Data collection – Experimental design

The data were collected via two online surveys – one for dried cranberries and another for cranberry juice – administered by the Qualtrics Research Services™ consumer research panel. We asked Qualtrics to gather participants over 18 years of age through random selection, to match the demographic profile of gender, age, and income as closely as possible to the general population in the United States. The surveys were pretested during a soft launch in November 2020, and data collection took place from December 2020 through March 2021.

The survey consisted of eight versions originating from the combination of four information treatments and two products (dried cranberries and cranberry juiceFootnote ² ). Qualtrics provided 250 nationwide respondents for each survey version, resulting in 1,000 responses for the dried cranberry survey and 1,000 for the cranberry juice survey, totaling 2,000 respondents. The screening criteria for the respondents varied based on the product being surveyed. The dried cranberry survey aimed to gather responses from both regular and non-regular consumers, so individuals who purchased or consumed dried cranberries at least once a year were selected. For the cranberry juice survey, the study screened for individuals who were familiar with the different cranberry juice categories (100% cranberry juice, cranberry cocktail, and cranberry juice blend), as knowledge and experience with the product are necessary to mimic a real-life purchasing situation as closely as possible to provide accurate and unbiased estimates (Louviere, Reference Louviere2006). The Institutional Review Board approved the survey (Mississippi State University IRB-20-305).

Choice experiment design

This study used a discrete choice experiment (DCE) to elicit consumers’ WTP for attributes of dried cranberries and cranberry juice. We used a cheap talk script (Champ, Moore and Bishop Reference Champ, Moore and Bishop2009) and a certainty scale to mitigate hypothetical bias (Hensher et al., Reference Hensher, Rose and Beck2012). The cheap talk script was presented to respondents in the explanation that preceded the DCE scenarios. An example of the complete set of descriptions presented to respondents is provided in Appendix A for dried cranberries and Appendix B for cranberry juice.

After each DCE scenario, a follow-up certainty question was presented following Hensher, Rose and Beck (Reference Hensher, Rose and Beck2012) who proved that including questions to assess the extent to which a respondent is certain of actually choosing the DCE alternative mitigates the proneness to hypothetical bias. This study used the 1–10 certainty scale, where 1 = “Very uncertain” and 10 = “Very certain.” An example of the certainty scale used is also included in Appendices A−B.

A detailed description of the attributes and attribute levels included in both DCE versions (dried cranberries and cranberry juice) is presented in Table 1. The study included three attributes with two levels: total sugars, cranberry flavor, and cranberry breeding technologies. A description of each attribute was included in the survey, before the DCE, and can be found in Appendix A for dried cranberries and Appendix B for cranberry juice. The total sugar levels for the dried cranberries were presented as “Regular” and “50 Less Sugar” which are equivalent to 29 g. and 14 g. of sugars per serving, respectively. For cranberry juice, “Original” is equivalent to 25 g., and “50% Less Sugar” is equivalent to 12 g. of sugars. These levels were aligned with commercial products in the market. Instead of added sugar, total sugar was included because the study aimed to investigate if there were trade-offs between total sugar content and the possibility of reducing it by applying CRISPR. By doing so, it is possible that the flavor intensity of cranberries is affected. Given that literature suggests flavor attributes are crucial for consumers’ acceptance, we included flavor with two levels, full/intense and bland/weak. Price was included with three levels for each product. For dried cranberries: $1.99, $2.99, and $3.00 per 6-oz bag, and for juice: $2.49, $2.99, and $3.99 per 64-fl-oz bottle. These prices were consistent with prices of similar commercial products when the survey took place.

Table 1. List of attributes and attribute levels for sets of discrete choice experiment scenarios for dried cranberries, and cranberry juice

The attribute levels included yielded a total of 72 possible combinations (2³ × 3²) for each cranberry product. We generated a multinomial logit D-efficient fractional factorial experimental design with no priors in NGENE version 1.2. The experimental design, for each cranberry product, consisted of 18 choice sets divided into three blocks of six choice tasks each, with a D-error of 0.06 and 0.23 for the dried cranberries and cranberry juice, respectively.

