Introduction The distribution of nicotine among its free-base (fb) and protonated forms in aerosolised nicotine affects inhalability. It has been manipulated in tobacco smoke and now in electronic cigarettes by the use of acids to de-freebase nicotine and form ‘nicotine salts’.
Methods Measurements on electronic cigarette fluids (e-liquids) were carried out to determine (1) the fraction of nicotine in the free-base form (αfb) and (2) the levels of organic acid(s) and nicotine. Samples included JUUL ‘pods’, ‘look-a-like/knock-off’ pods and some bottled ‘nicotine salt’ and ‘non-salt’ e-liquids.
Results αfb= 0.12 ±0.01 at 40°C (≈ 37°C) for 10 JUUL products, which contain benzoic acid; nicotine protonation is extensive but incomplete.
Discussion First-generation e-liquids have αfb ≈ 1. At cigarette-like total nicotine concentration (Nictot) values of ~60 mg/mL, e-liquid aerosol droplets with αfb≈ 1 are harsh upon inhalation. The design evolution for e-liquids has paralleled that for smoked tobacco, giving a ‘déjà vu’ trajectory for αfb. For 17th-century ‘air-cured’ tobacco, αfb in the smoke particles was likely ≥ 0.5. The product αfbNictot in the smoke particles was high. ‘Flue-curing’ retains higher levels of leaf sugars, which are precursors for organic acids in tobacco smoke, resulting in αfb ≈ 0.02 and lowered harshness. Some tobacco cigarette formulations/designs have been adjusted to restore some nicotine sensory ‘kick/impact’ with αfb≈ 0.1, as for Marlboro. Overall, for tobacco smoke, the de-freebasing trajectory was αfb ≥ 0.5 → ~0 →~0.1, as compared with αfb= ~1 →~0.1 for e-cigarettes. For JUUL, the result has been, perhaps, an optimised, flavoured nicotine delivery system. The design evolution for e-cigarettes has made them more effective as substitutes to get smokers off combustibles. However, this evolution has likely made e-cigarette products vastly more addictive for never-smokers.
- electronic nicotine delivery devices
- tobacco industry
- harm reduction
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Nicotine can exist in a free-base (fb) form and in two protonated forms (figure 1). For electronic cigarette fluids (e-liquids) and the aerosolised droplets created therefrom, both the total nicotine concentration (Nictot) and the fraction of nicotine in the free-base form (αfb) can vary.1 Fb nicotine is volatile and gaseous fb nicotine is directly sensable. Protonated nicotine is not volatile and so has been referred to in the tobacco industry as ‘bound nicotine’.2 First-generation e-liquids were simply fb nicotine dissolved in a mix of propylene glycol (PG) and/or glycerol (GL), with αfb=1, and Nictot in the range of 6–24 mg/mL. In comparison, in the droplets making up tobacco smoke particulate matter (PM), Nictot values are typically much higher (~60 mg/mL).3 Electronic cigarette (e-cigarette) aerosols with high values of the product αfbNictot can be expected to be harsh upon inhalation, as with αfb = 1 and Nictot = 60 mg/mL.1 Non-harsh cigarette-like nicotine levels in aerosolised e-liquids therefore require αfb << 1. This can be achieved by the addition of an acid to the PG/GL/nicotine mix, for example, benzoic acid, as in the JUUL product line.
Given the large market share quickly achieved by JUUL4 5 and its youth-oriented e-cigarette demographic,6 the goal of this work was to determine αfb values and acid levels in the e-liquids from JUUL and look-a-like/knock-off product7 competitors, available as of October 2018, and thereby characterise the use of acid additives to moderate fb nicotine delivery, and thus harshness, while maintaining high total nicotine delivery. The measured αfb values were compared with those for first-generation e-cigarette products. The first-generation e-cigarette → JUUL trajectory is compared with that for the smoke aerosol from colonial-era air-cured tobacco → flue-cured tobacco (1850s forward) → the modern Marlboro cigarette. The measurements were carried out by application of 1H NMR spectroscopy (hereafter, NMR).1 8 9 As outlined by Duell et al,1 NMR is a method that allows the reliable determination of αfb values in e-liquids without any alteration of the sample, for example, without water addition, which changes nicotine protonation chemistry. The e-liquid results are examined in the context of the acid+nicotine first protonation equilibrium constant.
