Survey instrument

We developed an online survey collaboratively with the Center for Survey Statistics and Methodology (CSSM) at Iowa State University to collect information about U.S. pork consumers. Dynata, an international marketing company, programmed the survey instrument into a web-based format and distributed it through their database of survey panelists.Footnote ⁴ The survey sample was balanced for age, gender, race, income, and region of the United States according to the U.S. Census.Footnote ⁵ A screening question was included at the beginning of the survey to identify pork consumers. A household that does not eat pork was not included in the sample. In total, 2,107 completed responses were obtained from April 29, 2020 to May 4, 2020. Among total respondents to the survey, 1,052 participants were randomly assigned to the survey experiment designed for this study. Table 1 shows select summary statistics of survey participants compared with 2020 U.S. Census data where available. About 46% of respondents were female, mean age was 46 years with a range of 18 to 93 years, and 28% of respondents had a bachelor’s degree or higher. Annual household income was classified into five categories, and residence into four categories for region of the United States. Half of respondents eat pork at home more than once a week and selected pork chops as a pork product that they typically buy.

Table 1. Summary statistics of survey participants

Prior knowledge of ASF

To our knowledge, there is little published evidence on consumer awareness and perceptions of ASF or other swine diseases. The first part of the survey consisted of questions that evaluated how much pork consumers know about various swine diseases. Specifically, three questions allowed us to infer the degree to which consumers were aware of ASF. The first question asked how much they were aware of various swine diseases, using a Likert scale. Swine diseases included swine influenza, porcine epidemic diarrhea (PED), porcine reproductive and respiratory syndrome (PRRS), ASF, classical swine fever (CSF), and FMD. Common causes of foodborne illness, such as E. coli and salmonella, were also included in the list. To account for possible order bias, we provided swine diseases in a randomized order to survey participants. Using the same list of swine diseases, the second question asked respondents to indicate which diseases, if any, they thought were a possible threat to human health. Lastly, we asked whether respondents were aware of the global ASF outbreak in China and other countries.

The observed responses to these three survey questions were used to understand consumers’ prior knowledge about ASF. It is likely that there exist latent or hidden patterns between answers to the questions, as respondents with similar answers will tend to cluster within the same latent class. Latent class analysis allows us to identify qualitatively different subgroups within populations that share certain observable characteristics (Hagenaars and McCutcheon Reference Hagenaars and McCutcheon2002). This helps us evaluate the relationship between the observable survey responses and choose a proxy for the respondent’s prior knowledge of ASF. We find that an individual’s awareness of the global ASF outbreak was a key response that determines to which latent class a respondent likely belongs and the variable is used to represent consumers’ prior knowledge of ASF. To help retain brevity of the article, Table 2 contains only the survey responses that present respondents’ prior knowledge of ASF, which are selected for use in model estimation. Appendix 1 contains details of the survey responses about relative awareness of ASF along with prior knowledge of other swine diseases and the results from the latent class analysis.

Table 2. Awareness of global ASF outbreak and perceived impact of ASF on human health

The August 2018 outbreak of ASF in China and subsequent outbreaks in other countries has dramatically changed the global epidemiological conditions of ASF and has caused concerns the disease may continue to spread into disease-free regions, including the United States (Sundberg Reference Sundberg2019). Only 27% of respondents were aware of this situation when the survey was conducted in the spring of 2020. The cross tabulation for respondents’ awareness of the recent global outbreak of ASF and their belief that ASF is not a threat to human health, shown in Table 2, indicates that only 16% of respondents were aware of ASF and believed it was not a threat to human health. This is an extremely noteworthy finding, as some consumers have strong beliefs to the contrary despite considerable efforts by several government agencies (OIE 2021a; FAO-EMPRES-AH 2021b; USDA-APHIS 2021a) and others (Pork Checkoff 2021; SPS Plan 2021) to publicize that FMD, CSF, and ASF are not public health or food safety concerns and that pork will still be safe to eat in the event of a disease outbreak.

Experimental design: Information treatments

We designed a survey experiment to assess how news reporting and the degree of information exposure about an unfamiliar animal disease outbreak can affect pork purchases. The hypothetical situation is impossible to test in a real-world setting. Without a controlled environment, it is also difficult to ensure that consumers are actually exposed to specific news items or messages. The benefit of the stated preference methodology is that we can directly compare the effect of media coverage and food safety information on consumers’ behavioral changes in pork purchases during a hypothetical outbreak of ASF while accounting for respondents’ prior knowledge.

