Formation of N-nitrosamines by micelle-catalysed nitrosation of aliphatic secondary amines

N-Nitrosamines are an important class of potent human carcinogens and mutagens that can be present in water and wastewater. For instance, N-nitrosamines can be formed by reaction of nitrosating agents such as NO+ or N2O3 formed from nitrite under acidic conditions with secondary amine precursors by an acid-catalysed nitrosation pathway. This study investigates the catalytic effect of cationic and anionic micelles on the nitrosation of secondary aliphatic amines in the presence of nitrite at different pH values. The results of this study demonstrate that the nitrosation of hydrophobic secondary amines (e.g., dipropylamine and dibutylamine) by nitrite was significantly enhanced in the presence of micelles of the cationic surfactant cetyltrimethylammonium chloride whereas anionic micelles formed by sodium dodecylsulfate did not significantly enhance the formation of N-nitrosamines. Rate enhancements of up to 100-fold were observed for the formation of N-nitrosodibutylamine in the presence of cetyltrimethylammonium chloride. The magnitude of the catalytic effect of cationic micelles on the nitrosation reaction depended mainly of the hydrophobicity of the amine precursors (i.e., alkyl chain length), the stability and the charge of the micelles and pH. One important enhancement factor is the lowering of the pKa of the precursor alkylammonium ion due to the electrical potential at the micelle-water interface by up to ∼2.5 pH units. These results suggest that cationic micelle-forming surfactants might play a role in the formation of N-nitrosamines in wastewater, consumer products and in industrial processes using high concentrations of cationic surfactants.

Computational investigation of the nitrosation mechanism of piperazine in CO2 capture

Quantum chemistry calculations and kinetic modeling were performed to investigate the nitrosation mechanism and kinetics of diamine piperazine (PZ), an alternative solvent for widely used monoethanolamine in postcombustion CO₂ capture (PCCC), by two typical nitrosating agents, NO₂^- and N₂O₃, in the presence of CO₂. Various PZ species and nitrosating agents formed by the reactions of PZ, NO₂^-, and N₂O₃ with CO₂ were considered. The results indicated that the reactions of PZ species having NH group with N₂O₃ contribute the most to the formation of nitrosamines in the absorber unit of PCCC and follow a novel three-step nitrosation mechanism, which is initiated by the formation of a charge-transfer complex. The reactions of all PZ species with NO₂^- proceed more slowly than the reactions of PZ species with ONOCO₂^-, formed by the reaction of NO₂^- with CO₂. Therefore, the reactions of PZ species with ONOCO₂^- contribute more to the formation of nitrosamines in the desorber unit of PCCC. In view of CO₂ effect on the nitrosation reaction of PZ, the effect through the reaction of PZ with CO₂ shows a completely different tendency for different nitrosating agents. More importantly, CO₂ can greatly accelerate the nitrosation reactions of PZ by NO₂^- through the formation of ONOCO₂^- in the reaction of CO₂ with NO₂^-. This work can help to better understand the nitrosation mechanism of diamines and in the search for efficient methods to prevent the formation of carcinogenic nitrosamines in CO₂ capture unit.

N-nitrosamine formation by monochloramine, free chlorine, and peracetic acid disinfection with presence of amine precursors in drinking water system

