Strawberry Additive Increases Nicotine Vapor Sampling and Systemic Exposure But Does Not Enhance Pavlovian-Based Nicotine Reward in Mice

Animals

Adolescent male (n = 191) and female (n = 170) C57BL/6J mice between postnatal day 28 (P28) and P49, corresponding approximately to humans 12–18 years of age (Yuan et al., 2015), were used in the CPP and blood collection experiments (Figs. 1-5). They were housed at the University of Pennsylvania with a reverse 12 h light/dark cycle (lights off at 10:00 A.M.) in a temperature-controlled room (24 ± 2°C; relative humidity, 55 ± 10%). All behavioral testing and e-cigarette vapor exposures occurred in the dark phase of the light cycle. Animals were either purchased from The Jackson Laboratory or bred in-house. Those bred in-house were the offspring of 20+ different breeding pairs and distributed throughout treatment groups to ensure adequate genetic diversity. Similarly, adolescent male (n = 14) and female (n = 11) C57BL/6J mice between P28 and P49 were used in the plethysmography experiments (Figs. 4, 5) and were housed at the University of Florida in comparable conditions. All mice in this study had ad libitum access to food and water. All procedures were approved by the appropriate Institutional Animal Care and Use Committee and followed the guidelines for animal intramural research from the National Institutes of Health.

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Figure 1.

Nicotine delivery via e-cigarette vapor results in measurable plasma cotinine concentrations, and the rewarding properties of e-cigarette vapors can be evaluated using conditioned place preference. A, A vapor exposure setup allows for the simultaneous delivery of e-cigarette vapor to four mice, each in its own airtight chamber. B, Scatter plots of plasma cotinine concentrations detectable in adolescent mice (mean ± SEM) 30 min after nicotine exposure via an intraperitoneal injection (yellow diamonds, top x-axis, n = 7, 4, 7, 5) or e-cigarette vapor exposure as depicted in A (blue boxes, bottom x-axis, n = 27, 28, 4, 46). C, Schematic of the vapor-conditioned place preference paradigm in which mice receive experimental vapor (nicotine) once per day for 5 d in the CS+ compartment and vehicle once per day for 5 d in the CS– compartment. D, Before and after plots show the time spent in the CS+ environment before and after conditioning with nicotine vapor (n = 28, 20, 24, 25). E, Before and after plots show the time spent in the CS+ environment before and after conditioning with strawberry vapor of various concentrations (n = 28, 20, 13). In D and E, bars show the mean ± SEM, and the vehicle data (i.e., “0”) are the same in both panels. Two-way repeated-measures ANOVA and multiple comparisons: ***p < 0.001, relative to time spent in CS+ before conditioning. For all charts, circles represent individual male mice and triangles represent female mice. NIC, Nicotine; VEH, vehicle.

E-liquid and nicotine preparations

E-liquid materials [Vegetable Glycerin (VG), Propylene Glycol (PG), NicSelect Nicotine (free-base; 100 mg/ml in VG), and Strawberry Flavor Concentrate (in PG)] were purchased from Liquid Barn. E-liquids were mixed in the laboratory to the desired concentration of nicotine and strawberry additive while maintaining a 50:50 ratio of VG/PG. The e-liquid was kept in the dark and made fresh every 3 d to prevent nicotine degradation. pH was not adjusted between solutions, but adding the flavor additive to the nicotine solution slightly lowered the pH of the e-liquid (Figs. 1, 2). For intraperitoneal nicotine injections, nicotine tartrate salt (Sigma-Aldrich) was dissolved in PBS to desired concentrations (0.03–0.1 mg/ml freebase nicotine). When the additive was added to PBS for injections, a concentrated nicotine stock solution was used to make both the nicotine only and nicotine plus additive injection solutions. The final injection solution was diluted with either PBS alone or PBS containing 5% strawberry additive (Liquid Barn) to ensure that nicotine concentration in the injection solutions was identical.

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Figure 2.