When an ASF outbreak occurs, depending on how the outbreak is reported, some consumers may only be informed of the occurrence of the outbreak, while some consumers may learn more about the disease. Even if sensational headlines are avoided, a negative framing in the headlines can have a cognitive effect on consumers’ perceptions, resulting in them avoiding the consumption of pork. According to Ecker et al. (Reference Ecker, Lewandowsky, Chang and Pillai.2014), the information presented in news articles can be misleading without being blatantly false. They define slightly misleading headlines as those focusing on one negative aspect of the issue rather than the article’s main issue. Moreover, consumers may seek further assurances that eating pork is safe. Ortega, Wang and Olynk Widmar (Reference Ortega, Wang and Olynk Widmar2015) find that news headlines regarding food safety have a significant impact on U.S. consumer preferences and willingness to pay for enhanced safety characteristics.

The news article format in our experiment, reporting the first occurrence of ASF in the United States, serves as the information treatment. We specified in the instructions as follows:

To eliminate the source of bias in treatments, each respondent was randomly assigned to one of four treatments or a control group. A control group received no headline or corresponding news article content. Four treatment groups received news articles, and we used a two-by-two factorial design to compare the relative effects of the combinations of two types of content and two types of headlines.

For the body of the news article, we prepared two different paragraphs of approximately 200 words each. General information about ASF was included, and it was explicitly stated that ASF was not a potential threat to human health. The difference between the two contents was that we included additional food safety assurance messaging in one, but not the other.

We considered two possible headlines that may be used when reporting on an ASF outbreak. One headline may be focused on food safety, stating it is “still safe to eat pork.” The other headline may state that “no vaccine is available” but does not specify to whom the vaccine was unavailable, and also does not have a direct statement about food safety. The latter headline is slightly misleading because it emphasizes one negative aspect rather than the dominant point of the accompanying content about the nonimpact on human health. Table 3 presents a summary of the experimental design based on a mix-and-match of two news article contents and two headlines. Instructions, headlines, and the news articles provided for the contingent valuation experiment are provided in Appendix 2.

Table 3. Design of Information Treatments (N = 1,052)

Double-bounded dichotomous contingent valuation methodology with a follow-up question

We used the double-bounded contingent valuation methodology (Hanemann, Loomis and Kanninen Reference Hanemann, Loomis and Kanninen1991) in the survey to determine how willingness to pay for pork chops differ by exposure to different information treatments. Boneless pork chops were used for the study because they are a familiar cut of fresh pork (USDA-AMS 2020; US-BLS 2020) and have been frequently utilized in previous studies (Sanders, Moon and Kuethe Reference Sanders, Moon and Kuethe2007; Olynk, Tonsor and Wolf Reference Olynk, Tonsor and Wolf2010; Pozo, Tonsor and Schroeder Reference Pozo, Tonsor and Schroeder2012; Lusk et al. Reference Lusk, Tonsor, Schroeder and Hayes2018). Moreover, possible changes in purchase intentions and consumer behavior are highly correlated when asking consumers about their purchases of existing products (Morwitz, Steckel and Gupta Reference Morwitz, Steckel and Gupta2007).

We provided survey participants with the average retail price of $3.35 per pound for boneless pork chops, which was based on the National Retail Report – Pork, published by USDA’s Agricultural Marketing Service, for the third week of February 2020 (USDA-AMS 2020).Footnote ⁶ The price served as a representative, prevailing price for normal market conditions. Then, we asked each respondent if they would buy a boneless pork chop for a lower price ( ${B_i}$ ) per pound during an ASF outbreak in the United States. If a participant answered “yes” to the first question, the price was raised by $0.50 ( $B_i^h = {B_i} + 0.5)\;$ and the question was asked again. If a participant answered “no” to the first question, the price was reduced by $0.50 ( $B_i^l = {B_i} - 0.5)$ and the question was asked again. We randomly assigned survey participants to three initial lower prices: $2.00, $2.35, and $2.70.

We used initial prices lower than the reference price of $3.35 per pound. This reflects the notion that countries with confirmed cases of ASF would be subject to international trade restrictions. As a result, an outbreak of ASF in the United States would lead to a significant reduction, if not complete halt, in U.S. pork exports. This would result in immediately larger supplies of pork in the domestic market, putting downward pressure on prices throughout the pork supply chain (Carriquiry et al. Reference Carriquiry, Elobeid, Swenson and Hayes2020).