In this study, the formation of eight N-nitrosamines, N-nitrosodimethylamine (NDMA), N-nitrosodiethylamine, N-nitrosomethylamine, N-nitrosodi-n-propylamine, N-nitrosodi-n-butylamine, N-Nitrosopiperidine, N-Nitrosopyrrolidine, N-Nitrosomorpholine, were systematically evaluated with respect to seven N-nitrosamine precursors (dimethylamine, trimethylamine, 3-(dimethylaminomethyl)indole, 4-dimethylaminoantipyrine, ethylmethylamine, diethylamine, dipropylamine) and three disinfectants (monochloramine, free chlorine, peracetic acid) under variable dosages, exposure times, and pH in a drinking water system. Without the presence of the seven selected N-nitrosamine precursors N-nitrosamine formation was not observed under any tested condition except very low levels of N-Nitrosopyrrolidine under some conditions. With selected N-nitrosamine precursors present N-nitrosamines formed at different levels under different conditions. The highest N-nitrosamine formation was NDMA with a maximum concentration of 1180 ng/L by monochloramine disinfection with precursors present; much lower levels of N-nitrosamines were formed by free chlorine disinfection; and no detectable level of N-nitrosamines were observed by peracetic acid disinfection except low level of N-Nitrosodi-n-propylamine under some conditions. NDMA formation was not affected by pH while four other N-nitrosamine formations were slightly affected by sample pH tested between 7 and 9, with formation decreasing with increasing pH. Monochloramine exposure time study displayed fast formation of N-nitrosamines, largely formed in four hours of exposure and maximized after seven days. This was a systematic study on the N-nitrosamine formation with the seven major N-nitrosamine precursors presence and absence under different conditions, including peracetic acid disinfection which has not been studied elsewhere.

Identification of precursors and mechanisms of tobacco-specific nitrosamine formation in water during chloramination

We report here that tobacco-specific nitrosamines (TSNAs) are produced from specific tobacco alkaloids during water chloramination. To identify the specific precursors for the formation of specific TSNAs in drinking water, we have developed a solid-phase extraction-liquid chromatography-tandem mass spectrometry (SPE-LC-MS/MS) method for simultaneous determination of five TSNAs and three tobacco alkaloids. Using this method, we detected nicotine (NIC) at 15.1 ng/L in a source water. Chloramination of this source water resulted in the formation of 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) (0.05 ng/L) and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL) (0.2 ng/L) along with the reduction of NIC to 1.1 ng/L, suggesting that NNK and NNAL were formed from NIC. To confirm that tobacco alkaloids are the precursors of TSNAs, we chloraminated water-leaching samples of tobacco from three brands of cigarettes and found that the formation of TSNAs coincides with the reduction of the alkaloids. Chloramination of individual alkaloids confirms that NNK and NNAL are produced from NIC, N-nitrosonornicotine (NNN) from nornicotine (NOR), and N-nitrosoanabasine (NAB) from anabasine (ANA). Furthermore, we have identified specific intermediates of these reactions and proposed potential pathways of formation of TSNAs from specific alkaloids. These results confirm that NNK and NNAL are the disinfection byproducts (DBPs) resulting from NIC in raw water.

Nitrosamine formation in amine scrubbing at desorber temperatures

Amine scrubbing is a thermodynamically efficient and industrially proven method for carbon capture, but amine solvents can nitrosate in the desorber, forming potentially carcinogenic nitrosamines. The kinetics of reactions involving nitrite and monoethanolamine (MEA), diethanolamine (DEA), methylethanolamine (MMEA), and methyldiethanolamine (MDEA) were determined under desorber conditions. The nitrosations of MEA, DEA, and MMEA are first order in nitrite, carbamate species, and hydronium ion. Nitrosation of MDEA, a tertiary amine, is not catalyzed by the addition of CO2 since it cannot form a stable carbamate. Concentrated and CO2 loaded MEA was blended with low concentrations of N-(2-hydroxyethyl) glycine (HeGly), hydroxyethyl-ethylenediamine (HEEDA), and DEA, secondary amines common in MEA degradation. Nitrosamine yield was proportional to the concentration of secondary amine and was a function of CO2 loading and temperature. Blends of tertiary amines with piperazine (PZ) showed n-nitrosopiperazine (MNPZ) yields close to unity, validating the slow nitrosation rates hypothesized for tertiary amines. These results provide a useful tool for estimating nitrosamine accumulation over a range of amine solvents.