Nicotine protonation and αfb
Predicting the extent of nicotine protonation (including αfb10) in any solution requires knowledge of the governing acid/base concentrations and their medium-dependent equilibrium constants. Fully protonated nicotine carries two protons (figure 1) with acidity constants (=Ka,1) and (=Ka,2). Measurement of Ka values in tobacco smoke and e-liquids is very difficult but relatively easy in water. In water, reported values at 25°C are =8.01 and =3.10.11 At 37°C, the values are 7.65 and 2.77, respectively.12 In water, pH≤4 is required for significant (≥10%) .
When conditions are such that there is not an equivalent excess of acid over nicotine (so that total molar-based concentration of monoprotic acid (CHA)/total molar-based concentration of nicotine (CNic) is ≤ 1), or the protonating acid is weak for the medium, can be neglected and the dominant protonation of fb nicotine (Nic) occurs according to
The diprotonated form may not be negligible for all e-liquids, including some non-JUUL high-acid brands examined experimentally here. Each bracketed term in equations (1) and (2) is a molar concentration (and not a chemical activity) so that and all the other K values herein are constant-medium-type equilibrium constants, analogous to cK values as discussed by Pankow,13 and dependent on the nature of the particular solution medium.
Net protonation reaction
In a liquid medium (eg, the PG/GL matrix and water), the acid dissociation reaction of an acid, HA (eg, benzoic acid and acetic acid), is
The overall reaction for monoprotonation of Nic by HA is given by equations (1) + (3), so that
Koa,1 is dimensionless because both the forward and backward reactions are bimolecular: any mol-proportional concentration scale can be used. For water, Koa,1 values for different acids can be calculated; values and values for many important acids are individually well known because pH is easily measured in water: at 37°C, for benzoic acid and vanillin (a common e-liquid flavour additive), =4.20 and 7.27, respectively.14 For these two acids with nicotine in water at 37°C, then Koa,1=103.45 and 100.38, respectively. In contrast, in PG and GL, either individually or as a mixture, and values for relevant acids are unknown. The species H+, however, does not appear in equation (4), and so Koa,1 values can be directly measured in PG and GL solutions/mixtures.
Let CHA and CNic be the total molar-based concentrations of HA and nicotine as initially added to a PG/GL solution. (CNic and Nictot are proportional; Nictot has units of mg/mL.) Neglecting formation of the diprotonated species, establishment of a reaction equilibrium will lead to protonation such that [NicH+]=[A–]=x:
so that αfb= (CNic – x) / CNic . Because the reaction is bimolecular and Koa,1 is dimensionless, for any mass concentration of total nicotine, we can set CNic = 1 and CHA = CHA/CNic. Then , and
When Koa,1 and CHA/CNic are known, then equation (6) can be solved for either numerically or by the quadratic equation. For the latter, a = Koa,1–1, b = (Koa,1CHA/CNic– Koa,1+2), and c = –1; the root is chosen so that > 0. Cases involving Koa,1=1 are not second order (a=0), and so reduce to =1/(1+CHA/CNic). When protonation is favoured, the reliability of equations (5-6) will decrease for CHA/CNic > 1 due to an increasing importance of . For the special case of CHA/CNic = 1, then
NMR determinations of αfb, nicotine and acid concentrations
JUUL e-liquid ‘pods’ were purchased from JUUL. Other pod brands (ZOOR, SMPO, Myle, ZiiP and Eon Smoke) and bottles of e-liquids (Fuzion Vapor) were purchased from online suppliers. Bottles of ‘nicotine salt’ e-liquids (Salt Bae50 and Pacha Mama Salts) were purchased from a vape shop in Portland, Oregon. Glacial acetic acid was obtained from Mallinckrodt Chemicals (Staines-upon-Thames, England). Tertbutylamine (98%) was obtained from Sigma-Aldrich (St. Louis, Missouri, USA). DMSO-d6, D 99.9%, was obtained from Cambridge Isotope Laboratories (Andover, Massachusetts, USA). Precision coaxial NMR inserts (WGS-5BL-SP and WGS-5BL) and precision NMR tubes (535-PP-7) were purchased from Wilmad (Vineland, New Jersey, USA).