Strawberry additive does not affect nicotine CPP. Adolescent mice were conditioned to nicotine vapor with (2.5% strawberry flavorant) or without a strawberry additive using a CPP-biased protocol (nicotine only, n = 20, 24, 25; nicotine + additive, n = 16, 29, 30). Scatter plots represent individual mice, and bars represent the mean ± SEM. One-sample t tests (vs 0 s change in time spent in CS+): +p < 0.05, +++p < 0.001. Two-way ANOVA and multiple comparisons: *p < 0.05, **p < 0.01. For all charts, circles represent individual male mice and triangles represent female mice.

E-cigarette vapor delivery

E-liquid was vaporized using a Vapor Generator Controller (La Jolla Research) in conjunction with a SMOK Baby Beast Brother e-cigarette tank and V8 X-Baby-Q2 coils (0.4 Ω; SMOK). The Vapor Generator Controller was operated at 75.0 W using the preset “nicotine” settings in the system, which has the temperature set to 400°F. This machine has been previously validated for nicotine vapor delivery (Montanari et al., 2020; Cooper et al., 2021). For all vapor exposures (i.e., for cotinine quantification and for the conditioning phase of CPP experiments), the vapor “puff” from a single e-cigarette is diverted into four air-tight exposure apparatuses (dimensions = 5.25 × 5.25 × 5.625 inches) and is quickly replaced by clean room air via a vacuum (flow rate = 3.0 L/min; Fig. 1A, schematic). We delivered a 1 s puff every 90 s for a total of 25 min, resulting in a vapor period, which, in pilot experiments, we found was sufficient to allow the delivery of pharmacologically relevant doses of nicotine while delivering vapor in a puff-like pattern. This delivery pattern also provided sufficient time for the perception of the cues and the association of cues with the presence (or absence) of nicotine. The 25 min vapor delivery period is followed by a 5 min “washout” to protect experimenters from vapor inhalation. Therefore, mice are placed individually into one of the four exposure chambers for a total of 30 min per exposure. When vapor exposures were part of a conditioned place preference or aversion experiment, tactile and visual cues were added to the floor and to the outside of the clear Plexiglas chamber (Fig. 1C). Tactile cues comprised either rigid embroidery mesh in a grid pattern or flexible corrugated floors.

Cotinine quantification

To measure plasma cotinine (the primary metabolite of nicotine) concentrations in mice following nicotine exposures, trunk blood was collected 30 min following nicotine treatment. Thirty minutes postinjection has been previously shown to be the approximate time at which the maximum concentration of plasma cotinine is achieved in C57BL/6 mice (Siu and Tyndale, 2007), and pilot studies in our laboratory indicate that this is also true using our vapor delivery system (T. Patten, A. Dreier, M. De Biasi, unpublished observations). After blood collection and plasma separation, cotinine was quantified using a Mouse/Rat Cotinine ELISA kit according to package instructions (CALBIOTECH). Samples were diluted with purified, Milli-Q water when necessary to achieve a concentration of cotinine within the range of the standard curve that allowed for the most accurate cotinine quantification (10–50 ng/ml), and a pipetting variability of <15% was required for the inclusion of data. Samples that did not meet these requirements were reanalyzed. Cotinine values in diluted samples were calculated as follows: cotinine = cotinine_dilution * dilution factor.

Analyses of strawberry additive volatiles and e-liquid nicotine concentration

To identify major volatiles in the Strawberry Flavor Concentrate (Liquid Barn), headspace gas chromatography/mass spectrometry (GC/MS) analyses were conducted with a dynamic headspace analyzer (HT3 Automated Headspace Analyzer, Teledyne Tekmar) outfitted with a thermal desorption trap (Supelco Trap K Vocarb 3000 Thermal Desorption Trap, Sigma-Aldrich). The GC/MS (Trace Ultra, Thermo Fisher Scientific) was equipped with a single quadrupole mass spectrometer (Thermo Fisher Scientific) and a 30 m × 0.25 mm ID fused-silica capillary column (Stabiliwax-DA, Restek). The e-liquid additive solutions (0.1% in water) were subjected to dynamic headspace GC/MS analysis by placing 50 μl in a sealed 20 ml headspace vial. The vial was maintained at 30°C, swept with helium for 10 min (flow rate, 75 ml/min), and the volatiles were collected on the thermal desorption trap. Trap contents were desorbed at 260°C directly into the GC/MS using a split injection. The GC oven program had an initial temperature of 40°C (held for 3.0 min) followed by a ramp of 7.0°C/min to a final temperature of 230°C (held for 6.0 min). The MS was used in scan mode with a mass/charge ratio from 33 to 400 using a 3 min solvent delay. Mass spectral peak identifications were assigned based on the library search of the National Institute of Standards and Technology Standard Reference Database.