Effects of flue gas compositions on nitrosamine and nitramine formation in postcombustion CO2 capture systems

Amine-based technologies are emerging as the prime contender for postcombustion CO2 capture. However, concerns have arisen over the health impacts of amine-based CO2 capture associated with the release of nitrosamines and nitramines, which are byproducts from the reactions between flue gas NOx and solvent amines. In this study, flue gas compositions were systematically varied to evaluate their effects on the formation of nitrosamines and nitramines in a lab-scale CO2 capture reactor with morpholine as a model solvent amine. The accumulation of N-nitrosomorpholine in both the absorber and washwater increased linearly with both NO and NO2 for concentrations up to ∼20 ppmv. These correlations could be extrapolated to estimate N-nitrosomorpholine accumulation at extremely low NOx levels (0.3 ppmv NO2 and 1.5 ppmv NO). NO played a particularly important role in driving N-nitrosomorpholine formation in the washwater, likely following partial oxidation to NO2 by O2. The accumulation of N-nitromorpholine in both the absorber and washwater positively correlated with flue gas NO2 concentration, but not with NO concentration. Both N-nitrosomorpholine and N-nitromorpholine accumulated fastest in the absence of CO2. Flue gas humidity did not affect nitrosamine accumulation in either the absorber or the washwater unit. These results provide a basis for estimating the effects of flue gas composition on nitrosamine and nitramine accumulation in postcombustion CO2 capture systems.

Occurrence and fate of N-nitrosamines and their formation potential in three wastewater treatment plants in Japan

N-nitrosamines are well known as carcinogens present in the environment. However, studies of the occurrence and fate of N-nitrosamines and their N-nitrosamine formation potential (FP) in wastewater treatment plants (WWTPs) are lacking. Therefore, the objectives of this study were to determine the occurrence of N-nitrosamines in WWTPs, the FP of N-nitrosamines on chloramination during wastewater treatment, and the efficiency of FPNH2Cl reduction by biological treatment. Also, the residual FPNH2Cl in the final discharge was investigated. The efficiencies of removal of N-nitrosamines ranged from 35 to 94% (WWTP O; residential area), from 58 to 98% (WWTP E; industrial area), and from 58% to >99% (WWTP N; industrial area). In WWTP O, the rates of production of N-nitrosodimethylamine (NDMA) (42%) and NDBA (58%) were the highest. In WWTP E, only NDBA (34%) was produced. In WWTP N, NPYR and NPIP (both >99%) were produced. NDMA FPNH2Cl values were very high in influent in all WWTPs. The efficiencies of removal of N-nitrosamine FPNH2Cl during biological treatment ranged from 20% to >99%, but there is no obvious explanation for this variability. Residual N-nitrosamine FPNH2Cl ranged from 2 to 22 ng L(-1). Thus, N-nitrosamines could be produced in water purification or reclamation plants using discharge from WWTPs.

Occurrences of nitrosamines in chlorinated and chloraminated drinking water in three representative cities, China

An investigation of the occurrence of nine nitrosamines in drinking water following different water treatment processes was conducted using samples from seven drinking water treatment plants in three cities and tap waters in one city in China. The total nitrosamine levels ranged from not detected (n.d.) to 43.45 ng/L. The species and concentrations of the nine nitrosamines varied with disinfection methods and source waters. N-nitrosodimethylamine (NDMA), which is the nitrosamines of greatest concern, was identified in raw water, disinfecting water, finished water and tap water samples, ranging from 0.8 to 21.6, 0.12 to 24.2, n.d. to 8.8, and n.d. to 13.3 ng/L, respectively. Chloramination alone produced the most significant amounts of NDMA, while ozonation followed by chloramination led to moderately reduced levels. Additionally, chlorination produced relatively less NDMA, while low pressure ultraviolet radiation followed by chlorination could also significantly reduce them. Total organic carbon is one of the most important factors influencing nitrosamines formation in disinfecting water. In contrast, the addition of chlorine following any other disinfection was found to increase the formation of the other eight species of nitrosamines. The three nitrosamines recommended for monitoring by the US EPA were detected in the tap water samples, but most were present at levels below those that pose a risk to human health. Nevertheless, the occurrence and concentration of nitrosamines regulated in the Drinking Water Contaminant Candidate List could cause some potential human effects and therefore warrant attention.

