Simultaneous analysis of nicotine,nicotine metabolites,and tobacco alkaloids in serum or urine by tandem mass spectrometry,with clinically relevant metabolic profiles

BACKGROUND: Assessment of nicotine metabolism and disposition has become an integral part of nicotine dependency treatment programs. Serum nicotine concentrations or urine cotinine concentrations can be used to guide nicotine patch dose to achieve biological concentrations adequate to provide the patient with immediate relief from nicotine withdrawal symptoms, an important factor in nicotine withdrawal success. Absence of nicotine metabolites and anabasine can be used to document abstinence from tobacco products, an indicator of treatment success. METHODS: The procedure was designed to quantify nicotine, cotinine, trans-3'-hydroxycotinine, anabasine, and nornicotine in human serum or urine. The technique required simple extraction of the sample with quantification by HPLC-tandem mass spectrometry. RESULTS: The procedure for simultaneous analysis of nicotine, its metabolites, and tobacco alkaloids simultaneously quantified five different analytes. Test limit of quantification, linearity, imprecision, and accuracy were adequate for clinical evaluation of patients undergoing treatment for tobacco dependency. The test readily distinguished individuals who had no exposure to tobacco products from individuals who were either passively exposed or were abstinent past-tobacco users from those who were actively using a tobacco or nicotine product. CONCLUSIONS: Nicotine, cotinine, trans-3'-hydroxycotinine, nornicotine, and anabasine can be simultaneously and accurately quantified in either serum or urine by HPLC-tandem mass spectrometry with imprecision <10% at physiologic concentrations and limits of quantification ranging from 0.5 to 5 micro g/L. Knowledge of serum or urine concentrations of these analytes can be used to guide nicotine replacement therapy or to assess tobacco abstinence in nicotine dependency treatment. These measurements are now an integral part of the clinical treatment and management of patients who wish to overcome tobacco dependence.     

Determination of nicotine and its major metabolite cotinine in plasma or serum by gas chromatography-mass spectrometry using ion-trap detection.

A specific method has been developed for the quantitative determination of nicotine and its major metabolite cotinine in plasma or serum of active and passive smokers. Deuterium-labelled nicotine and cotinine were used as internal standards. The amounts of nicotine and cotinine present in a sample of plasma or serum were extracted with a simple extraction procedure (liquid-liquid or solid-phase extraction). The extracts were analysed by gas chromatography coupled with mass spectrometry using ion-trap detection. The analysis was done in positive chemical ionisation with methanol as the liquid reagent. The method has been demonstrated to be linear up to 1000 microg/l. Limits of quantification for nicotine and cotinine are 10 and 5 microg/l, respectively with liquid-liquid extraction, and 1 microg/l for each of the compounds with solid-phase extraction. The present method has been applied to several real cases.     

Female sex and oral contraceptive use accelerate nicotine metabolism

BACKGROUND: Several studies have reported that female smokers have a higher risk of lung cancer than male smokers. This could be related to sex differences in nicotine metabolism and related smoking behavior. This study tested the hypothesis that women metabolize nicotine more rapidly than men and that, among women, oral contraceptive users metabolize nicotine more rapidly than nonusers of oral contraceptives. METHODS: Two hundred seventy-eight healthy volunteers who were twins and 16 who were siblings of twins, recruited from the Northern California Twin Registry, received an infusion of deuterium-labeled nicotine and cotinine with frequent blood sampling. The plasma clearances of nicotine and cotinine, the clearance of nicotine to cotinine (an index of cytochrome P450 [CYP] 2A6 activity), and the ratio of trans-3'-hydroxycotinine to cotinine (another indicator of CYP2A6 activity) were measured. RESULTS: The clearances of nicotine and cotinine, the clearance of nicotine to cotinine, and the trans-3'-hydroxycotinine/cotinine ratio were significantly higher in women than in men (nicotine clearance, 15.6 +/- 4.3 mL.min(-1).kg(-1) in men versus 18.8 +/- 6.6 mL.min(-1).kg(-1) in women; P < .001); they were also higher among women taking oral contraceptives than in those who were not taking oral contraceptives (nicotine clearance, 22.5 +/- 6.6 mL.min(-1).kg(-1) in women taking oral contraceptives versus 17.6 +/- 6.1 mL.min(-1).kg(-1) in those who were not; P < .05). Women who were menopausal or postmenopausal were not different from men. Among oral contraceptive users, nicotine metabolism was accelerated among those taking combined and estrogen-only contraceptives but not progesterone-only contraceptives. CONCLUSIONS: Sex hormones influence nicotine metabolism. Nicotine and cotinine metabolism is faster in women than in men and is faster in women taking oral contraceptives compared with those who are not. Accelerated nicotine metabolism appears to be a result of estrogen. Sex-related differences in nicotine clearance could affect smoking behaviors, as well as response to nicotine medications, and could be a marker for altered metabolism of nicotine-derived carcinogens.     