Monoprotonated and fb nicotine standards, which were used to calculate the fb nicotine fraction in each sample, were prepared by adding acetic acid or tertbutylamine to the e-liquids until the limiting NMR chemical shifts were achieved. In the present study, standards were prepared using the following commercial e-liquids: ‘Mango’-flavoured JUUL, ‘Apple’-flavoured ZOOR, ‘Cake’-flavoured ZOOR and ‘Blue Raspberry Lemonade’-flavoured Salt Bae50. In our previous work, standards were prepared from nicotine-containing PG/GL samples rather than actual commercial e-liquids, resulting in small differences in the αfb values reported here. Various commercial e-liquid standards were prepared because dissimilarities in the e-liquid compositions (such as the presence of benzoic acid or levulinic acid) can result in slightly different limiting chemical shifts for the monoprotonated and fb nicotine reference samples. Appropriate reference samples were matched to the tested commercial e-liquids by using the most similar compositions as determined by analysis of 1H NMR spectra. In particular, this was executed by matching samples and reference standards containing the same primary acid(s) (if present), that is, benzoic acid or levulinic acid. Details for the references used for each sample can be found in online supplementary table S-1. αfb was calculated using the difference between the chemical shifts of two aromatic nicotine protons and the nicotine methyl resonance, respectively. The average was then calculated (±the difference between the two values divided by 2).1
Concentric tube samples containing each e-liquid were prepared for αfb analyses per previous methods,1 and samples containing a single drop of each e-liquid in 500 µL of DMSO-d6 were used for composition analysis, owing to the better shim that can be achieved with a lower sample concentration. A 600 MHz NMR spectrometer was used to execute zg30 1H experiments using parameters reported previously and heteronuclear single quantum coherence spectroscopy (HSQC) experiments, as needed.1 Thus, each e-liquid sample was placed in a precision coaxial NMR insert and the lock solvent, DMSO-d6, was placed in the outer 5 mm NMR tube. 1H NMR experiments were conducted using a TXI (“Triple Resonance”) probe and at 40°C in order to increase the molecular tumbling rate, improving the shim. Sixteen scans were collected using the zg30 pulse sequence; a relaxation delay (D1) of 3 s between each scan was used; the size of the real spectrum (TD) was 65 536 data points; and the spectral width (SW) was 15 ppm, with the transmitter frequency offset (O1P) set to 6 ppm, giving a total experiment time of 2 min per sample.
Spectra for composition determinations were assessed using integration analysis. After phasing and baseline correction, the chemical components (eg, PG, GL, nicotine, and benzoate or levulinate) were analysed using the resonance(s) with the least overlap. The resulting integrations were used to calculate the mole per cent of each component, which was then used to calculate the weight per cents (wt%). Other details about the calculation of αfb have been reported previously,1 except with a modification to the fb and monoprotonated nicotine standards used as described above.
Based on equation (6), values of Koa,1 were determined for benzoic acid at 40°C in 43/57 PG/GL by weight (48/52 by mol). The mixture was amended with benzoic acid and nicotine to give CHA=3.31×10−4 mol/mL and CNic=3.28×10−4 mol/mL (CHA/CNic=1.01, nicotine at 4.6 wt%). A second mixture was prepared with a PG/GL ratio of 32/68 by weight (36/64 by mol) (similar to that currently represented by JUUL) and amended with benzoic acid to give CHA=3.38×10−4 mol/mL and nicotine at CNic=3.30×10−4 mol/mL (CHA/CNic=1.03, nicotine 4.6 wt%). To investigate the effects of water on nicotine protonation, an aliquot of the second mixture was amended with water at 5% (by volume). Values of Koa,1 were also calculated for benzoic acid at 40°C based on the data for the JUUL products in table 1, with CHA/CNic≈ 1, as verified here by a liquid chromatography (LC) method discussed elsewhere.15 1H NMR results gave slightly different CHA:CNic ratios (online supplementary table S-1); because NMR spectra can be subject to resonance overlap in these cases, due to the presence of flavourants, the LC-determined CHA:CNic ratios were used for the calculations herein.