The theoretical framework in Aizaki, Nakatani and Sato (Reference Aizaki, Nakatani and Sato.2014) is adapted for this study. We assume an individual’s indirect utility function is ${U_i}\left( {{q_i},{m_i}} \right)$ , where ${q_i}$ is the perceived food safety of a pork chop, and ${m_i}$ is the individual’s income. Suppose that an individual compares the perceived food safety of a pork chop in normal conditions ( ${q_{0i}})$ to the perceived food safety after hearing about an ASF outbreak in the United States ( ${q_{1i}})$ . Learning about an ASF outbreak may or may not change individuals’ perceptions of the safety of pork. If individuals think they will gain utility from purchasing pork chops at a proposed price, they would answer “yes” to the question, and we can write it as an equation:

(1) $$\;{U_i}\left( {{q_{1i}},{m_i} - {b_i}} \right) \ge \;{U_i}\left( {{q_{0i}},{m_i}} \right)$$

where ${B_i}$ is a price which is further assumed to be ${b_i} = 3.35 - {d_i}$ , and ${d_i}$ reflects the perceived discount in the value of the pork chop evaluated by individuals due to an ASF outbreak.

The responses to the double-bounded valuation questions can be partitioned into four intervals. For example, if a respondent answered “yes” to both valuation questions (“yes, yes”), then the respondent’s willingness to pay is considered higher than the last price, and the willingness to pay interval is classified as $\left[ {b_i^h, + \infty } \right)$ . An interval for a (“yes, no”) answer is $\left[ {{b_i},b_i^h} \right)$ , an interval for a (“no, yes”) answer is $\left[ {b_i^l,{b_i}} \right)$ , and an interval for a (“no, no”) answer is $\left( { - \infty ,b_i^l} \right)$ .

In this study, following the conventional design of double-bounded valuation questions, we added a question for respondents who answered “no” to the initial price and the following price with a value decreased by $0.50. Specifically, we asked “Would you buy a boneless pork chop for any price below the last suggested price?” This question allows us to further distinguish between consumers who have willingness to pay in the range of [ $b_i^l,\;0)$ or 0. Appendix 3 depicts schematically how we provided the double-bounded contingent valuation and follow-up questions.

Willingness-to-pay estimation: Double-bounded discrete choice contingent valuation model

We first estimate willingness to pay using the double-bounded discrete choice contingent valuation (DBDC-CV) methodology which assumes a logistic distribution to account for both positive and negative ranges for willingness to pay. We then compare willingness to pay estimated from the spike model (Kriström Reference Kriström1997; Yoo and Kwak Reference Yoo and Kwak2002), which utilizes the answers from the follow-up question and focuses on positive willingness-to-pay values and spikes at zero willingness to pay. While considering the market good characteristics of pork chops make it reasonable to focus on the positive willingness to pay values, Bass et al. (Reference Bass, McFadden and Messer2021) points out that a market good may not always provide marginal utility if consumers are concerned about food safety. Because consumer valuations reflect consumer sentiment, the spike model that restricts willingness to pay to only positive values may overestimate the effective demand. We examine the two willingness to pay distributions estimated from the DBDC-CV model and the spike model to determine if they are significantly different. By this comparison, it is possible to gain insight into the potential impact of negative willingness to pay, which is attributable to consumers’ disutility from the introduction of animal disease that is perceived to compromise food safety.

To estimate willingness to pay using DBDC-CV, we assume an individual’s indirect utility function ( ${U_i})$ has a systematic component ( ${V_i}$ ) and a random component ( ${\varepsilon _i}$ ), based on the random utility model. Therefore, equation (1) can be written as

(2) $${V_{1i}}\left( {{q_{1i}},{m_i} - {b_i}} \right) + {\varepsilon _{1i}} \ge \;{V_{0i}}\left( {{q_{0i}},{m_i}} \right) + {\varepsilon _{0i}}$$

We use the linear utility model ${V_i} = {\alpha _i} + {\beta _i}{m_i} + {\varepsilon _i}$ , where ${b_i}$ represents the marginal utility of income. An individual’s maximum latent willingness to pay in the hypothesized situation satisfies:

(3) $${\alpha _{0i}} + {\beta _i}{m_i} + {\varepsilon _{0i}} = {\alpha _{1i}} + {\beta _i}\left( {{m_i} - y_i^*} \right) + {\varepsilon _{1i}}$$

Rearranging the equation yields $y_i^*$ = ${{{\alpha _i} + {\varepsilon _i}} \over {{\beta _i}}}$ , where ${\alpha _i} = {\alpha _{1i}} - $ ${\alpha _{0i}}\;$ and ${\varepsilon _i} = {\varepsilon _{1i}} - $ ${\varepsilon _{0i}}.$ An individual would say “yes” to a price if the individual perceives that purchasing pork chops at the proposed price provides greater utility, such that ${V_{1i}} - {V_{0i}} = {\alpha _i} - {\beta _i}{b_i} + {\varepsilon _i} \ge 0$ . The error term ${\varepsilon _i}$ is a stochastic component with a standard logistic distribution.