Effects of cigarette smoking and carbon monoxide on nicotine and cotinine metabolism

OBJECTIVES: To examine the effects of cigarette smoking on the disposition kinetics of nicotine and cotinine, to determine the effects of cigarette smoking on pathways of nicotine and cotinine metabolism, and to test the hypothesis that carbon monoxide inhibits the metabolism of nicotine. STUDY DESIGN: Twelve cigarette smokers were studied in three treatment conditions, each lasting 7 days, during which they smoked cigarettes, breathed carbon monoxide to achieve carboxyhemoglobin levels similar to cigarette smoking, or breathed air. In each treatment condition, subjects received a combined infusion of deuterium-labeled nicotine (d2) and cotinine (d4), with measurement of disposition kinetics and urine metabolite profile. RESULTS: Cigarette smoking significantly inhibited the metabolism of nicotine but had no effect on cotinine metabolism. Cigarette smoking markedly induced the O-glucuronidation of trans-3'-hydroxycotinine but had no effect on the N-glucuronidation of nicotine or cotinine. Carbon monoxide had no effect on nicotine or cotinine kinetics or metabolic profile. CONCLUSIONS: This study confirms previous observations that cigarette smoking inhibits nicotine metabolism but disproves the hypothesis that this effect is due to carbon monoxide. Induction of glucuronidation must be considered in understanding the effects of cigarette smoking on drug metabolism.     

Liquid-chromatographic determination of nicotine and cotinine in urine from passive smokers: comparison with gas chromatography with a nitrogen-specific detector

We describe a simple, sensitive, and specific high-performance liquid-chromatographic method with ultraviolet detection (256 nm) for the simultaneous analysis of nicotine and cotinine in urine of passive smokers. The analytes are extracted and purified from the complex and impure matrix in two stages; first, by liquid-liquid extraction and followed by solid-phase extraction (C2 column). We used a "DB" C8 5-microns-particle column (25 x 0.46 cm) and a mobile phase of phosphate-citrate buffer and acetonitrile (91:9 by vol) containing 5 mL of triethylamine and 600 mg of heptanesulfonate per liter, adjusted to pH 4.4, to separate the compounds. Two internal standards (2-phenylimidazole and N-ethylnorcotinine) were used. The detection limit of the HPLC assay was less than 1 microgram/L for both analytes. The average interassay CV for nicotine was 7.6%, for cotinine 6.5%, in the concentration range 0-60 micrograms/L. The mean analytical recovery of nicotine with respect to the internal standard N-ethylnorcotinine was 102% and that for cotinine was 99%; the mean absolute recoveries of the compounds were as follows: nicotine 85%, cotinine 87%, and N-ethylnorcotinine 87%. To compare the HPLC assay results of 20 samples with the more-sensitive in-laboratory gas-chromatographic method with a nitrogen-phosphorus detector, we used both N-ethylnornicotine and N-ethylnorcotinine as internal standards. The mean correlation coefficient for nicotine values between the two methods was 0.934; for cotinine, 0.987.     

