanoff, AM, Fidler, F, Gordon, A, Garrard, GE, Bekessy, SA (2020) Five lessons to guide more effective biodiversity conservation message framing. Conservation Biology 34: 11311141.CrossRefGoogle ScholarPubMed
Lauber, BT, Knuth, BA, Tantillo, JA, Curtis, PD (2007) The role of ethical judgments related to wildlife fertility control. Society & Natural Resources 20: 119133.CrossRefGoogle Scholar
Lepczyk, CA, Mertig, AG, Liu, J (2004) Landowners and cat predation across rural-to-urban landscapes. Biological Conservation 115: 191201.CrossRefGoogle Scholar
Levy, JK, Crawford, PC (2004) Humane strategies for controlling feral cat populations. Journal of the American Veterinary Medical Association 225: 13541360.CrossRefGoogle ScholarPubMed
Lewis, CL, Granek, EF, Nielsen-Pincus, M (2019) Assessing local attitudes and perceptions of non-native species to inform management of novel ecosystems. Biological Invasions 21: 961982.CrossRefGoogle Scholar
Louviere, JJ, Flynn, TN, Marley, AAJ (2015) Best–Worst Scaling: Theory, Methods and Applications. Cambridge, UK: Cambridge University Press.CrossRefGoogle Scholar
Louviere, JJ, Lings, I, Islam, T, Gudergan, S, Flynn, T (2013) An introduction to the application of (case 1) best–worst scaling in marketing research. International Journal of Research in Marketing 30: 292303.CrossRefGoogle Scholar
Lovell, SJ, Stone, SF, Fernandez, L (2006) The economic impacts of aquatic invasive species: a review of the literature. Agricultural and Resource Economics Review 35: 195208.CrossRefGoogle Scholar
Lowe, S, Browne, M, Boudjelas, S, De Poorter, M (2000) 100 of the World’s Worst Invasive Alien Species: A Selection from the Global Invasive Species Database (Vol. 12). Auckland, New Zealand: Invasive Species Specialist Group.Google Scholar
Loyd, KAT, Hernandez, SM, Abernathy, KJ, Shock, BC, Marshall, GJ (2013) Risk behaviours exhibited by free-roaming cats in a suburban US town. Veterinary Record 173: 295.CrossRefGoogle Scholar
MacDonald, E, Milfont, T, Gavin, M (2015) What drives cat-owner behaviour? First steps towards limiting domestic-cat impacts on native wildlife. Wildlife Research 42: 257265.CrossRefGoogle Scholar
Mameno, K, Kubo, T (2021) Tourist intentions to donate to non-lethal feral cat management at a potential natural World Heritage site in Japan. Human Dimensions of Wildlife 26: 99114.CrossRefGoogle Scholar
Mameno, K, Kubo, T, Shoji, Y, Tsuge, T (2020) How to engage tourists in invasive carp removal: Application of a discrete choice model. In: Managing Socio-ecological Production Landscapes and Seascapes for Sustainable Communities in Asia: Mapping and Navigating Stakeholders, Policy and Action (eds O Saito, SM Subramanian, S Hashimoto, K Takeuchi), pp. 31–44. Singapore: Springer Singapore.CrossRefGoogle Scholar
Mameno, K, Kubo, T, Suzuki, M (2017) Social challenges of spatial planning for outdoor cat management in Amami Oshima Island, Japan. Global Ecology and Conservation 10: 184193.CrossRefGoogle Scholar
Marzano, M, Dandy, N, Bayliss, HR, Porth, E, Potter, C (2015) Part of the solution? Stakeholder awareness, information and engagement in tree health issues. Biological Invasions 17: 19611977.CrossRefGoogle Scholar
McLeod, LJ, Hine, DW, Bengsen, AJ, Driver, AB (2017) Assessing the impact of different persuasive messages on the intentions and behaviour of cat owners: a randomised control trial. Preventive Veterinary Medicine 146: 136142.CrossRefGoogle ScholarPubMed
McNeely, JA (2001) The Great Reshuffling. Human Dimensions of Invasive Alien Species. Gland, Switzerland, and Cambridge, UK: IUCN.Google Scholar
McNeely, JA, Mooney, HA, Neville, LE, Schei, PJ, Waage, JK (2001) A Global Strategy on Invasive Alien Species. Gland, Switzerland, and Cambridge, UK: IUCN.Google Scholar
Ministry of the Environment (2018) Management plan for feral cat management in Amami Ōshima Islands [in Japanese; www document]. URL https://www.env.go.jp/nature/kisyo/amami_nonekomp.pdf Google Scholar
Ministry of the Environment (2020) Results in public comments for feral cat management plan in Amami Ōshima Islands [in Japanese; www docuement]. URL https://www.env.go.jp/info/iken/index.html Google Scholar
Mitsui, S, Kubo, T, Yoshida, M (2018) Analyzing the change in long-term information provision on cat management around a world natural heritage site. European Journal of Wildlife Research 64: 9.CrossRefGoogle Scholar
Myers, TA, Nisbet, MC, Maibach, EW, Leiserowitz, AA (2012) A public health frame arouses hopeful emotions about climate change. Climatic Change 113: 11051112.CrossRefGoogle Scholar
Paini, DR, Sheppard, AW, Cook, DC, De Barro, PJ, Worner, SP, Thomas, MB (2016) Global threat to agriculture from invasive species. Proceedings of the National Academy of Sciences of the United States of America 113: 75757579.CrossRefGoogle ScholarPubMed
Perry, DAN, Perry, GAD (2008) Improving interactions between animal rights groups and conservation biologists. Conservation Biology 22: 2735.CrossRefGoogle ScholarPubMed
Raghavarao, D, Padgett, LV (2005) Block Designs: Analysis, Combinatorics, and Applications (Vol. 17). Hackensack, NJ, USA: World Scientific.CrossRefGoogle Scholar