N-nitrosamines formation from secondary amines by nitrogen fixation on the surface of activated carbon

Our previous study demonstrated that many commercial activated carbon (AC) particles may catalyze transformation of secondary amines to yield trace levels of N-nitrosamines under ambient aerobic conditions. Because of the widespread usage of AC materials in numerous analytical and environmental applications, it is imperative to understand the reaction mechanism responsible for formation of nitrosamine on the surface of ACs to minimize their occurrence in water treatment systems and during analytical methods employing ACs. The study results show that the AC-catalyzed nitrosamine formation requires both atmospheric oxygen and nitrogen. AC's surface reactive sites react with molecular oxygen to form reactive oxygen species (ROS), which facilitate fixation of molecular nitrogen on the carbon surfaces to generate reactive nitrogen species (RNS) likely nitrous oxide and hydroxylamine that can react with adsorbed amines to form nitrosamines. AC's properties play a crucial role as more nitrosamine formation is associated with carbon surfaces with higher surface area, more surface defects, reduced surface properties, higher O(2) uptake capacity, and higher carbonyl group content. This study is a first of its kind on the nitrosamine formation mechanism involving nitrogen fixation on AC surfaces, and the information will be useful for minimization of nitrosamines in AC-based processes.

Demonstration of 20 pharmaceuticals and personal care products (PPCPs) as nitrosamine precursors during chloramine disinfection

The worldwide detection of pharmaceuticals and personal care products (PPCPs) in the aquatic environment and drinking water has been a cause for concern in recent years. The possibility for concurrent formation of nitrosamine DBPs (disinfection by-products) during chloramine disinfection has become another significant concern for delivered drinking water quality because of their potent carcinogenicity. This study demonstrates that a group of PPCPs containing amine groups can serve as nitrosamine precursors during chloramine disinfection. Molar yields higher than 1% are observed for eight pharmaceuticals, with ranitidine showing the strongest potential to form N-nitrosodimethylamine (NDMA). The molar conversion increases with the Cl(2):N mass ratio, suggesting that dichloramine is relevant to the formation of NDMA from these precursors. Although the trace level of PPCPs in the environment suggests that they may not account for the majority of nitrosamine precursors during the disinfection process, this study demonstrates a connection between the transformation of PPCPs and the formation of nitrosamines during chloramine disinfection. This both expands the pool of potential nitrosamine precursors, and provides a possible link between the presence of trace levels of certain PPCPs in drinking water sources and potential adverse health effects.

Formation of N-nitrosodiphenylamine and two new N-containing disinfection byproducts from chloramination of water containing diphenylamine

N-nitrosodiphenylamine (NDPhA) is a disinfection byproduct (DBP) in drinking water. However, it is not known what governs the formation of NDPhA and which precursor(s) in the raw water is responsible for its formation. We report here diphenylamine (DPhA) as a key precursor of NDPhA, and we describe the effect of water pH and chloramination conditions on the formation of NDPhA. To identify precursors of NDPhA, raw water samples were collected from the same drinking water system in which NDPhA was previously detected. Analysis of the raw water samples showed the presence of 1.3 ng/L of DPhA and no detectable NDPhA. Seven hours after the treatment of the raw water with chloramines, the concentration of DPhA decreased to 0.4 ng/L with corresponding formation of NDPhA (0.4 ng/L). Controlled experiments involving chloramination of DPhA in water showed that chloramines were essential to the formation of NDPhA, and that increasing the pH from 4 to 10 resulted in 64-fold enhancement in NDPhA formation. Removal of DPhA and formation of NDPhA was found by mass imbalance, which led to the identification of two new DBPs, phenazine (MW 180 Da) and a chlorinated phenazine derivative (MW 216 Da), using liquid chromatography tandem mass spectrometry and gas chromatography mass spectrometry. Both new DBPs were detected only in the treated water and not in the raw water. Phenazine and N-chlorophenazine have never been reported as DBPs and neither their occurrence in drinking water nor their health effects are known.

