II. Literature background

The relationship between alcohol and cannabis use has been the subject of extensive research, with ongoing debate over whether these substances function primarily as substitutes or complements. Some studies report that alcohol and cannabis use can reinforce each other, while others suggest that cannabis may replace alcohol in certain contexts, potentially reducing alcohol-related harms (Gunn et al., Reference Gunn, Aston and Metrik2022). The effects of policy interventions, such as restricting access to one substance, are also mixed: some research finds that limiting one leads to increased use of the other, while other studies observe a concurrent decline in both (O’Hara et al., Reference O’Hara, Armeli and Tennen2016; Weinberger et al., Reference Weinberger, Zhu, Levin, Moeller, McKee and Goodwin2021).

Legalization of medical cannabis has generally led to increased cannabis use among adults, but its impact on adolescent use remains uncertain (Bae and Kerr, Reference Bae and Kerr2020). In contrast, recreational cannabis legalization is more consistently linked to higher cannabis use among adolescents and young adults (Paschall et al., Reference Paschall, García-Ramírez and Grube2021). Age restrictions also shape consumption patterns: Crost and Guerrero (Reference Crost and Guerrero2012) found that reaching the legal drinking age of 21 was associated with increased alcohol use and decreased marijuana use, suggesting that legal access to alcohol may prompt some young adults to substitute alcohol for cannabis.

The evidence for substitution or complementarity is nuanced and often context-dependent. Some studies indicate that liberal cannabis policies are associated with reduced alcohol use among young adults (Subbaraman, Reference Subbaraman2016), whereas others report increased co-use following legalization (García-Ramírez et al., Reference García-Ramírez, Paschall and Grube2021). Cannabis and alcohol use are positively correlated, especially among adolescents and adults (Guttmannova et al., Reference Guttmannova, Lee, Kilmer, Fleming, Rhew, Kosterman and Larimer2016). Daily cannabis users tend to consume more alcohol (Gunn et al., Reference Gunn, Norris, Sokolovsky, Micalizzi, Merrill and Barnett2018), and frequent cannabis use is linked to more frequent drinking (Guttmannova et al., Reference Guttmannova, Fleming, Rhew, Abdallah, Patrick, Duckworth and Lee2021). However, longitudinal research suggests that cannabis users may experience a more rapid decline in alcohol consumption over time, pointing toward a substitution effect (Weinberger et al., Reference Weinberger, Zhu, Levin, Moeller, McKee and Goodwin2021).

The interplay between alcohol and cannabis use is further shaped by economic and policy factors, such as substance pricing and taxation. Some studies have found that higher taxes on beer and other alcoholic beverages reduce the consumption of both alcohol and cannabis, indicating a complementary relationship in certain populations (Williams et al., Reference Williams, Pacula, Chaloupka and Wechsler2004; Miller & Seo, Reference Miller and Seo2021). For example, among college students, increased beer taxes were associated with reduced use of both substances (Williams et al., Reference Williams, Pacula, Chaloupka and Wechsler2004). Conversely, other research reports that the introduction of medical marijuana laws is associated with reduced beer consumption among young adults and fewer alcohol-related traffic fatalities, supporting a substitution effect (Anderson et al., Reference Anderson, Hansen and Rees2013). After recreational cannabis legalization in Washington State, both binge drinking and overall alcohol intake declined while marijuana use increased, again suggesting substitution (Subbaraman, Reference Subbaraman2016).

Recent evidence underscores the importance of distinguishing between user types. Zhu et al. (Reference Zhu, Trangenstein and Kerr2025) demonstrated that, after recreational cannabis legalization in Washington State, recreational cannabis users tended to use alcohol and cannabis together—displaying a complementary pattern—while medical cannabis users showed a substitution pattern, consuming less alcohol on days they used cannabis. This distinction highlights the need to consider user motives and contexts in understanding co-use behaviors, which have significant public health implications for legal cannabis markets.

The physiological and social underpinnings of alcohol and cannabis use also contribute to their complex relationship. Both substances activate similar brain reward pathways, potentially increasing sensitivity to other addictive substances and promoting complementary use (Hall and Lynskey, Reference Hall and Lynskey2005; O’Hara et al., Reference O’Hara, Armeli and Tennen2016). Social and psychological motives further influence co-use patterns. Stevens et al. (Reference Stevens, Aston, Gunn, Sokolovsky, Treloar Padovano, White and Jackson2021) found that motives related to enhancement, socializing, and responding to offers were linked to adverse outcomes through alcohol use, while coping motives were more strongly associated with cannabis use. Planned simultaneous use of both substances is often driven by social and enhancement motives, whereas unplanned co-use is more likely in response to offers or stress relief (Stevens et al., Reference Stevens, Boyle, Sokolovsky, White and Jackson2022).