In the dried cranberries survey, respondents evaluated six hypothetical purchase scenarios. Each scenario consisted of two 6–oz bags of dried cranberries with varying attribute levels options (A and B) and a no-buy option. An example of a dried cranberries choice scenario is presented in Appendix A. For the cranberry juice version, respondents were presented with six scenario choices with three cranberry juice options – “100% Juice,” “Cocktail,” and “Blend” – and a no-buy alternative. The narrative that preceded the juice DCE had a definition of each juice type following guidance from industry stakeholders. An example of the cranberry juice scenario choice is presented in Appendix B.

Information treatments

Because the public is often exposed to different types of food information that could affect food preferences (Dutriaux et al. Reference Dutriaux, Papies, Fallon, Garcia-Marques and Barsalou2021), we tested how emphasizing different kinds of information scripts would impact the WTP for total sugars, flavor intensity, and plant breeding technology. We included four information treatments. Treatment 1 was the control, with no information.

Treatment 2 presented a script on the health benefits of cranberries: Cranberries are considered a superfood due to their high nutrient and anthocyanin content. Anthocyanins are substances that can prevent or slow damage to cells caused by free radicals. The anthocyanin properties of cranberries provide multiple health benefits, including the support of cardiovascular health and reduction of the risk of some cancers. We hypothesize that the treatment 2 information would result in a higher WTP (decreased price discount) for regular sugar content, CRISPR breeding, and bland and weak cranberry flavor, compared to the control: H₀₁: WTP^treatment1 $ \le $ WTP^treatment2, H_a1: WTP^treatment1 $ \gt $ WTP^treatment2.

Treatment 3 presented a script with the recommended sugar intake limit and the benefit of limiting sugar consumption: The FDA defines “Added Sugars” as sugars that are added during the processing of foods. Added sugars increase calories without contributing important nutrients. The Dietary Guidelines for Americans recommend limiting the daily amount of added sugars consumed to no more than 10% of total calories per day (which is equivalent to 200 calories or 50 grams per day). Diets lower in sugar-sweetened foods are associated with a reduced risk of developing cardiovascular disease Footnote ³ . We anticipate that the inclusion of the information in treatment 3 would lead to a lower WTP (increased price discount) compared to the control, for regular sugar content, CRISPR breeding, and bland and weak cranberry flavor: H₀₂: WTP^treatment1 $ \geqslant $ WTP^treatment3, H_a2: WTP^treatment1 $ \lt $ WTP^treatment3.

Treatment 4 included both sets of information provided in treatments 2 and 3. In this case, we expect that the health benefits information will counterbalance the impact of the dietary recommendation to limit added sugar consumption, resulting in the same willingness to pay as in the control (H₀₃: WTP^treatment1 = WTP^treatment4, H_a3: WTP^treatment1 $ \ne $ WTP^treatment4).

The text describing each information treatment was presented right before the DCE. An example of Treatment 4, which includes both treatments 2 and 3 scripts, is shown right before the DCE exhibits in Appendices A for dried cranberries and B for cranberry juice. A between-subjects design was used for all survey versions. Respondents were randomly assigned to each information treatment.

The survey included questions about respondents’ sociodemographic characteristics such as gender, age, racial-ethnicity, education, income, number of people in the household, presence of children, self-reported health status, and diet-related chronic disease diagnoses. The survey also included questions to gauge preferences for cranberry product attributes, food purchase habits, and respondents’ use of NFP labels, use of information on the NFP label, and a heat map for respondents to identify the piece of information on the NFP most important to them. In addition, we included questions to measure whether respondents correctly interpreted the added sugar line on the NFP. We also asked questions to assess perceptions on using new technologies for food production and processing, plant breeding technologies (specifically genetic engineering versus CRISPR), and the level of trust on different information sources related to food.