The probability that individual i answers “yes, yes” to the first and second questions is given by ${P^{yy}}$ ( ${b_i},b_i^h) = Pr\;\left( {b_i^h \le y_i^*} \right)\; = 1 - F(b_i^h;\;{\alpha _i},$ ${\beta _i}$ ). Similarly, the probability of answering “yes, no” is ${P^{yn}}$ = $F\left( {b_i^h;{\alpha _i},\;{\beta _i}} \right) - F\left( {{b_i};{\alpha _i},\;{\beta _i}} \right)$ , and the probability of answering “no, yes” is ${P^{ny}}$ = F $\left( {{b_i};{\alpha _i},\;{\beta _i}} \right) - F\left( {b_i^l;{\alpha _i},\;{\beta _i}} \right)$ . Lastly, the probability of answering “no, no” is ${P^{nn}}$ ( ${b_i},b_i^h) = F(b_i^l;{\alpha _i},$ ${\beta _i}).\;$ Therefore, the log-likelihood for estimation can be specified as

(4) \begin{align}\ln L = \;\sum\nolimits_{i = 1}^N \; &\left\{ {\;\;D_i^{yy}ln\left[ {\;1 - F\left( {\;b_i^h;\;{\alpha _i},\;{\beta _i}} \right)} \right]} \right\}{\rm{ }}\\ & + D_i^{yn}\;ln\left[ {\;F\left( {b_i^h;{\alpha _i},\;{\beta _i}} \right) - F\left( {{b_i};{\alpha _i},\;{\beta _i}} \right)} \right]{\rm{ }}\\ & + D_i^{ny}\;ln\left[ {\;F\left( {{b_i};{\alpha _i},\;{\beta _i}} \right) - F\left( {b_i^l;{\alpha _i},\;{\beta _i}} \right)} \right]{\rm{ }}\\ & + D_i^{nn}\;ln\left[ {F\left( {b_i^l;{\alpha _i},\;{\beta _i}} \right)} \right]\}\end{align}

where $D_i^{yy},\;D_i^{yn},D_i^{ny},D_i^{nn}$ are indicator variables that have a value of 1 when the respondent answers “yes, yes,” “yes, no,” “no, yes,” or “no, no,”, respectively. ${\rm{F}}( \cdot )$ is defined as having a standard logistic distribution. Maximum likelihood is used to estimate the model.

Willingness-to-pay estimation: Spike model

The follow-up response added to the double-bounded contingent valuation question allows us to utilize the spike model, which provides smaller standard errors of the mean willingness to pay when a high proportion of respondents are expected to express an unwillingness to pay (Yoo and Kwak Reference Yoo and Kwak2002). The spike model assumes willingness to pay is distributed as logistic on the positive axis, with a spike at zero. Considering these aspects, the log likelihood for the estimation is further expanded as

(5) \begin{align}\ln L = \;\sum\nolimits_{i = 1}^N \; &\left\{ {\;\;D_i^{yy}ln\left[ {\;1 - F\left( {\;b_i^h;\;{\alpha _i},\;{\beta _i}} \right)} \right]} \right\}{\rm{ }}\\ & + D_i^{yn}\;ln\left[ {\;F\left( {b_i^h;{\alpha _i},\;{\beta _i}} \right) - F\left( {{b_i};{\alpha _i},\;{\beta _i}} \right)} \right]{\rm{ }}\\ & + D_i^{ny}\;ln\left[ {\;F\left( {{b_i};{\alpha _i},\;{\beta _i}} \right) - F\left( {b_i^l;{\alpha _i},\;{\beta _i}} \right)} \right]{\rm{ }}\\ & + D_i^{nny}\;ln\left[ {\;F\left( {b_i^l;{\alpha _i},\;{\beta _i}} \right) - F\left( {0;{\alpha _i},\;{\beta _i}} \right)} \right]{\rm{ }}\\ & + D_i^{nnn}\;ln\left[ {F\left( {0;{\alpha _i},\;{\beta _i}} \right)} \right]\}\end{align}

where $D_i^{nny},D_i^{nnn}$ are responses from the follow-up questions, $F\left( {b;\alpha ,\beta } \right) = {\left[ {1 + \exp \left( {\alpha - \beta b} \right)} \right]^{ - 1}}$ when b has positive value, $F\left( {b;\alpha ,\beta } \right) = {\left[ {1 + \exp \left( \alpha \right)} \right]^{ - 1}}$ when b is zero, which represents the spike at zero willingness to pay, and $F\left( {b;\alpha ,\beta } \right) = 0$ when b has negative value.