Coping motives are particularly relevant among college students. Those who use alcohol and cannabis to manage negative emotions may be more likely to substitute one substance for the other (O’Hara et al., Reference O’Hara, Armeli and Tennen2016). Conversely, students who use these substances for social reasons may be more likely to increase use of both (Cooper et al., Reference Cooper, Frone, Russell and Mudar1995; O’Hara et al., Reference O’Hara, Armeli and Tennen2016; Simons et al., Reference Simons, Gaher, Correia, Hansen and Christopher2005).

Overall, the literature highlights a multifaceted and context-dependent relationship between alcohol and cannabis use, shaped by policy, economic factors, user type, and individual motives. Some studies support substitution, others complementarity, and many point to both effects depending on the circumstances (Risso et al., Reference Risso, Boniface, Subbaraman and Englund2020). Brown (Reference Brown2019) notes that the current evidence does not allow for a definitive conclusion regarding the nature of the relationship, highlighting the need for further research, particularly studies that address user type and longitudinal patterns.

III. Materials and methods

b. Methodology

A factor analysis with varimax rotation was performed to simplify the variables and uncover the underlying structure of the motivation factors for wine and cannabis use. The reliability of these constructs was then evaluated using Cronbach’s α.

The relationship between ordinal wine consumption (with 3 levels) and cannabis use is analyzed by the Ordered Probit (OP) model,Footnote ² in which an underlying score is estimated as a linear function of the independent variables and a set of cut points, κ’s. The probability that individual i will select outcome j corresponds to the probability that the estimated linear function plus random error is within the range of the cut points estimated for the outcome:

Outcome equation:

(1)\begin{equation}P\left( {{Y_i} = j} \right) = Pr\left( {k_{j - 1} \lt \left( {\boldsymbol{x_i^\prime{\beta _1}} + {\beta _2}\ Cannabi{s_i} + e.{y_i}} \right){ \leq _{kj}}} \right)\end{equation}

First-stage equations:

(2a)\begin{equation}P\left( {Cannabi{s_i} = n} \right) = Pr\left( {{\vartheta _{n - 1}} \lt \left( {\boldsymbol{{x_i^\prime{\gamma _1}}}+ z_i^\prime{\gamma _2} + e.{c_i}} \right) \leq {\vartheta _n}} \right)\end{equation}

(2b)\begin{equation}\kern-35pt P\left( {Cannabi{s_i} = 1} \right) = \emptyset \left( {{\alpha _0} + {\boldsymbol{ x_i^\prime{\alpha _1}}} + z_i^\prime{\alpha _2} + e.{c_i}} \right)\end{equation}

where $ {e.{y_i}}$ is the unobserved error that is assumed to be standard normal. The coefficients $\beta $’s are estimated together with the cut points $k_1$, $k_2$,…, $k_{J - 1}$, where J is the number of possible outcomes, J = 3 in our case. The term x is a vector of explanatory variables that explain wine consumption, as cannabis does, and ${\beta _2}$ is the key coefficient of our interest.

To meaningfully estimate a model, covariates must be exogenous. This assumption is violated if omitted confounders are correlated with $x_i^\prime$ or cannabis use, if reverse causation is present, if $x_i^\prime$ or cannabis use are measured with error, or if they are correlated with the error term in the outcome equation. In our case, none of these conditions can be ruled out. To address this, we employ an IV-OP model with endogenous covariates,Footnote ³ treating cannabis use as endogenous. In the first stage, cannabis use is regressed on a set of exogenous and instrumental variables.

We examine the relationship between wine consumption (the dependent variable) in two different ways. First, we regress wine use frequency on cannabis user status (binary). Since the endogenous variable cannabis_user is binary, we estimate a Probit model (eq. 2a) using age cohorts (Generation Z, Millennials) and gender (female) as instruments, zs. Since other studies find these controls correlate with cannabis use (Ghvanidze et al., 2024, 2025b), while they are not correlated with wine consumption (see Table S3, Online Supplementary Material), we consider them valid instruments in this model.