Empirical approach

The current study’s empirical approach stems from the demand theory by Lancaster (Reference Lancaster1966) and the random utility model by McFadden (Reference McFadden and Zarembka1974) The demand theory states that consumers derive utility from the attributes inherent to a good rather than the good itself. At the same time, the random utility model postulates that consumers’ utility can be explained by a deterministic component given by the good’s attributes and a random component given by unobserved factors.

This study estimated the models in WTP space using the Generalized Multinomial Logit Model (GMNL) proposed by Fiebig et al. (Reference Fiebig, Keane, Louviere and Wasi2010). The GMNL models allow for scale heterogeneity and preference heterogeneity. Scale heterogeneity is defined as the variance in the degree of randomness between respondents in the decision-making process. Following Fiebig et al. (Reference Fiebig, Keane, Louviere and Wasi2010), the general specification of the GMNL model is as follows,

(1) $${U_{ni}} = \left[ {{\sigma _n}{\rm{\beta }} + \gamma {\eta _n} + \left( {1 - \gamma } \right){\sigma _n}{\eta _n}} \right]{x_{ni}} + {\varepsilon _{ni}} \\ {\beta _n} = {\sigma _n}{\rm{\beta }} + \left[ {\gamma + \left( {1 - \gamma } \right){\sigma _n}} \right]{\eta _n}$$

where ${\sigma _n}$ is the individual-specific scale of the idiosyncratic error term that captures scale heterogeneity and is log-normally distributed with mean $\bar \sigma $ and standard deviation τ. ${\eta _n}$ is a vector of individual specific taste deviate from the mean based on observed attributes, and it captures residual preference heterogeneity, and $\gamma $ is a parameter between 0 and 1 that controls how the variance of residual taste heterogeneity ${\eta _n}$ varies with the scale heterogeneity ${\sigma _n}$ .

We estimated the different model formulations encompassed by the GMNL: the Type II, where $\gamma = 0$ (GMNL-II) and Type I where $\gamma = 1$ (GMNL-I) to the Random Parameter Logit (RPL) model. In the GMNL-I model, the standard deviation of residual taste heterogeneity is independent of the scale, whereas in the GMNL-II model, it is proportional to the scale. The RPL model is a special case of the GMNL model where the scale of the error term, ${\sigma _n}$ , is normalized to 1 (Fiebig et al. (Reference Fiebig, Keane, Louviere and Wasi2010). All models were estimated using the “gmnl” package in R 4.0.5 (Sarrias and Daziano Reference Sarrias and Daziano2017). After comparing goodness of fit indicators [Akaike Information Criterion (AIC), Bayesian Information Criterion (BIC), and the likelihood functions] of the models estimated, we found that the GMNL-II model outperforms the GMNL-I and RPL models. Thus, we report the results of the GMNL-II model.

Following the general form of the GMNL and the attributes of the cranberry products in our study, we can write the utility respondent n derives from choosing alternative I as:

(2) $${U_{ni}} = {\ \beta _{AS{C_n}}}AS{C_n} + {\sigma _n}( { - Price + {\beta _{RS}}RegularSugar + {\beta _{BF}}BlandFlavor} \\ + {{\beta _{CRISPR}}CRISPR + L{\eta _n}} ) + {\varepsilon _{ni}} $$

where $Price$ is a continuous variable that takes any of the three values in the experimental design, and whose coefficient takes a fixed value of −1. The coefficient of Price is normalized to −1 so that the attribute coefficients can be directly interpreted as WTP values (Sarrias and Daziano Reference Sarrias and Daziano2017). $RegularSugar$ is a binary variable indicating the product has a regular sugar content, $BlandFlavor$ is a binary variable indicating the product has a bland/weak cranberry flavor intensity (flavor was described as the overall combination of sensations and its influence by taste, aroma, look and texture), $CRISPR$ is a binary variable indicating that the product is made from CRISPR cranberries, ${\beta _{AS{C_n}}}$ is the alternative-specific constant (ASC), L is the lower triangular matrix of the Cholesky decomposition, and ${\eta _n}$ follows a standard normal distribution.