Elimination of organic micropollutants in a municipal wastewater treatment plant upgraded with a full-scale post-ozonation followed by sand filtration

The removal efficiency for 220 micropollutants was studied at the scale of a municipal wastewater treatment plant (WWTP) upgraded with post-ozonation followed by sand filtration. During post-ozonation, compounds with activated aromatic moieties, amine functions, or double bonds such as sulfamethoxazole, diclofenac, or carbamazepine with second-order rate constants for the reaction with ozone >10(4) M(-1) s(-1) at pH 7 (fast-reacting) were eliminated to concentrations below the detection limit for an ozone dose of 0.47 g O3 g(-1) dissolved organic carbon (DOC). Compounds more resistant to oxidation by ozone such as atenolol and benzotriazole were increasingly eliminated with increasing ozone doses, resulting in >85% removal for a medium ozone dose (approximately 0.6 g O3 g(-1) DOC). Only a few micropollutants such as some X-ray contrast media and triazine herbicides with second-order rate constants <10(2) M(-1) s(-1) (slowly reacting) persisted to a large extent. With a medium ozone dose, only 11 micropollutants of 55 detected in the secondary effluent were found at >100 ng L(-1). The combination of reaction kinetics and reactor hydraulics, based on laboratory-and full-scale data, enabled a quantification of the results by model calculations. This conceptual approach allows a direct upscaling from laboratory- to full-scale systems and can be applied to other similar systems. The carcinogenic by-products N-nitrosodimethylamine (NDMA) (< or =14 ng L(-1)) and bromate (<10 microg L(-1)) were produced during ozonation, however their concentrations were below or in the range of the drinking water standards. Furthermore, it could be demonstrated that biological sand filtration is an efficient additional barrier for the elimination of biodegradable compounds formed during ozonation such as NDMA. The energy requirement for the additional post-ozonation step is about 0.035 kWh m(-3), which corresponds to 12% of a typical medium-sized nutrient removal plant (5 g DOC m(-3)).

Nitrosamine, dimethylnitramine, and chloropicrin formation during strong base anion-exchange treatment

Strong base anion-exchange resins represent an important option for water utilities and homeowners to address growing concerns with nitrate, arsenate, and perchlorate contamination of source waters. Most commercially available anion-exchange resins employ quaternary amine functional groups. Previous research has provided contradictory evidence regarding whether these resins serve as sources of nitrosamines, considered as highly carcinogenic nitrogenous disinfection byproducts (N-DBPs), even without disinfectants. For three common varieties of commercial anion-exchange resins, we evaluated the importance of releases of nitrosamines, and two other N-DBPs (dimethylnitramine and chloropicrin), when the resins were subjected to typical column flow conditions with and without free chlorine or chloramine application upstream or downstream of the columns. In the absence of disinfectants, fresh trimethylamine- and tributylamine-based type 1 and dimethylethanolamine-based type 2 anion-exchange resins usually released 2-10 ng/L nitrosamines, likely due to shedding of manufacturing impurities, with excursions of up to 20 ng/L following regeneration. However, the lack of significant nitrosamine release in a full-scale anion-exchange treatment system after multiple regeneration cycles indicates that releases may eventually subside. Resins also shed organic precursors that might contribute to nitrosamine formation within distribution systems when chloramines are applied downstream. With free chlorine or chloramine application upstream, nitrosamine concentrations were more significant, at 20-100 ng/L for the type 1 resins and approximately 400 ng/L for the type 2 resin. However, chloropicrin formation was lowest for the type 2 resin. Dimethylnitramine formation was significant with free chlorine application upstream but negligible with chloramines. Although no N-DBPs were detected in cation-exchange-based consumer point-of-use devices exposed to chlorinated or chloraminated waters, our results indicate that inclusion of anion-exchange resins in these devices, as in laboratory deionized water systems, would likely be problematic.