Inactivation of CYP2A6 and CYP2A13 during nicotine metabolism

Nicotine is the major addictive agent in tobacco. The primary catalyst of nicotine metabolism in humans is CYP2A6. However, the closely related enzyme CYP2A13 is a somewhat better catalyst. CYP2A13 is an extrahepatic enzyme that is an excellent catalyst of the metabolic activation of the tobacco-specific carcinogen 4-(methylnitrosamine)-1-(3-pyridyl)-1-butanone (NNK). Here we report that both CYP2A6 and CYP2A13 were inactivated during nicotine metabolism. Inactivation of both enzymes was dependent on NADPH and increased with time and concentration. Alternate substrates for CYP2A6 and CYP2A13 protected these enzymes from inactivation. Inactivation of CYP2A13 was irreversible upon extensive dialysis and seems to be mechanism-based. The K(I) of CYP2A13 inactivation by nicotine was 17 microM, the rate of inactivation, k(inact), was 0.1 min(-1), and the t(1/2) was 7 min. However, the loss in enzyme activity occurred after nicotine metabolism was complete, suggesting that a secondary or possible tertiary metabolite of nicotine may be responsible. [5-(3)H]Nicotine metabolism by CYP2A13 was monitored by radioflow high-pressure liquid chromatography during the course of enzyme inactivation; the major product was the Delta(1'(5'))iminium ion. However, cotinine was a significant metabolite even at short reaction times. The metabolism of the nicotine Delta(1'(5'))iminium ion to cotinine did not require the addition of aldehyde oxidase. CYP2A13 catalyzed this reaction as well as further metabolism of cotinine to 5'-hydroxycotinine, trans-3'-hydroxycotinine, and N-(hydroxymethyl)-norcotinine as enzyme inactivation occurred. Studies are on-going to identify the metabolite responsible for nicotine-mediated inactivation of CYP2A13.     

Nicotine metabolite ratio predicts efficacy of transdermal nicotine for smoking cessation

BACKGROUND: Nicotine is metabolized to cotinine, and cotinine is metabolized to 3'-hydroxycotinine (3-HC) by the liver enzyme cytochrome P450 (CYP) 2A6. More rapid metabolism of nicotine may result in lower nicotine blood levels from nicotine replacement products and poorer smoking cessation outcomes. This study evaluated the utility of the 3-HC/cotinine ratio as a predictor of the efficacy of nicotine replacement therapy as an aid for smoking cessation. METHODS: By use of an open-label design, 480 treatment-seeking smokers were randomly assigned to 8 weeks of transdermal nicotine or nicotine nasal spray use, plus behavioral group counseling. Assessments included demographics, smoking history, body mass index, and plasma nicotine, cotinine, and 3-HC concentrations, as well as CYP2A6 genotypes. Smoking cessation was biochemically verified at the end of treatment and at 6-month follow-up. RESULTS: The rate of nicotine metabolism, as indicated by pretreatment 3-HC/cotinine ratio derived from cigarette smoking, predicted the effectiveness of transdermal nicotine at both time points. The odds of abstinence were reduced by almost 30% with each increasing quartile of metabolite ratio (odds ratio, 0.72 [95% confidence interval, 0.57-0.90]; P=.005). Higher metabolite ratios also predicted lower nicotine concentrations (beta=-1.72, t(179)=-3.31, P<.001), as well as more severe cravings for cigarettes after 1 week of treatment (beta=0.32, t(190)=2.91, P=.004). The metabolite ratio did not predict cessation with use of nicotine nasal spray (odds ratio, 1.05 [95% confidence interval, 0.83-1.33]; P=.68). CONCLUSION: The nicotine metabolite ratio might be useful in screening smokers to determine likely success with a standard dose of transdermal nicotine.     