We allowed for scale heterogeneity in the scale parameter ${\sigma _n}$ across individuals based on their stated choice certainty level (Kunwar, Bohara and Thacher Reference Kunwar, Bohara and Thacher2020), such that:

(3) $${\sigma _n} = exp\left( {\delta certai{n_n} + \tau {\nu _n}} \right)$$

where $\delta $ is the parameter of the observed heterogeneity in the scale term, $\tau $ is the coefficient on the unobserved scale heterogeneity, ${\nu _n}\sim N\left( {0,1} \right)$ , and $certai{n_n}$ is an indicator variable equal to 1 if individual $n$ ’s level of certainty after responding to each choice scenario is greater or equal to 7 and 0 otherwise. ^{Footnote 4}

To investigate the trade-offs between having a product with regular sugar content and acceptance of CRISPR technology, we estimated the marginal rate of substitution between regular sugar content and CRISPR (see Appendix D).

Compensating surplus

To further understand respondents’ preferences for cranberry products with different combination of attribute levels, we computed the compensating surplus (CS). This represents the welfare change for consumers when going from a base option to an improved hypothetical scenario. Following Britwum and Yiannaka (Reference Britwum and Yiannaka2019) and Espinosa-Goded, Barreiro-Hurlé and Ruto (Reference Espinosa-Goded, Barreiro-Hurlé and Ruto2010), CS is defined as:

$$Compensating\;surplus = - \left( {{1 \over {{\beta _{price}}}}} \right)\left( {{V_1} - {V_2}} \right)$$

where ${V_1}$ is the conditional indirect utility of the base option, ${V_2}$ is associated with the hypothetical option which represents the alternative with the change. The base option and hypothetical option are described in Table 2. The base option for both cranberry products (dried cranberries and cranberry juice) is defined as cranberry products manufactured from conventionally bred cranberries, with regular sugar content and a weak cranberry flavor. CRISPR-bred cranberries with reduced sugar content and full cranberry flavor are the hypothetical alternative. We solely used data from the control treatment (no additional information) group in order to rule out any potential impacts of the information treatment. In our GMNL-II certainty model, the parameter of price is fixed at −1, thus the economic surplus becomes:

$$Compensating{\rm{\;}}surplus = {V_1} - {V_2} = \Delta {\widehat V_l}.$$

Table 2. Description of base cranberry product option and hypothetical option used in compensating surplus analysis

Latent class model

A latent class analysis was performed to investigate the factors triggering the heterogeneity in WTP estimates for the cranberry products’ attributes. The model assumes unobservable characteristics are captured by class membership variables or respondents’ socioeconomic characteristics, cranberry and food purchase habits, knowledge, and perceptions of plant breeding methods (genetic engineering and CRISPR).Footnote ⁵

The latent class model captures the heterogeneous preferences by identifying segments within the sample of survey respondents, namely classes. Accordingly, individuals were grouped into several latent classes or unobservable subgroups. Preferences across classes are heterogeneous, but choices within each class are homogeneous. The mathematical formulation of the latent class model can be found in (Greene and Hensher Reference Greene and Hensher2003)

To identify the number of classes, this study used a set of indicators including measures of goodness of fits such as AIC, BIC, and likelihood function; the best-fitting model is the one with the smaller AIC and BIC. Other criteria include the interpretability of results and classification diagnosis. The latter ensures that selected classes are not an expanded version of the other (Nylund-Gibson and Choi Reference Nylund-Gibson and Choi2018). We opted for three classes across all regressions, as these models exhibit the lower values for the AIC and the BIC, ensuring the interpretability of results and the number of statistically significant parameter estimates in each class. Appendix D presents the measures of goodness of fit used as part of the criteria to select the number of classes. The latent class models were estimated in R 4.0.5 using the package “gmnl” developed by (Sarrias and Daziano Reference Sarrias and Daziano2017).