Nicotine vapor-conditioned place preference

The CPP procedure is divided into the following three phases: pretest, conditioning, and post-test (Fig. 1C). All phases of testing occurred during the dark cycle in either dim light (1–2 lux) or red light to prevent circadian rhythm disruption. During the pretest, mice were able to freely explore a testing chamber with two rooms containing identical cues (e.g., tactile, visual) and dimensions as the vapor exposure chamber (described in subsection E-cigarette vapor delivery) for 15 min. One chamber had the following cues: walls, black and white “bulls-eye” symbol; solid white, vertical black and white stripes; and solid black; and flooring: rigid white embroidery mesh in a grid pattern. The opposing chamber had the following cues: walls. black and white argyle pattern; solid blue, horizontal black and white stripes; and solid black; and flooring: flexible corrugated floors. CPP was conducted using a biased design (i.e., nicotine was assigned to the least preferred chamber). During the 5 d conditioning phase, mice received one CS+ (conditioned rewarded stimulus) and one CS– (conditioned unrewarded stimulus) conditioning session each day, in which they were placed in an exposure chamber individually with appropriate cues and received either control (50/50 VG/PG blend; vehicle) vapor, strawberry vapor, or nicotine with or without strawberry-flavored vapor. A control group received vehicle vapor in both compartments. A.M. and P.M. exposure sessions occurred ∼4 h apart. Following conditioning, mice were placed back into the testing chamber and allowed to freely explore both chambers for 15 min in a drug-free state. To avoid extreme bias skewing the results, mice showing strong innate preference (i.e., >65%) toward either compartment during the initial pretest were excluded.

Videos of both the pretest and post-test were recorded, and an experimenter blinded to the test stage (pretest or post-test) and the treatment group scored the time spent in each compartment, as well as the time spent climbing in the center region (unfocused). Preference scores were determined by comparing the time spent in the treatment-paired compartment (CS+) before and after conditioning with e-cigarette vapors (i.e., preference score = time in CS+ after conditioning – time in CS+ before conditioning), as this allows for a detection in the change in preference (for review, see McKendrick and Graziane, 2020).

Cotinine category determination

As the inclusion of the strawberry vapor increased nicotine intake (measured by cotinine plasma levels), thereby altering the dose of nicotine received, we sought to compare mice based on the actual level of nicotine exposure. “Cotinine categories” were objectively defined according to plasma cotinine concentrations following the injection of nicotine doses previously shown to be “subthreshold” (0.1 mg/kg), “rewarding” (0.3–0.5 mg/kg), and “aversive” (1.0 mg/kg) in rodents (Fudala et al., 1985; Jorenby et al., 1990; Torres et al., 2008). In our injection studies, mean ± SD plasma cotinine concentrations following a 0.3 mg/kg injection were 47.75 ± 19.05 ng/ml. We therefore set the lower threshold of the cotinine concentration defined as rewarding at 28.7 ng/ml (i.e., 1 SD below the average cotinine concentration of a rewarding 0.3 mg/kg nicotine injection). The upper threshold of rewarding plasma cotinine concentrations was set to 91.35 ng/ml, 1 SD above the average cotinine concentration following a rewarding 0.5 mg/kg, intraperitoneal (i.p.) nicotine injection, thereby ensuring that we captured a large range of cotinine values associated with a rewarding dose of nicotine. Subthreshold cotinine concentrations were determined to be anything below the rewarding threshold (i.e., <28.7 ng/ml), and aversive cotinine concentrations were defined as cotinine concentrations above the rewarding threshold (<91.35 ng/ml).