Enhanced nitrogenous disinfection byproduct formation near the breakpoint: implications for nitrification control

Increasing the chlorine to ammonia molar ratio and breakpoint chlorination are two control strategies practiced by drinking water treatment utilities experiencing nitrification during chloramination. The first strategy will increase dichloramine formation, which increases nitrosamine formation. Moreover, our results indicate that dichloramine is also an important factor for nitrile formation. Near the breakpoint, nitrosamine formation is over an order of magnitude higher than that observed during chloramination. We propose that there are two nitrosamine formation pathways active in the breakpoint chlorination region: (i) a relatively slow reaction of dichloramine with amine precursors in the presence of dissolved oxygen and (ii) a fast reaction involving reactive breakpoint chlorination intermediates. Lastly, in the presence of nitrite, if breakpoint chlorination is conducted to achieve a significant free chlorine residual, nitrosamines and nitramines will form through a reaction with nitrite and hypochlorite. However, nitrosamine formation will be much lower than when breakpoint chlorination is conducted with no significant free chlorine residual.

Inhibitory effects of Orostachys japonicus extracts on the formation of N-nitrosodimethylamine

In Korea, Orostachys japonicus has been used traditionally as a drug and health food. The aim of this study was to investigate possible inhibitory effects of O. japonicus extracts on the formation of N-nitrosodimethylamines (NDMA). Chloroform extraction was the most effective method for recovering the highest number of phenolic compounds and flavonoids; in these extracts the greatest nitrite-scavenging activity and inhibition of NDMA formation occurred at pH 2.5. The chloroform extract was separated into 10 fractions (J1-J10); fraction J4 inhibited NDMA formation by 90.1 +/- 0.4%. This fraction was then separated into five subfractions (J4-1-J4-5) using a silica gel column. Subfractions J4-2 [(+)-catechin] and J4-4 (3,4-dihdroxybenzoic acid) inhibited NDMA formation by 89.5 +/- 0.9 and 77.6 +/- 0.8%, respectively.

Synthesis and properties of bifunctional chloroalkyl nitrosamines with an intercalating moiety

Three N-nitroso-N-(arylcarbonyloxymethyl)-3-chloropropylamines were synthesized, and their chemical and biological properties were studied. All arylcarboxylates intercalated with double-stranded DNA, and their mutagenicity and DNA cross-linking activity were affected by their ring structure. The DNA interstrand cross-link formation increased dose dependently after treatment with the acridine analog. The anthraquinone analog showed the highest bacterial mutagenicity among the three nitrosamines in Salmonella typhimurium TA100, while in Salmonella typhimurium TA92, which can detect cross-linking agents, the acridine analog showed the highest mutagenicity. This agreed with the result of a cross-linking assay. These results suggest that the three-ring aromatic moiety gives DNA-intercalating ability to cross-linkable chloropropyl nitrosamine, and the acridine analog is considered as a possible new antitumor lead compound.

Amidine Nitrosation

The acidic nitrosation chemistry of nine acyclic secondary and tertiary amidines (Ph-N=C(R(1))NR(2)R(3); R(1) = H, CH(3), Ph; R(2), R(3) = H, Ph or (CH(3))(2) or C(CH(2))(4)) and several N-acylamidines was investigated. The principal nitrosation products were amides derived from the amino moiety and compounds derived from the benzenediazonium ion, which was independently trapped for quantitation in several cases. Tertiary amidines also produce nitrosamines in minor, but significant, yields. The benzamidines did not react, and the N-acylamidines hydrolyzed much more rapidly than they nitrosated. The data support the hypothesis that the reaction occurs by nitrosation on the imino nitrogen, followed by the addition of H(2)O to give a tetrahedral intermediate (alpha-hydroxynitrosamine) for which the main decomposition pathway generates an amide and a diazonium ion. In the case of the pyrrolidine-derived amidines, about 25% of the decomposition results in cleavage of the amine moiety, which nitrosates to give N-nitrosopyrrolidine. Pseudo-first-order rate constants for amidine nitrosation in aqueous acetic acid with excess nitrite at 25 degrees C ranged from (3 to 106) x 10(-5) s(-1), while the amidine basicity ranged over 5 pK(a) units. Rate constants corrected for amidine basicity showed the pyrrolidine derived amidines to be most reactive. The lack of benzamidine nitrosative reactivity is attributed to a very slow rate of H(2)O additon to the N-nitrosoamidinium ion and reversible nitrosation.