Second, we regress the frequency of wine consumption on cannabis use, measured in five ordered categories, with non-use as the reference group. Because the endogenous variable cannabis_usage is ordinal, we estimate an OP model in the first stage (eq. 2b). Differences in cannabis use among users allow us to draw on respondents’ assessments of cannabis’s healthiness and taste. These variables are correlated with cannabis use (see Table S3 in the Online Supplementary Material), apply only to cannabis users, and are unlikely to have a direct effect on wine consumption. We therefore use two binary instruments: C_healthy (equal to one if the respondent believes cannabis is healthy) and C_taste (equal to one if the respondent likes the taste of cannabis).

In both specifications of the first-stage model, the unobserved error term $e.{c_i}$ is assumed to follow a standard normal distribution. The presence of endogenous covariates is reflected in a nonzero correlation between the error terms of the outcome equation (eq. 1) and the first-stage equations (eq. 2a or eq. 2b). Formally, this is expressed as $\rho = corr\left( {e.{y_i},e.{c_i}} \right)$.

V. Discussion and conclusion

Understanding the relationship between alcohol and cannabis use is vital for developing effective strategies to manage substance use (O'Hara et al., Reference O’Hara, Armeli and Tennen2016). This study takes an innovative approach by examining whether cannabis and wine act as substitutes or complements to one another. The motivations and patterns behind the consumption of these substances can differ significantly. Initially, the research delved into the motives for consuming wine and cannabis. It also investigated the potential substitution or complementarity between the two by analyzing the correlation between their consumption frequencies. In our study, a complementary relationship would mean that frequent use of one substance is associated with higher use of the other, while a substitution relationship would indicate that higher use of one is associated with lower consumption of the other.

Our factor analysis indicates that the main motivation for using cannabis is enhancement. Cannabis is also frequently associated with coping and boosting creativity. These findings align with previous research, which suggests that cannabis is commonly used to amplify positive experiences, foster social connections, and enhance overall enjoyment, mood, and well-being (Fleming et al., Reference Fleming, Graupensperger, Calhoun and Lee2022).

The findings from the correlation tests and OP models indicate a complementary relationship between wine and cannabis. This pattern suggests that more frequent cannabis use is associated with more frequent wine consumption, indicating a complementary relationship specifically among cannabis users. Moreover, we find that individuals identified as cannabis users tend to consume wine more frequently, regardless of how often they use cannabis.

However, it is crucial to remember that this relationship is correlational and does not establish a causal link between the two behaviors. This finding is consistent with previous research showing that frequent recreational cannabis users tend to drink more alcohol overall (Gunn et al., Reference Gunn, Norris, Sokolovsky, Micalizzi, Merrill and Barnett2018) and that higher cannabis use correlates with increased alcohol intake on days when cannabis is used (Gunn et al., Reference Gunn, Jackson, Borsari and Metrik2019). Such users may face greater risks related to the combined use of these substances (Gunn et al., Reference Gunn, Jackson, Borsari and Metrik2019) or might experience enhanced dopaminergic effects from using both together (Hall and Lynskey, Reference Hall and Lynskey2005).

Our analysis confirms that wine consumption and cannabis use are endogenous behaviors, implying that unobserved factors influencing one are likely to influence the other. Since the estimated correlations are mostly negative, our data suggest that these unobserved factors tend to drive wine and cannabis consumption in opposite directions.

In fact, we identify opposite associations (or correlations with only one product) for several observed socio-demographic covariates in our study, such as education, income, and age. We also find that taste preferences and perceived healthiness regarding cannabis, together with age and education, serve as very good instruments. Future research should explore which omitted factors, not captured in our survey, may contribute to more accurate modelling of this relationship.

An interesting finding is that the complementary relationship observed between cannabis user and almost all types of wine does not extend to red wine. This could be due to two main reasons: Firstly, red wine is often enjoyed with heavy meals in traditional, familiar settings, either at home or outside. Consumers who favor this type of food and setting might be less inclined to use cannabis. Moreover, red wines are generally more expensive. Secondly, drinking red wine is sometimes seen as a coping mechanism or a way to relax. If this need is already met through cannabis use, there may be less desire to drink red wine for the same purpose (O'Hara et al., Reference O’Hara, Armeli and Tennen2016; Stone and Kennedy-Moore, Reference Stone, Kennedy-Moore and Friedman1992). However, this relationship is not apparent when cannabis use is considered as a binary choice; the complementary relationship emerges only when analyzing the frequency of both cannabis and red wine use.