Koa,1 values were also determined for vanillin at 40°C in 45/55 PG/GL by weight (49/51 by mol). The mixture was amended with nicotine and three levels of vanillin. The three solutions were characterised by (1) CHA= 1.80×10−4 and CNic= 3.61×10−4 mol/mL (CHA/CNic= 0.50) (nicotine at 5.1 wt%), (2) CHA= 3.67×10−4 and CNic= 3.59×10−4 mol/mL (CHA/CNic= 1.02) (nicotine at 5.1 wt%) and (3) CHA= 5.15×10−4 and CNic= 3.41×10−4 mol/mL (CHA/CNic= 1.51) (nicotine at 4.9 wt%).
JUUL aerosol PM determinations
A fully charged JUUL device was equipped with a JUUL ‘Classic Menthol’ 5% nicotine pod and vaped using the CORESTA puff method (55 mL puff volume, 3 s long) and employed vaping methods described previously.16 17 The JUUL device (+e-liquid pod) was weighed before and after the generation of five puffs to obtain the mass of aerosol produced over the five puffs.
Protonation in e-liquids
Table 1 lists the measured (by 1H NMR) versus manufacturer-listed nicotine concentrations and the measured αfb values (online supplementary figure S-3 visually depicts the data in a bar chart). The e-liquids tested included those for JUUL pods, other look-a-like/knock-off pods, bottled nicotine salt e-liquids and early-generation (ie, non-salt) bottled e-liquids. The agreement between the listed and actual nicotine contents varied among brands; in this work, the measured values were used; online supplementary figure S-1 illustrates the differences among the e-liquids. Table 1 also gives CHA/CNic; the acids were fully identifiable by NMR for the first 14 e-liquids, and the presence of at least one acid was identified for the first 18 e-liquids. CHA/CNic values varied widely among the brands (see also online supplementary figure S-2). Online supplementary figure S-5 is a comparison of the 1H NMR spectra for two e-liquids with differing ratios of benzoic acid relative to nicotine; for one, CHA/CNic= ~1, and for the other, CHA/CNic= ~4.
Figure 2 is a plot of measured Nictot versus αfb. Lines of constant fb concentration as given by the product αfbNictot plot as hyperbolas (see also the issue cover graphic for Duell et al).1 All the e-liquids with CHA/CNic≈1 with benzoic acid were found to be characterised by similar αfb values (0.09–0.14). As noted earlier, the inhalation harshness of a nicotine aerosol is related to the fb concentration in the aerosol liquid, as given by αfbNictot. Values for αfbNictot can be computed from the data in table 1 (see also online supplementary figure S-4). Bookending these values, e-liquids with CHA/CNic>> 1 gave αfb~0, and some e-liquids that were not marketed as nicotine salts gave αfb values as high as 0.98.
Besides carboxylic acids (eg, benzoic acid and levulinic acid) as protonating agents, the prevalent flavour phenols vanillin and ethyl vanillin can contribute to protonation of nicotine; these two weak acids can be found at high concentrations in some e-liquids.18 Such an effect on αfb may be indicated in the αfb values for the ‘Roundhouse with Cream’ flavour formulations for two different Nictot values, 33 and 6 mg/mL, with αfb=0.70 and 0.08, respectively. Assuming a constant phenol flavourant level, the lower αfb for the lower nicotine-level may have been caused in part by a higher total acids:nicotine ratio.