Plethysmography

E-liquids were prepared as above, and their volatile odors were presented to the mice through an air dilution olfactometer (Fig. 4A). During experimentation, all stimuli were contained in 40 ml glass headspace vials at room temperature. Odors were mixed with medical-grade nitrogen (Airgas) passed through headspace vials at a flow rate of 50 ml/min, following which they were mixed with a carrier stream of clean, filtered room air (1 L/min; Tetra Whisper air filter) before being introduced into the plethysmograph. All odors were handled within independent tubing to prevent cross-contamination.

To monitor the respiration of mice in response to e-cigarette odors, we used whole-body plethysmography and a computer-controlled olfactometer (Johnson et al., 2020). The unrestrained whole-body plethysmograph (Data Sciences International) allowed for the detection of respiratory transients as mice freely explored the chamber. Transients were detected using a flow transducer (Data Sciences International) and digitized at 300 Hz (bandpass filter, 0.1–12 Hz; Synapse software, Tucker Davis Technologies), following a 500× gain amplification (CYGNUS Technologies). The olfactometer allowed for precise control of odor delivery into the plethysmograph chamber (Fig. 4B). User-initiated openings of valves (Parker Hannifin) via a computer and digital relay (LabJack) allowed for the flow of vapors into the bottom of the plethysmograph for perception by the mouse. Following each stimulus trial, odor-vaporized air was passively cleared from the plethysmograph through an exhaust outlet at the ceiling of the chamber since the filtered room air is continuously delivered.

Mice were acclimated to the plethysmograph for 2 d before testing. During acclimation, mice were placed in the plethysmograph for 30 min and vehicle solution (50/50 VG/PG) was presented for 10 s each with a 60 s intertrial interval (ITI). The goal of this was to allow the mice to acclimate to handling, the chamber, and other possible nonolfactory cues (e.g., pressure changes, sounds) associated with valve opening and airflow. The day following this acclimation, mice were exposed to e-cigarette odors. On this day, first VG/PG was presented for 10 s with a 60 s ITI to further acclimate the mouse to vapor delivery, followed by five trials of pseudorandom presentations of 2.5% strawberry, 10 mg/ml nicotine ± 2.5% strawberry, and 50 mg/ml ± 2.5% strawberry. Each odor was presented for 10 s with a 90 s ITI.

Inhalation peaks were detected offline in Spike2 (Cambridge Electronic Design). First, the respiratory data were filtered (bandpass filter, 0.1–12 Hz). Second, the maximum point of each respiratory cycle was identified, and instantaneous frequency was then calculated based off of the duration between one peak and its preceding peak. Data were downsampled to 50 Hz for subsequent analyses. Although the odor valves were open for 10 s, the first second was excluded from analysis to account for the latency of odor delivery to the plethysmograph (Fig. 5B) and unavoidable pressure artifacts (Fig. 5C). We calculated the average instantaneous frequency over the remaining 9 s of each odor presentation to quantify odor-evoked sniffing. Amplitude was calculated based on the root mean square of the respiratory signal.

Statistical analyses

All datasets were tested for normality using the D’Agostino–Pearson test before selecting appropriate methods of analysis (nonparametric vs parametric). Nonparametric data (i.e., data that were not normally distributed) were analyzed using Mann–Whitney and Wilcoxon tests, and the Scheirer–Ray–Hare test—an extension of the Kruskal–Wallis test that allows for a factorial design—was used to detect interactions. The parametric tests used in this study include t tests and fixed-effects one and two-way Analysis of Variance (ANOVAs). Summary data is represented in figures as the mean +/− the standard error of the mean (SEM). GraphPad Prism was used for all data analyses except the Scheirer–Ray–Hare test, which was conducted using the Real Statistics Add-In for Microsoft Excel. In all figures, asterisks (*) indicate a significant difference from a comparison group, a plus sign (+) indicates a significant difference from 0 (0 s change from pretest; no change in preference from baseline). Mice were excluded from CPP experiments in one of two instances: 20% of screened mice (n = 39 of 194) showed a strong initial preference (>65%) for a particular compartment during the pretest, and two mice climbed out of the apparatus during the pretest or post-test. Sufficient numbers of mice of each sex were used to detect sex effects in behavioral tests (∼7) and in cotinine quantification experiments (∼5) when possible. Sex differences were always investigated using ANOVAs; data were collapsed across sex when a significant difference between sexes was not identified. Final sample sizes are included in the figure legends.