Analysis of nicotine, 3-hydroxycotinine, cotinine, and caffeine in urine of passive smokers by HPLC-tandem mass spectrometry

BACKGROUND: A method is described for the simultaneous analysis of nicotine and two of its major metabolites, cotinine and 3-hydroxycotinine, as well as for caffeine from urine samples. The method was developed to assess exposure of restaurant and hotel workers to environmental tobacco smoke. METHODS: The method includes sample pretreatment and reversed-phase HPLC separation with tandem mass spectrometric identification and quantification using electrospray ionization on a quadrupole ion trap mass analyzer. Sample pretreatment followed standard protocols, including addition of base before liquid-liquid partitioning against dichloromethane on a solid matrix, evaporation of the organic solvent using gaseous nitrogen, and transferring to HPLC vials using HPLC buffer. HPLC separation was run on-line with the electrospray ionization-tandem mass spectrometric detection. RESULTS: The detection limits of the procedure were in the 1 microg/L range, except for nicotine (10 microg/L of urine). Still lower detection limits can be achieved with larger sample volumes. Recoveries of the sample treatment varied from 99% (cotinine) to 78% (3-hydroxycotinine). CONCLUSIONS: The method described is straightforward and not labor-intensive and, therefore, permits a high throughput of samples with excellent prospects for automation. The applicability of the method was demonstrated in a small-scale study on restaurant employees.     

Identification of novel CYP2A6*1B variants: the CYP2A6*1B allele is associated with faster in vivo nicotine metabolism

Cytochrome P450 2A6 (CYP2A6) is the human enzyme responsible for the majority of nicotine's metabolism. CYP2A6 genetic variants contribute to the interindividual and interethnic variation in nicotine metabolism. We examined the association between the CYP2A6*1B variant and nicotine's in vivo metabolism. Intravenous infusions of deuterium-labeled nicotine were administered to 292 volunteers, 163 of whom were White and did not have common CYP2A6 variants, other than CYP2A6*1B. We discovered three novel CYP2A6*1B variants in the 3'-flanking region of the gene that can confound genotyping assays. We found significant differences between CYP2A6*1A/*1A, CYP2A6*1A/*1B, and CYP2A6*1B/*1B groups in total nicotine clearance (17.2+/-5.2, 19.0+/-6.4, and 20.4+/-5.9, P<0.02), non-renal nicotine clearance (16.4+/-5.0, 18.5+/-6.2, and 19.8+/-5.7, P<0.01), and the plasma trans-3'-hydroxycotinine/cotinine ratio (0.26+/-0.1, 0.26+/-0.1, and 0.34+/-0.1, P<0.001). There were also differences in total nicotine (29.4+/-12.9, 25.8+/-0.12.9, and 22.4+/-12.4, P<0.01), cotinine (29.2+/-8.1, 32.2+/-9.1, and 33.0+/-6.6, P<0.01) and trans-3'-hydroxycotinine (32.4+/-9.1, 34.2+/-12.3, and 41.3+/-11.3, P<0.001) excreted in the urine. We report evidence that CYP2A6*1B genotype is associated with faster nicotine clearance in vivo, which will be important to future CYP2A6 genotype association studies.     

CYP2A6 genotype and the metabolism and disposition kinetics of nicotine

BACKGROUND AND OBJECTIVE: The liver enzyme cytochrome P450 (CYP) 2A6 is primarily responsible for the metabolism of nicotine. Variants in the CYP2A6 gene have been associated with altered nicotine metabolism and with effects on smoking behavior. Our objective was to determine the relationship between variant CYP2A6 genotypes and the disposition and metabolism of nicotine administered intravenously. METHODS: Intravenous infusions of deuterium-labeled nicotine and cotinine were administered to 278 healthy twin volunteers, most of whom were white. They were genotyped for CYP2A6*1, CYP2A6*2, CYP2A6*4, CYP2A6*7, CYP2A6*8, CYP2A6*9, CYP2A6*10, and CYP2A6*12. RESULTS: On the basis of the fractional clearance of nicotine to cotinine and on the plasma ratio of 3'-hydroxycotinine to cotinine, both shown to be indicators of CYP2A6 enzymatic activity, subjects were classified into 3 groups. Group 1 included wild-type variant CYP2A6*1/*1 (n=215) and was assumed to have 100% activity. Group 2 included *1/*9 (n=21) and *1/*12 (n=12), which averaged about 80% of normal activity. Group 3 included *1/*2 (n=10), *1/*4 (n=2), *9/*12 (n=3), *9/*4 (n=2), and *9/*9 (n=3), which averaged about 50% of normal activity. The mean total plasma clearance of nicotine (+/-SD) was 18.8+/-6.0, 15.5+/-4.9, and 11.7+/-5.1 mL.min-1.kg-1 in groups 1, 2, and 3, respectively, and group 1 had significantly faster clearance than group 2 (P<.05) and group 3 (P<.01). Overall, groups 2 and 3 also had lower total clearance of cotinine, had longer half-lives for nicotine and cotinine, and excreted in the urine a greater fraction of the nicotine dose as unchanged nicotine and nicotine glucuronide and excreted less as 3'-hydroxycotinine compared with group 1. CONCLUSIONS: We provide novel pharmacokinetic and metabolic data on nicotine after systemic dosing in relation to common CYP2A6 genotypes. Our data will enhance the interpretation of CYP2A6 genotypic data as used in association studies of smoking behavior and its health consequences.     