Synthesis of stereospecifically deuterated 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL) iastereomers and metabolism by A/J mouse lung microsomes and cytochrome p450 2A5

The tobacco-specific nitrosamine 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) is a lung carcinogen in mice and rats and is a putative human lung carcinogen. NNK undergoes cytochrome p450-mediated metabolic activation to DNA-binding intermediates but is also extensively reduced to 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL) in vivo. Because NNAL is also tumorigenic, the carcinogenicity of NNK may actually be governed by the metabolic activation of NNAL, rather than direct activation of NNK. Metabolism of NNK and NNAL at the 4-position generates the same critical DNA lesion, O(6)-methylguanine, the levels of which are correlated to tumorigenicity in the A/J mouse model. In an effort to better understand the bioactivation of NNAL and the effect of carbinol-carbon stereochemistry on prochiral selectivity at the 4-position, (R)- and (S)-NNAL, along with the stereospecifically 4-deuterated diastereomers (1R,4R)-[4-(2)H(1)]NNAL, (1R,4S)-[4-(2)H(1)]NNAL, (1S,4R)-[4-(2)H(1)]NNAL, and (1S,4S)-[4-(2)H(1)]NNAL, were synthesized. The in vitro metabolism of these compounds was investigated using A/J mouse lung microsomes and Spodoptera frugiperda-expressed mouse cytochrome p450 2A5. Carbinol-carbon stereochemistry did not appreciably influence stereoselectivity at the 4-position in the metabolism of these compounds by mouse lung microsomes or p450 2A5 but did influence the regiochemistry of metabolism. The ratio of 4- to N-methyl hydroxylation was approximately 1:1 for the A/J mouse lung microsome-mediated metabolism of all substrates, but this ratio was higher for (1S) substrates than for their (1R) counterparts when p450 2A5 was used. Interestingly, p450 2A5 converted substrates with (1S) stereochemistry to the respective N-oxides, but this metabolite was not formed from substrates with (1R) stereochemistry. Furthermore, p450 2A5 catalyzed the formation of NNK from (1S) substrates at significantly greater maximal rates than from (1R) substrates. The implications of these differences in metabolism for the tumorigenic mechanism of NNAL are discussed.

The combined solid/solution-phase synthesis of nitrosamines: the evolution of the "libraries from libraries" concept

The generation of diverse chemical libraries using the "libraries from libraries" concept by combining solid-phase and solution-phase methods is described. The central features of the approaches presented are the use of solid-phase synthesis methods for the generation of a combinatorial polyamine library. Following cleavage from the resin with HF, the polyamine library was reacted with ethyl nitrite in the solution phase to yield the desired nitrosamine library in good yield and purity. The approaches described enable the efficient syntheses of individual nitrosamines as well as mixture-based nitrosamine libraries.

Ambident ethyl N-nitrosocarbamate anion: experimental and computational studies of alkylation and thermal stability

