Association Between Marijuana Exposure and Pulmonary Function over 20 Years

Abstract

INTRODUCTION

Exposure to tobacco smoke causes lung damage with clinical consequences that include respiratory symptoms, chronic obstructive pulmonary disease (COPD), and lung cancer1,2. COPD and lung cancer are leading causes of death2,3, and smoking tobacco cigarettes is the most important preventable cause of death in the United States4,5.

Marijuana smoke contains many of the same constituents as tobacco smoke6, but it is unclear whether smoking marijuana causes pulmonary damage similar to that caused by tobacco. Prior studies of marijuana smokers have demonstrated consistent evidence of airway mucosal injury and inflammation7–9, and increased respiratory symptoms such as cough, phlegm production and wheeze similar to tobacco smokers10–12. However, analyses of pulmonary function and lung disease have failed to detect clear adverse effects of marijuana use on pulmonary function10–13. It is possible that cumulative damage to the lungs from years of marijuana use could be masked by short-term effects; prior analyses have not attempted to disentangle these factors. Smoking marijuana is increasingly common in the United States14, and understanding whether it causes lasting damage to lung function has important implications for public health messaging and medical use of marijuana15,16.

The Coronary Artery Risk Development in Young Adults (CARDIA) Study collected repeated measures of tobacco and marijuana smoking as well as pulmonary function over 20 years in more than 5000 study participants. We estimated both current intensity and lifetime cumulative exposure to tobacco and marijuana smoking, and analyzed their associations with spirometric measures of pulmonary function over the 20 years of follow-up.

METHODS

RESULTS

The 5115 CARDIA participants recruited in 1985–6 contributed 20,777 total visits that included pulmonary function testing. Of these, 959 visits were excluded for lack of complete information on smoking behavior, 114 for lack of height or waist measurements, and 1 for an unknown visit date, leaving 19703 visits (95%) with complete data from 5016 participants (98%). Participants contributed 3.9 visits/participant on average; attrition was more common in tobacco smokers but not associated with marijuana use. FEV1 and FVC varied across participants, rose slightly with age through the late 20’s, and declined slowly thereafter (Figure 1).

Figure 1

Pulmonary function measurements by age

More than half of participants (54%, mean age 25 at baseline) reported current marijuana or tobacco smoking or both at one or more examinations (Table 1). Smoking patterns differed by race and sex, with black women most likely to smoke tobacco only, white men most likely to smoke marijuana only, and black men most likely to smoke both. Tobacco smokers tended to have lower education and income and to be slightly shorter and less active, whereas marijuana smokers tended to be taller and more active. The median intensity of tobacco use in tobacco smokers was substantially higher (8–9 cigarettes per day) than the median intensity of marijuana use in marijuana smokers (2–3 episodes in the last 30 days). While marijuana and tobacco exposures were strongly correlated, our sample included 91 participants with no tobacco exposure and more than 10 joint-years of marijuana exposure (contributing 153 observations of pulmonary function), 40 (56 observations) of whom had more than 20 joint-years of exposure.

Table 1

Characteristics of CARDIA participants with pulmonary function test results, by smoking behavior

In fully adjusted models that considered 4-level categorizations of current and lifetime exposure to tobacco and marijuana, tobacco smoking (both current and lifetime) was associated with a lower FEV1, and current smoking with a lower FVC (Table 2). For example, compared with zero exposure, FEV1 was 63 ml lower (95%CI: −89 – −36) and FVC was 69 ml lower (95%CI: −97 – −41) with current tobacco exposure of >20 cigarettes per day, and 101 ml lower (95%CI: −136 – −65) with lifetime tobacco exposure >20 pack-years. In contrast, exposure to marijuana (both current and lifetime) was associated with a higher FVC, and lifetime exposure with higher FEV1. For example, compared with zero exposure, FVC was 59 ml higher (95%CI: 12 – 107) and FEV1 36 ml higher (95%CI: −6.5 – 79) with lifetime marijuana exposure >20 joint-years, and FVC was 20 ml higher (95%CI: −5.2 – 49) with >20 episodes of marijuana use/month. We found no statistically significant interactions between tobacco and marijuana exposure for either FEV1 or FVC.