Nicotine metabolism and elimination kinetics in newborns

OBJECTIVE: To characterize the presence of and elimination kinetics of nicotine and its metabolites in newborns. METHODS: Blood samples from 13 newborns were collected during the first day of life and analyzed for nicotine and cotinine. Single daily urine samples were collected from nine newborns for up to 7 days and analyzed by gas chromatography-mass spectrometry for nicotine, cotinine, 3'-hydroxycotinine, and their conjugates. NONMEM was used to determine population half-life values. RESULTS: Blood and urine data gave similar results for nicotine and cotinine elimination kinetics. The elimination half-life for nicotine was 11.2 hours (95% confidence interval [CI], 8.0 to 18.9) based on blood data and 9.0 hours (95% CI, 7.0 to 12.4) based on urine data. The elimination half-life for cotinine was 16.3 hours (95% CI, 12.4 to 23.9) based on blood data and was 22.8 hours (95% CI, 19.5 to 25.8) based on urine data. The elimination half-lives for the other metabolites were 13 hours for conjugated nicotine; 19.8 hours for conjugated cotinine; 18.8 hours for 3'-hydroxycotinine; and 19.4 hours for conjugated 3'-hydroxycotinine. The half-life of nicotine is three to four times longer in newborns than in adults, whereas the half-life of cotinine is similar in newborns and adults. CONCLUSIONS: In adults, CYP2A6 is the predominant enzyme responsible for the metabolism of both nicotine and cotinine. The prolonged elimination of nicotine but not of cotinine in the newborn compared with that in the adult may be a result of different newborn CYP2A6 enzymatic substrate specificity, low CYP2A6 activity with another enzyme that is primarily responsible for cotinine metabolism, or differences in tissue distribution.     

Effects of nicotine, cocaine and some of their metabolites on schedule-controlled responding by beagle dogs and squirrel monkeys

The behavioral effects of nicotine were compared with those of its metabolites, nornicotine and cotinine, in beagle dogs and squirrel monkeys. Subjects responded under a multiple fixed-interval (FI) 300-sec, fixed-ratio (FR) 30 response schedule of food presentation. Nicotine (0.01-1.0 mg/kg i.m.) and nornicotine (0.03-3.0 mg/kg i.m.) produced qualitatively similar effects in both dogs and monkeys. Nicotine produced dose-related increases, then decreases in rates of responding during FI components; rates of responding during FR components were only decreased. Nornicotine produced only dose-dependent decreases in responding during both FI and FR components. In the dogs, cotinine (0.01-10.0 mg/kg i.m.) produced only dose-dependent decreases in rates of responding during both FI and FR components. In the squirrel monkeys, however, cotinine (0.1-3.0 mg/kg i.m.) increased responding during FI components; a high dose of 30.0 mg/kg decreased responding during both FI and FR components. The behavioral effects of cocaine (0.03-3.0 mg/kg i.m.) and its metabolite norcocaine (0.01-1.0 mg/kg i.m.) were compared in the dogs. FI rates of responding first increased and then decreased with increasing doses of each drug, whereas FR rates of responding only decreased in a dose-related manner. Norcocaine was slightly more potent than cocaine in producing these effects on schedule-controlled responding in dogs. These experiments indicate the metabolites of nicotine and cocaine are behaviorally active and may contribute to the pharmacological profile of the parent compounds.     