The Koa,1 values (40°C ≈ 37°C) obtained here are provided in table 2. For benzoic acid, values were determined in JUUL liquids and in two laboratory-prepared mixtures (with added ~1:1, by mol, benzoic acid:nicotine): 43/57 PG/GL and 32/68 PG/GL (similar to JUUL) by weight. The average Koa,1 value for the JUUL e-liquids tested was 67, which is within a factor of 3 of Koa,1 for 43/57 PG/GL by weight, where Koa,1=26 and with Koa, 1 for 32/68 PG/GL by weight, where Koa,1=31. When 5 vol% water was added to the 32/68 PG/GL (by weight) mixture, Koa,1=51; this sample may be the most comparable to the JUUL liquids, which contain some water. For vanillin in ~45/55 PG/GL by weight, Koa,1 averaged 0.0089, about 6000 times smaller than that for benzoic acid. (At constant CNic, the Koa,1 values for vanillin may indicate some tendency to increase with an increasing CHA:CNic ratio; an increasingly ionic medium would be expected to favour the HA+Nic=A–+NicH+ reaction, due to Debye-Hückel effects.)
JUUL aerosol PM determinations
The average mass lost per puff, for five puffs, was 4.4 mg, which when divided by the puff volume (55 mL) results in an average aerosol PM of ~80 mg/L, or 80×106 µg/m3. This is only slightly greater than the high end of the range for tobacco cigarettes, from 13 to 63×106 µg/m3.19
Past was prologue: Vu – tobacco smoke
The chemistry changes during the rapid evolution of e-cigarettes closely parallel the events that occurred during the centuries-long development of smoked tobacco. The tobacco that the English colony of Jamestown in Virginia exported to England beginning in 1619 was dark, ‘air-cured’ tobacco. Air curing occurs by slow drying (6–8 weeks) in ventilated barns. Air-cured (aka ‘dark’, ‘brun’, ‘black’)20 21 tobacco generally produces tobacco smoke that is much more basic than other tobacco types.20 22 Leaf sugars, which are precursors of tobacco-smoke organic acids, are generally lost during slow air curing; it is this loss that accounts for the relatively high proportions of fb nicotine in the smoke aerosol droplets from air-cured tobacco23 (figure 3). Regardless of smoke basicity/acidity, most tobacco smoke nicotine is in the smoke PM, distributed among the fb and protonated nicotine forms.10
Nicotine-related harshness of tobacco smoke has long been viewed as being correlated with smoke basicity, with basicity favouring PM nicotine being in the volatilisable and therefore sensable (harsh) fb form. Consider:
‘…The presence of unprotonated nicotine in the smoke of French cigarettes and the observation that French smokers of black tobacco inhale less frequently than smokers in England and the USA … support our hypothesis that the pH is a determining factor in the “inhalability” of tobacco smoke’.20
‘…increasing the pH … introduces a smoke with high physiological impact and a harsh bite, which would seem to offset the advantages gained from increased nicotine’.24
‘Flue-cured’ (aka ‘bright’) tobacco was developed in the 1850s after the accidental discovery that rapid drying with heat yields a bright yellow leaf that produces a noticeably milder smoke.25–27 Indeed, flue-cured tobacco remains high in leaf sugars so that the resulting smoke contains numerous organic acids.22 27 While historical measurements of ‘smoke pH’ both inside and outside the industry were indisputably flawed in absolute terms, within a given protocol (eg, the ‘pH electrode’ method), relative comparisons have likely been meaningful, so it is relevant that ‘smoke pH’ was found by the industry to be strongly negatively correlated with both leaf sugar levels and leaf sugar/leaf nicotine ratios.28 In 1970, Armitage and Turner29 wrote:
‘It is usually believed that the majority of cigarette smokers inhale to varying degrees the smoke which they take into their mouths, whereas the majority of cigar smokers do not…. One of the most striking differences between cigarette and cigar smoke is the pH of the smoke. The pH of T 29 cigarettes by the method of Grob…was 5.35, whereas the pH of the C 1 cigars was 8.5’.29
Overall, as compared with tobacco smoke from air-cured tobacco, for flue-cured tobacco, the fraction of the PM nicotine in the fb form is much lower. The role of acids in converting nicotine to a protonated, ‘salt’ form in tobacco smoke has long been understood. In 1909, Garner23 wrote:
‘Apparently the only possible explanation of this pronounced effect on the sharpness of the smoke is that in the presence of the citric acid the nicotine enters the smoke in the form of a salt rather than in the free state, and thereby loses its pungency while still exerting the usual physiological effect’.23
Modern measurement of αfb values in cigarette smoke PM began ~15 years ago.3 30 In ‘American blend’ cigarettes, flue-cured tobacco dominates. Thus, in measurements with tobacco smoke PM from nine commercial brands of cigarettes sold in the USA, Pankow et al3 reported relatively low αfb values, ranging between ~0.01 (GPC) and ~0.10 (Marlboro). Two other, atypical commercial brands gave higher αfb values: Gauloises Brunes (relatively high in air-cured tobacco) at αfb= 0.25 and American Spirit/Maroon at αfb=0.36.3 Overall, together with historical evidence, it can be concluded that air-cured tobacco was characterised by very high αfb values (≥0.4 and perhaps ≥0.5).
Figure 3 summarises the main tobacco product development stages: (1) Aerosol PM produced from smoked tobacco products in the early 1600s contained high levels of fb nicotine and so was harsh on inhalation; the αfb in the PM was likely greater than 0.5. (2) Flue-curing allowed retention of plant acids in the leaf during the curing process, bringing αfb values in smoke PM to ~0.01 (very mild). (Note here that Proctor has aptly commented that manufacturers of cigars giving high fb smoke might similarly make their products more inhalable by adding acids, a process that he has termed ‘de-freebasing’.27) (3) For Marlboro, by using additives and/or blend manipulation31 32 to accomplish a Goldilocks principle solution (ie, not too harsh, not too mild), αfb was brought to ~0.1 for a tolerable/desired level of impact/harshness. Consider, by analogy, human affinity for the sensory ‘bite’ of carbonated beverages.33 Much has been written on the technical efforts of Philip Morris and its competitors to understand and provide some nicotine ‘impact’.31 32Overall, the tobacco smoke trajectory wasαfb≥0.5→~0→~0.1.
Present: ‘Déjà Vu’ – e-cigarette aerosols
Stepanov and Fujioka34 were the first to consider the acid/base chemistry of nicotine in e-liquids. Most early versions of e-cigarettes used PG/GL-based fluids with total nicotine levels of 6–24 mg/mL and αfb ≈ 1 (nicotine+PG/GL is characterised by αfb ≈ 1).16 It has been verified that such e-liquids correspondingly generate e-cigarette aerosol PM with αfb≈ 1.16 When e-liquids including some acid and their resulting aerosol PM are compared, total nicotine levels have been found to be similar,1 35 as have the αfb values.1 Following our prior work,1 the product αfbNictot can be used to compare e-liquid fb delivery values, with JUUL products having been found to be de-freebased to αfb≈ 0.1.
Cigarette smoke PM generally contains nicotine levels that are much higher than those in early e-liquids. Assuming unit density for cigarette smoke PM, values of ~54 mg/mL for the GPC brand and 72 mg/mL for Marlboro (‘red’) have been reported.3 If e-cigarettes were to attempt cigarette-like nicotine levels along with αfb≈ 1, then with αfbNictot≈ 50–70 mg/mL, the aerosol would be expected to be exceedingly harsh on inhalation. Enter JUUL, which was launched in 2015, offering its nicotine+benzoic acid pods (5% (w/w) nicotine, ~59 mg/mL); table 1 (and the results of Pankow et al15) indicate a ≈1:1 molar ratio of benzoic acid to nicotine. As indicated earlier for Koa, 1= 38.5 (table 2), equation (8) then gives αfb= 0.14 (see therefore figure 3), so that αfbNictot≈ 8.3 mg/mL. This is very similar to what has been found for Marlboro cigarettes (αfbNictot ≈ 0.10×72 mg/mL = 7.2 mg/mL).3The trajectory for e-cigarettes has then been a partial de-freebasing according toαfb=~1→~0.1 (as compared with αfb≥ 0.5→ ~ 0 → ~0.1 for most smoked tobacco). Thus, taken with the PM results discussed earlier, the JUUL design characteristics provide effective cigarette-like delivery of nicotine, including (1) high total nicotine concentration in the liquid (Nictot, mg/mL); (2) low but not zero fb fraction (αfb); (3) cigarette-like concentrations of fb nicotine in the aerosol droplets (αfbNictot, mg/mL); and (4) relatively low, cigarette-like PM; along with (5) optional flavours and no tobacco-smoke odour: a flavoured (at present) e-cigarette analogue of Marlboro.