Table 2

Associations between categorized exposure to tobacco and marijuana smoke and pulmonary function

When we modeled current and lifetime tobacco and marijuana exposure as continuous exposures and permitted flexible non-linear associations (via splines), we again found strong, dose-related associations (p<.001) between increasing exposure to tobacco and lower FEV1 and FVC (Figure 2), with no evidence of non-linearity (Table 3). Declining slopes ranged as steep as −2.8 ml (95%CI: −4.8 – −0.7) per additional cigarette smoked per day and −7.0 ml (95%CI: −10 – −3.7) per additional pack-year for FEV1, and were of similar magnitude for FVC (Table 3). At 50 pack-years of exposure, FEV1 was on average 332 ml lower (95%CI: −401 – −263) and FVC was 229 ml lower (95%CI: −310 – −147) compared with no exposure.

Figure 2

Associations between continuous smoothed exposure to current and lifetime tobacco and marijuana and pulmonary function

Table 3

Estimated slopes and net associations between continuous smoothed exposure to current and lifetime tobacco and marijuana and pulmonary function

For marijuana, we found strong statistical evidence that associations between marijuana use and pulmonary function were non-linear (Figure 2, Table 3). At low lifetime exposure levels, increasing marijuana use was associated with a steepincrease in both FEV1 (13 ml/joint-year higher [95%CI: 6.4–20]) and FVC (20 ml/joint-year FVC [95%CI: 12 – 27]); but at higher levels of exposure (>7 joint-years), the slope leveled out or even turned downwards. At >10 joint-years of lifetime exposure, we found a declining slope for FEV1 of borderline significance (−2.2 ml/joint-year [95%CI: −4.9 – 0.36], p=0.079), and a significant decline in FEV1 at more than 20 episodes of marijuana use per month (−3.2 ml/episode [95%CI: −5.8 – −0.6], p=.017). While net associations with FEV1 became negative at very high exposure levels (>40 joint-years/>25 episodes/month), these negative deflections were not statistically significant (Table 3). FVC remained significantly elevated in even heavy users (e.g., 76 ml [95%CI:34 – 117) at 20 joint-years).

COMMENT

In this 20-year study of marijuana and pulmonary function, we confirmed the expected reductions in FEV1 and FVC from tobacco use. In contrast, marijuana use was associated with higher FEV1 and FVC at the low levels of exposure typical for most marijuana users. With up to 7 joint-years of lifetime exposure (e.g., 1 joint/day for 7 years or 1 joint/week for 49 years), we found no evidence that increasing exposure to marijuana adversely affects pulmonary function. This association, however, was non-linear: at higher exposure levels, we found a leveling off or even a reversal in this association, especially for FEV1. While our sample contained insufficient numbers of heavy users to confirm a detrimental effect of very heavy marijuana use on pulmonary function, our findings suggest this possibility.

The associations we found between tobacco and pulmonary function are consistent with a large body of prior research on the adverse pulmonary consequences of tobacco smoking. The high prevalence of tobacco smoking, the wide range of exposure intensity among smokers, and tobacco’s legality have made it an easy target for observational epidemiology. Exposure predicts reduced expiratory flow and air trapping, gas exchange abnormalities and emphysema1, and smoking cessation interventions reduce the rate of FEV1 decline in smokers26 (i.e., these associations are likely causal). Our findings of a linear dose-response relationship showing lower FEV1 and FVC with increasing tobacco exposure, consistent with prior findings, represent a positive control for our study of the association between marijuana smoking and pulmonary function.

Prior studies of marijuana and pulmonary function have yielded apparently conflicting results10–13. Many studies have focused on the ratio of FEV1/FVC, lower values of which suggest the presence of airway obstruction, and have found either no association10,20,27 or lower FEV1/FVC with marijuana use28–32. Lower FEV1/FVC in marijuana smokers, however, can be explained at least partly by a tendency towards higher FVC or total lung capacity28,29,32. A recent longitudinal study, which demonstrated significantly higher FVC and total lung capacity with marijuana exposure, strongly supports this notion13,20, as does our study.

Marijuana’s potential association with FEV1 has been even less clear. Tobacco smoking reduces FEV1, but despite the similarities in the constituents of marijuana smoke and tobacco smoke and a priori expectations that marijuana smoking might have similar effects, prior research has not demonstrated this. In studies that report FEV1 in association with marijuana use, findings have mostly been null20,28,32–35, though one study reported the apparently paradoxical finding of a lower FEV1 withpast marijuana use, but a non-significantly higher FEV1 with current use29.