Nicotine metabolite ratio as an index of cytochrome P450 2A6 metabolic activity

BACKGROUND: Nicotine and a variety of other drugs and toxins are metabolized by cytochrome P450 (CYP) 2A6. Our objective was to evaluate the use of oral nicotine with measurement of the trans-3'-hydroxycotinine (3HC)/cotinine (COT) metabolite ratio as a noninvasive probe of CYP2A6 activity. METHODS: Sixty-two healthy volunteers received an oral solution of deuterium-labeled nicotine (2 mg) and its metabolite cotinine (10 mg). Plasma nicotine and plasma and saliva cotinine and 3HC concentrations were measured over time. RESULTS: The 3HC/COT ratio derived from deuterium-labeled cotinine, measured in either plasma (2-8 hours after administration) or saliva (at 6 hours), was strongly correlated with the oral clearance of nicotine (r = 0.76-0.83, depending on the time of measurement). The 6-hour 3HC/COT ratio from nicotine derived from tobacco in 14 smokers was highly correlated with the ratio derived from deuterium-labeled nicotine (r = 0.88) and was also highly correlated with the oral clearance of nicotine (r = 0.90). Two subjects homozygous for inactive CYP2A6 alleles produced no 3HC, confirming the specificity of the metabolite ratio. The 3HC/COT ratio was also highly correlated with the clearance and half-life of cotinine, consistent with the fact that cotinine is also primarily metabolized by CYP2A6. CONCLUSIONS: The 3HC/COT ratio derived from nicotine either administered as a probe drug or from tobacco use, measured in either plasma or saliva, is highly correlated with the oral clearance of nicotine. The ratio appears to be a useful noninvasive marker of the rate of nicotine metabolism (which is important in studying nicotine addiction and smoking behavior), as well as a general marker of CYP2A6 activity (which is important in studying drug and toxin metabolism).     

Nicotine, cotinine, and anabasine inhibit aromatase in human trophoblast in vitro.

Epidemiologic studies suggest that women who smoke have lower endogenous estrogen than nonsmokers. To explore the possible link between cigarette smoking and decreased endogenous estrogens, we have examined the effects of constituents of tobacco on estrogen production in human choriocarcinoma cells and term placental microsomes. In choriocarcinoma cell cultures, nicotine, cotinine (a major metabolite of nicotine), and anabasine (a minor component of cigarette tobacco) all inhibited androstenedione conversion to estrogen in a dose-dependent fashion. Removal of nicotine, cotinine, and anabasine from the culture medium resulted in the complete reversal of the inhibition of aromatase. In the choriocarcinoma cell cultures, a supraphysiologic concentration of androstenedione (73 microM) in the culture medium blocked the inhibition of aromatase caused by nicotine, cotinine, and anabasine. In preparations of term placental microsomes, nicotine, cotinine, and anabasine inhibited the conversion of testosterone to estrogen. Kinetic analysis demonstrated the inhibition to be competitive with respect to the substrate. These findings suggest that some nicotinic alkaloids directly inhibit aromatase. This mechanism may explain, in part, the decreased estrogen observed in women who smoke.     

Gas-liquid chromatographic determination of nicotine and cotinine in plasma

We report a procedure for determining nicotine and cotinine in plasma. Nicotine is extracted from 1 ml of plasma with diethyl ether, back extracted, and analyzed by gas-liquid chromatography with a nitrogen/phosphorus detector. Nicotine and its internal standard, modaline, had retention times of 1.9 and 2.9 min, respectively. Cotinine is then extracted from the same plasma with dichloromethane and similarly analyzed. Cotinine and its internal standard, lidocaine, had retention times of 3.8 and 4.9 min. Day-to-day reproducibilities (CV) within 14% for nicotine and within 6% for cotinine are attainable for the respective concentration ranges 1-100 microgram/liter and 1-200 microgram/liter. Nornicotine and related alkaloids do not interfere. The sensitivity was such that less than 0.1 microgram (0.62 nmol) of nicotine and 0.1 microgram (0.62 nmol) of nicotine and 0.1 microgram (0.57 nmol) of cotinine could be detected per liter.     