The trajectory in figure 3 for smoked tobacco allowed cigarettes to become much more addictive, abused, and deadly than would have been the case if smoked tobacco remained of an air-cured type. The evolution of e-cigarettes has followed a similar overall trajectory. It is undoubtedly true that this evolution has made e-cigarettes more effective as substitutes to get smokers off combustibles. However, exactly as occurred with smoked tobacco, this evolution has made e-cigarette products vastly more addictive for never-smokers. The full public health implications of widely prevalent e-cigarette use will only become fully apparent perhaps a decade hence.
What this paper adds
The chemistry of nicotine in aerosols from smoked tobacco and electronic cigarette (e-cigarette) products underlie their parallel product developments and popularities, and therefore their abuse liabilities.
The development over more than four centuries of smoked tobacco products (de-freebasing then partial re-freebasing) is compared with the development of e-cigarette products during the last 16 years (extensive but incomplete de-freebasing). An explanation is provided of what has been perceived by some as inconsistent that (1) tobacco companies during the mid-20th century were interested in increasing the value of the free-base nicotine fraction (by the partial re-freebasing step) in the products’ smoke aerosol particulate matter, denoted αfb, while (2) some e-cigarette manufacturers have moved to decrease it (by the extensive but incomplete de-freebasing).
Values of αfb are measured by 1H nuclear magnetic resonance spectroscopy for a total of 29 products, including JUUL, JUUL look-a-like/knock-off products, as well as bottles of ‘nicotine salt’ and ‘non-salt’ e-liquids.
The overall trajectory of smoked tobacco development is discussed as having been αfb ≥ 0.5 → ~0.02 → ~0.1. A ‘Déjà Vu’ trajectory of αfb≈ 1 → ~0.1 has been followed in the design of the nicotine-containing liquids used in e-cigarettes, as supported by the measurements of αfb.
A mathematical framework and equilibrium chemistry model are developed for understanding nicotine protonation chemistry in e-cigarette fluids in terms of Koa,1, the first overall nicotine protonation constant.
De-freebasing has undoubtedly made e-cigarettes more effective as substitutes to get smokers off combustibles. However, as with smoked tobacco, it is likely that e-cigarettes have also been made vastly more addictive for never-smokers. The full public health implications of widely prevalent e-cigarette use will only become fully apparent perhaps a decade hence.
We thank Dr Wentai Luo and Kevin McWhirter for their assistance with high-performance liquid chromatography determinations of the benzoic acid:nicotine ratio in JUUL products.
Contributors AKD carried out the experimental work; JFP conceived the work; and DHP directed the work. All authors contributed to the writing of the manuscript.
Funding This work was supported by the US National Institutes of Health (grant R01ES025257). Research reported was supported by the National Institute of Environmental Health Sciences and the Food and Drug Administration Center for Tobacco Products.
Disclaimer The content is solely the responsibility of the authors and does not necessarily represent the views of the NIH or the FDA.
The quote in the title has been attributed to Yogi Berra.
Competing interests None declared.
Patient consent for publication Not required.
Provenance and peer review Not commissioned; externally peer reviewed.
Data availability statement All data relevant to the study are included in the article or uploaded as supplementary information.
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