Our study suggests a way to reconcile these findings. Because of the many thousands of measurements obtained over 20 years among over 5000 participants with a wide range of smoking habits, we could simultaneously account for levels of current and past lifetime use of both marijuana and tobacco, and test for non-linearity in their associations with pulmonary function in order to disentangle short-term and long-term effects. We found highly significant non-linearity, with a positive association for both FEV1 and FVC at low levels of exposure that reversed in direction towards a possibly negative association for FEV1 at higher levels of exposure (see Figure 2 and slopes in Table 3). These findings could explain the past/current paradox previously noted29, and are also consistent with the average null association reported in studies20,28,32–35 that either dichotomized marijuana exposure (user/non-user)28–31,33,36 or constrained the association to be linear across all levels of exposure10,20,32,35. When we looked at “marijuana only” smokers (Table 2, first panel), we also found a null association with FEV1 and FVC. Only after parsing out the association at different levels of exposure, with careful control for confounding, did the suggestion of a negative association for FEV1 at high levels of exposure emerge.

These findings suggest that marijuana smoking could influence pulmonary function via multiple mechanisms. To explain the higher FVC previously observed in marijuana smokers20,32, some have proposed that the deep inspiratory maneuvers practiced by marijuana smokers could stretch the lungs13,20, resulting in larger lung volumes20,32. Another speculative possibility is strengthening of chest wall musculature or another “training” effect that allows marijuana users to inspire more fully (closer to total lung capacity) on spirometry testing. A non-destructive stretch or training effect is consistent with previously reported findings in marijuana smokers of lower lung density32 and a lack of emphysematous change32 or diminished diffusion capacity20,27,32,36. This mechanism would explain our FVC results, and could explain the positive deflection of FEV1. The functional impact of this association on lung health or respiratory function in daily life is unclear13. An alternate explanation is the acute bronchodilatory effect of marijuana use that has been directly observed in some studies11. This effect, however, is transient (lasting approximately 60 minutes11), and seems unlikely to explain higher lung volumes measured during the CARDIA examination unless many marijuana users smoked immediately before the examination.

The suggestion of a negative association with FEV1 at higher exposure levels could reflect mixing of this putative stretch/training effect with a second mechanism operating on a different time-exposure scale. A negative association with heavy marijuana smoke exposure aligns with our a priori hypothesis that marijuana smoking should produce damage to the airways and accelerated loss of lung function similar to that caused by tobacco smoking. Hypothetically speaking, a positive effect from marijuana in the short term (the stretch/training effect) and a negative effect in the long term (damage from smoke exposure), should result in a non-linear association such as the one we observed. According to this explanation, the predominant effect for FEV1 at very high exposure (over 40 joint-years) reflects cumulative damage; the predominant effect for FVC at all levels of exposure is from the stretch/training mechanism.

Our study has limitations. While CARDIA offers longitudinal spirometry measurements, it lacked body plethysmographic measurements of static lung volumes (total lung capacity and residual volume) and measures of diffusing capacity and radiographic emphysema. A minority of our participants reported very high levels of marijuana exposure (and a smaller minority of these were non-smokers of tobacco), so our estimates at high marijuana exposure levels are imprecise. The self-reported measures of marijuana and tobacco smoking are certain to include recall error, both random and systematic, and do not include any indication of smoking method (joint, pipe, “bong”, etc). It is unlikely, however, that such error would differentially occur in association with pulmonary function, and non-differential error would most likely bias results towards of the null. Our mixed modeling approach is ideal for filtering out random error and taking advantage of individual-level correlations in the data. As with any observational analysis, unmeasured or inadequately modeled confounding effects could be mixed with our estimates, but our study’s extensive covariate measurements and large sample permitted more extensive efforts to control confounding than were possible in previous studies.

Marijuana may have beneficial effects on pain control, appetite, mood, and management of other chronic symptoms15,16. Our findings suggest that occasional use of marijuana for these or other purposes would not have significant adverse consequences on pulmonary function. It is more difficult to estimate the potential effects of regular heavy use, as this pattern of use is relatively rare in our study sample; however, our findings do suggest an accelerated decline in pulmonary function with heavy use, and a resulting need for caution and moderation when marijuana use is considered.

ACKNOWLEDGEMENTS

Footnotes

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