A high-performance liquid-chromatographic method for routine simultaneous determination of nicotine and cotinine in plasma

We describe a rapid, sensitive method for the routine simultaneous determination of nicotine and cotinine in 1 mL of plasma. Extraction in 10-mL screw-capped Teflon tubes with methylene chloride after deproteinization with trichloroacetic acid eliminated emulsion formation. The extract, after evaporation and reconstitution in 30 microL of mobile phase, is injected into a reversed-phase C-18 ion-pair column of an isocratic high-performance liquid-chromatographic unit. Absorbance is monitored at 256 nm. The mobile phase is a citrate-phosphate (30 mmol each per liter) buffer mixture containing 50 mL of acetonitrile and 1 mmol of sodium heptanesulfonate per liter. 2-Phenylimidazole is the internal standard. The detection limit is 1 microgram/L for nicotine and 3 micrograms/L for cotinine. The standard curve is linear from 0 to 700 micrograms/L for both compounds. The average CV for nicotine in the concentration range 0-100 micrograms/L is 6.5%, and that for cotinine in the concentration range 50-700 micrograms/L is 4%.     

Determinants of the rate of nicotine metabolism and effects on smoking behavior

BACKGROUND: Studies on cytochrome P450 (CYP) 2A6 suggest that genotype affects the rate of nicotine metabolism and, consequently, cigarette consumption. However, known alleles of CYP2A6 associated with fast or slow metabolism are relatively uncommon, and there remains considerable variation in metabolic activity among those with presumed wild-type CYP2A6 alleles, suggesting that other genetic or environmental factors also influence the rate of nicotine metabolism. METHODS: We investigated determinants of the rate of nicotine metabolism and effects on smoking behavior in a United Kingdom cohort who participated in a placebo-controlled trial of smoking cessation via nicotine replacement therapy. Those who continued to smoke cigarettes at the 8-year follow-up formed our study group (N = 545). The ratio of the nicotine metabolite trans-3'-hydroxycotinine to cotinine in plasma was used as an index of CYP2A6 activity and thus as a marker of the rate of nicotine metabolism. RESULTS: The nicotine metabolite ratio was associated with sex (P < .0001), CYP2A6 genotype (*1B, *2, *4, *9, and *12) (P < .0001), CYP2B6 haplotype (*4-dominant) (P = .02), plasma nicotine concentration (P < .0001), and age (P = .02) but was not associated with dependence score (P > .20). The ratio also predicted the number of cigarettes smoked at will per day, although the association was weak (F(1, 492) = 4.05, P = .04). CONCLUSION: In this cohort the rate of nicotine metabolism is related to age, sex, CYP2A6 genotype, and CYP2B6 genotype and may affect the level of tobacco consumption.     

Influence of menstrual cycle on cytochrome P450 2A6 activity and cardiovascular effects of nicotine