Reddy, SMW, Wardropper, C, Weigel, C, Masuda, YJ, Harden, S, Ranjan, P et al. (2020) Conservation behavior and effects of economic and environmental message frames. Conservation Letters 13: e12750.CrossRefGoogle Scholar
Rhee, JW (1997) Strategy and issue frames in election campaign coverage: a social cognitive account of framing effects. Journal of Communication 47: 2648.CrossRefGoogle Scholar
Roberts, M, Cresswell, W, Hanley, N (2018) Prioritising invasive species control actions: evaluating effectiveness, costs, willingness to pay and social acceptance. Ecological Economics 152: 18.CrossRefGoogle Scholar
Ruyver, DC, Abatih, E, Villa, PD, Peeters, EH, Clements, J, Dufau, A, Moons, CP (2021) Public opinions on seven different stray cat population management scenarios in Flanders, Belgium. Research in Veterinary Science 136: 209219.CrossRefGoogle ScholarPubMed
Seo, A, Ueda, Y, Tanida, H (2021) Health status of ‘community cats’ living in the tourist area of the old town in Onomichi City, Japan. Journal of Applied Animal Welfare Science (epub ahead of print) DOI: 10.1080/10888705.2021.1874952.CrossRefGoogle Scholar
Shackleton, RT, Adriaens, T, Brundu, G, Dehnen-Schmutz, K, Estévez, RA, Fried, J et al. (2019) Stakeholder engagement in the study and management of invasive alien species. Journal of Environmental Management 229: 88101.CrossRefGoogle Scholar
Shannon, C, Quinn, CH, Sutcliffe, C, Stebbing, PD, Dally, T, Glover, A, Dunn, AM (2019) Exploring knowledge, perception of risk and biosecurity practices among researchers in the UK: a quantitative survey. Biological Invasions 21: 303314.CrossRefGoogle Scholar
Shiokawa, K, Llanes, A, Hindoyan, A, Cruz-Martinez, L, Welcome, S, Rajeev, S (2019) Peridomestic small Indian mongoose: an invasive species posing as potential zoonotic risk for leptospirosis in the Caribbean. Acta Tropica 190: 166170.CrossRefGoogle ScholarPubMed
Shoji, Y, Kim, H, Kubo, T, Tsuge, T, Aikoh, T, Kuriyama, K (2021) Understanding preferences for pricing policies in Japan’s national parks using the best–worst scaling method. Journal for Nature Conservation 60: 125954.CrossRefGoogle Scholar
Suzuki, T, Ikeda, T (2019) Challenges in managing invasive raccoons in Japan. Wildlife Research 46: 476483.CrossRefGoogle Scholar
Toukhsati, SR, Phillips, CJC, Podberscek, AL, Coleman, GJ (2012) Semi-ownership and sterilisation of cats and dogs in Thailand. Animals 2: 611627.CrossRefGoogle ScholarPubMed
Tsuge, T, Nakamura, S, Usio, N (2014) Assessing the difficulty of implementing wildlife-friendly farming practices by using the best–worst scaling approach. In: Social-Ecological Restoration in Paddy-Dominated Landscapes (eds Usio, N, Miyashita, T), pp. 223236. Tokyo, Japan: Springer Japan.CrossRefGoogle Scholar
Tyner, EH, Boyer, TA (2020) Applying best–worst scaling to rank ecosystem and economic benefits of restoration and conservation in the Great Lakes. Journal of Environmental Management 255: 109888.CrossRefGoogle ScholarPubMed
United Nations (1992) Conference on Environment and Development: Convention on Biological Diversity. International Legal Materials 31: 818841.CrossRefGoogle Scholar
Vane, M, Runhaar, HAC (2016) Public support for invasive alien species eradication programs: insights from The Netherlands. Restoration Ecology 24: 743748.CrossRefGoogle Scholar
Wald, D, Peterson, A (2020) Cats and Conservationists: The Debate over Who Owns the Outdoors. West Lafayette, IN, USA: Purdue University Press.CrossRefGoogle Scholar
Walsh, PJ (2021) Behavioural approaches and conservation messages with New Zealand’s threatened kiwi. Global Ecology and Conservation 28: e01694.CrossRefGoogle Scholar
Wilson, KA, McBride, MF, Bode, M, Possingham, HP (2006) Prioritizing global conservation efforts. Nature 440: 337340 CrossRefGoogle ScholarPubMed
Zhao, Z, Wahl, TI, Marsh, TL (2006) Invasive species management: foot-and-mouth disease in the U.S. beef industry. Agricultural and Resource Economics Review 35: 98115.CrossRefGoogle Scholar
Figure 0

Table 1. Conversion from a balanced incomplete block design (BIBD) to the choice sets. Note: ‘A’ appears in three choice sets on the left side of the table (the first, third and fourth choice set). In these three choice sets, ‘A’ is compared two times each against each of the other goals (i.e., ‘B’, ‘C’ and ‘D’).

Figure 1

Table 2. Information that was provided to each group.

Figure 2

Table 3. Socio-demographic characteristics of respondents.

Figure 3

Fig. 1. Maximum difference model results of best–worst scaling for outdoor cat management goals. The average utility for each goal in each group is shown; that is, the utility for each goal in the Ecology and Risk groups was calculated by using the interaction term variables of each goal and information about Ecology and Risk, respectively. The error bars represents standard errors. CI = confidence interval.

Figure 4

Table 4. Estimated results using the conditional logit model. The numbers of respondents (and observations) are 1675 (6700) in Model 1, 544 (2176) in Model 2 and 1131 (4524) in Model 3.

Figure 5

Fig. 2. Rates of choice amongst the four outdoor cat management goals in each group.

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