Additionally, our findings reveal that increased consumption of rosé and sparkling, and red wines is associated with more frequent cannabis use when cannabis is used for mood enhancement. This is consistent with research by Fleming et al. (Reference Fleming, Graupensperger, Calhoun and Lee2022), Hamilton et al. (Reference Hamilton, Jang, Patrick, Schulenberg and Keyes2019), O’Hara et al. (Reference O’Hara, Armeli and Tennen2016), and Stevens et al. (Reference Stevens, Aston, Gunn, Sokolovsky, Treloar Padovano, White and Jackson2021), which suggests that individuals who use alcohol for enhancement purposes tend to consume both substances more frequently and concurrently. Moreover, drinking rosé, sparkling, and white wines is often linked to socializing in pleasant and relaxed environments.

Furthermore, the results indicate a substitution relationship, as wines are consumed less frequently, whereas cannabis is used more frequently for conformity, to fit in with a group. Although this finding holds for all wines, the negative association is stronger for rosé & sparkling, and sweet wines. This aligns with the findings of O’Hara et al. (Reference O’Hara, Armeli and Tennen2016), which suggest that when both alcohol and cannabis are used to fit in with a group and to cope with stress, higher alcohol consumption reduces the likelihood of cannabis use. Moreover, cannabis and sweet wines are substitutes when cannabis is used for socializing.

Our study’s findings are also consistent with previous research, which suggests that alcohol consumption is frequently associated with social activities, whereas cannabis use is often related to coping with stress, anxiety, and negative emotions, as well as managing social isolation (Fleming et al., Reference Fleming, Graupensperger, Calhoun and Lee2022; O’Hara et al., Reference O’Hara, Armeli and Tennen2016).

Alcohol and cannabis use share physiological and social factors that reinforce their complementary nature (Hall and Lynskey, Reference Hall and Lynskey2005). Research on animals suggests these substances activate similar brain reward pathways, which may increase sensitivity to other addictive substances and promote complementary use (O’Hara et al., Reference O’Hara, Armeli and Tennen2016).

The findings of this study underscore the complexities involved in addressing substance use among wine consumers. Although infrequent cannabis use poses less risk than frequent use, the complementary use of wine and cannabis significantly increases the chances of accidents, alcohol-related consequences, and health problems (Lee et al., Reference Lee, Calhoun, Abdallah, Blayney, Schultz, Brunner and Patrick2022). Policies or interventions designed to curb alcohol and cannabis use may have varying effects on different groups of consumers. Notably, reducing cannabis use among frequent users could decrease the concurrent use of both substances; the same could be the case for heavy wine drinkers. Therefore, strategies to reduce complementary use should focus on frequent users of cannabis and frequent wine drinkers.

VI. Limitations and future research

This study underscores the need for further research in determining whether wine and cannabis function as substitutes or complements. The lack of detailed data on consumption patterns, including timing and quantity, necessitates further investigation to clarify the circumstances under which (and for whom) these substances may act as substitutes or complements. For example, individuals might use them alternately or together depending on context and motivation. Investigating these relationships in various social settings is not just important but essential for a comprehensive understanding (Weinberger et al., Reference Weinberger, Zhu, Levin, Moeller, McKee and Goodwin2021).

The results of this study may be influenced by self-selection, as participants voluntarily opted into the online survey. To improve the reliability and generalizability of future research, it is recommended that participants be recruited using randomized sampling drawn from the broader population of wine consumers. This approach would help reduce potential biases associated with self-selection. It is also important to note that our sample includes only individuals who reported wine consumption within the past 30 days. As such, the findings pertain exclusively to active wine consumers. The study cannot therefore speak to whether cannabis use influences the binary decision to consume wine at all.

With Germany on the verge of major regulatory changes related to cannabis legalization, future research should include longitudinal studies to track changes in consumption patterns, motivations, and the interaction between wine and cannabis, whether as substitutes or complements. Investigating shifts in attitudes and perceived benefits of cannabis and wine post-legalization may shed light on behavioral changes and associated health impacts. These insights could help shape public health strategies aimed at minimizing harm in a post-legalization context (Turna et al., Reference Turna, Balodis, Van Ameringen, Busse and MacKillop2022).