BACKGROUND AND OBJECTIVES: The phase of the menstrual cycle has been reported to affect frequency of smoking, withdrawal symptoms, and the likelihood of smoking cessation in women. Cytochrome P450 (CYP) 2A6 is primarily responsible for the metabolism of nicotine. Our objective was to evaluate the effect of the phase of the menstrual cycle on the activity of CYP2A6 and the cardiovascular effects of nicotine. METHOD: Eleven healthy, nonsmoking women received a 30-minute combined infusion of deuterium-labeled nicotine and cotinine (0.5 microg . kg(-1) . min(-1) of each compound) during the midfollicular and midluteal phases of the menstrual cycle. Nicotine and cotinine pharmacokinetic parameters and plasma adrenocorticotropic hormone (ACTH), epinephrine, and norepinephrine responses were measured over time. RESULTS: There were no biologically or statistically significant differences in the comparison of menstrual cycle phases with regard to the pharmacokinetics of nicotine and cotinine. Nicotine clearance was 1000 +/- 315 mL/min and 1047 +/- 271 mL/min in the follicular and luteal phases, respectively (geometric mean ratio, 1.06; 90% confidence interval, 0.87-1.29). Cotinine clearance was 44 +/- 20 mL/min and 55 +/- 42 mL/min in the follicular and luteal phases, respectively (geometric mean ratio, 1.13; 90% confidence interval, 0.90-1.41). Nicotine infusion increased blood pressure, heart rate, and epinephrine concentrations. There were no differences in catecholamine, ACTH, or hemodynamic responses to nicotine infusion between menstrual cycle phases, although norepinephrine concentrations were constantly higher in the luteal phase compared with the follicular phase. CONCLUSIONS: CYP2A6 activity is not affected by menstrual cycle phase, and it is unlikely that menstrual cycle-related smoking habits of women are determined by changes in nicotine pharmacokinetics. The effects of nicotine on plasma ACTH and catecholamine levels and hemodynamic parameters are not altered by menstrual cycle phase in healthy, nonsmoking women.     

Brain uptake kinetics of nicotine and cotinine after chronic nicotine exposure

Blood-brain barrier (BBB) nicotine transfer has been well documented in view of the fact that this alkaloid is a cerebral blood flow marker. However, limited data are available that describe BBB penetration of the major tobacco alkaloids after chronic nicotine exposure. This question needs to be addressed, given long-term nicotine exposure alters both BBB function and morphology. In contrast to nicotine, it has been reported that cotinine (the major nicotine metabolite) does not penetrate the BBB, yet cotinine brain distribution has been well documented after nicotine exposure. Surprisingly, therefore, the literature indirectly suggests that central nervous system cotinine distribution occurs secondarily to nicotine brain metabolism. The aims of the current report are to define BBB transfer of nicotine and cotinine in naive and nicotine-exposed animals. Using an in situ brain perfusion model, we assessed the BBB uptake of [3H]nicotine and [3H]cotinine in naive animals and in animals exposed chronically to S-(-)nicotine (4.5 mg/kg/day) through osmotic minipump infusion. Our data demonstrate that 1) [3H]nicotine BBB uptake is not altered in the in situ perfusion model after chronic nicotine exposure, 2) [3H]cotinine penetrates the BBB, and 3) similar to [3H]nicotine, [3H]cotinine BBB transfer is not altered by chronic nicotine exposure. To our knowledge, this is the first report detailing the uptake of nicotine and cotinine after chronic nicotine exposure and quantifying the rate of BBB penetration by cotinine.     

Simulation and evaluation of nicotine intake during passive smoking: cotinine measurements in body fluids of nonsmokers given intravenous infusions of nicotine

The technique of monitoring cotinine concentrations in body fluids as a means of measuring nicotine intake during passive smoking has been evaluated in two studies, both of which used intravenous infusion to stimulate nicotine intake. In the first study, nicotine and cotinine were given separately, for 1 hour in four different intravenous doses (3.2, 15.4, 30.9, and 61.7 nmol/min) to each nonsmoker. In the second study, nicotine and cotinine were infused for 4 hours; each subject received five different doses of nicotine (1.5, 3.1, 6.2, 10.8, and 15.4 nmol/min) and one of cotinine (10.8 nmol/min). The concentration of cotinine was constant in both plasma and saliva from 1 to 4 hours after the nicotine infusion; the plateau levels of cotinine were found to be linearly and directly related to the nicotine intake. The ratio of salivary to plasma cotinine was 1:1.27. A linear relationship was also found between nicotine and cotinine infusion rates and the AUC values for cotinine. The fraction metabolized to cotinine was found to be about 0.5. The results from these studies show that: (1) there is a linear relationship between the plateau concentration of cotinine and the amount of nicotine infused over a period of 1 up to 4 hours; (2) salivary cotinine provides the same information on nicotine intake as does plasma cotinine; and (3) single measurements of either plasma or salivary cotinine concentrations at 1 to 4 hours after the exposure could be used to predict the nicotine intake during 1 to 4 hours of environmental tobacco smoke exposure.