Alkylation of N-nitrosourethane tetrabutylammonium salt (2-Bu(4)N) with four electrophiles (MeI, EtI, i-PrI, and PhCH(2)Br) was studied by (1)H NMR in CD(2)Cl(2) and CD(3)CN solutions. The ratio of the three regioisomers N-alkyl-N-nitrosourethane 3, azoxy 4, and O-alkyldiazotate 5 was practically independent of solvent but dependent on the nature of the electrophile. The anion 2 and O-alkyl derivative 5 are thermally unstable and decompose to ethyl carbonates 9 and 10, respectively, with a first-order rate constant (2-Bu(4)N: k = 18.5 +/- 0.1 x 10(-5) s(-1); 5b (R = Et): k = 1.77 +/- 0.02 x 10(-5) s(-1); 5d (R = PhCH(2)): k = 4.78 +/- 0.08 x 10(-5) s(-1) at 35 degrees C in CD(2)Cl(2)). Further kinetic measurements gave activation parameters for the decomposition of 2 (E(a) = 24.2 +/- 0.3 kcal/mol and ln A = 30.9 +/- 0.1). Gas-phase calculations at the MP2(fc)/6-31+G(d)//MP2(fc)/6-31G(d) level showed that the alkylation of 2 involves the lone electron pairs of the N-N-O atoms, and the calculated activation energies correspond well to the observed ratio of regioisomers 3-5. The theoretical analysis of the decomposition processes supports a concerted mechanism with a four-center transition state in the first step for all four compounds. The calculated activation energy order (2 < 5 < 3 < 4) is consistent with the observed order of stability. Decomposition of 2 and 5 is a unimolecular process, giving carbonates 9 and 10 in a single step. In contrast, rearrangement of 3 and 4 leads to alkyl diazonium ions. A detailed theoretical analysis indicates that the rate-determining step for thermal decomposition of 2 is the loss of molecular nitrogen, while in 5 it is the trans-cis isomerization process. The nonconcerted process involving homolytic cleavage of the O-N bond in 5 was found to be significantly less favorable.

Genotoxic effects of N-nitrosodicyclohexylamine in isolated human lymphocytes

Dicyclohexylamine x nitrite is classified as an "experimental equivocal tumorigenic agent" by the National Toxicology Program. Since no genotoxic effects of the substance itself are known, the reported tumorigenic potential of dicyclohexylamine x nitrite could be due to generation of N-nitrosodicyclohexylamine (N-NO-DCHA), which occurs under conditions of use and can be detected in foils that contain dicyclohexylamine x nitrite. Therefore, we investigated possible mutagenic properties of N-NO-DCHA in the Ames test and the cytokinesis-block micronucleus assay with human lymphocytes. Since N-NO-DCHA is not commercially available, the substance was synthesized and purified by thin-layer chromatography. Identity was confirmed by gas chromatography/mass spectroscopy (GC/MS) and 1H- and 13C-NMR. More than 97% purity was achieved. Stability and availability in the solvent were checked by GC/MS. N-NO-DCHA induced micronuclei in isolated human lymphocytes at a dose range of 15-100 micrograms/ml (= 71.4-476.2 microM), exceeding the base rate significantly at one or two nontoxic concentrations in four out of six experiments. For the Ames test, arochlor-1254-, beta-naphthoflavone/phenobarbital- and pyrazole-induced S9-fractions were used with Salmonella typhimurium TA100, TA1535, TA98 and TA104. No effects were seen in the Ames test, with the exception of microcolony induction at doses higher than 250 micrograms (= 1.2 mmol) N-NO-DCHA/plate using TA104 and 20% arochlor-1254 induced S9 at pH 6.5. In conclusion, N-NO-DCHA was negative in the Ames test using TA98, TA100 and TA1535, inconclusive using TA104, and weakly genotoxic in the in vitro micronucleus test with isolated human lymphocytes. With regard to the tumorigenicity of the majority of nitrosamines, our data underline the necessity of further studies on possible genotoxic effects of N-NO-DCHA.

In vitro formation and properties of beta- and gamma-hydroxy-N-nitrosohexamethyleneimine

Stable hydroxylated metabolites of N-nitrosohexamethyleneimine (NO-HEX) account for about one-third of the metabolites produced in in vitro reactions using uninduced rat liver microsomes post-microsomal supernatant. The ratio of gamma- to beta-hydroxyNO-HEX thus produced is 3:1. Each of these isomers exists in two conformeric forms that can be separated easily at room temperature by h.p.l.c. on C18 columns. The ratio of isomers does not vary with substrate concentration or time of reaction, which suggests that one liver enzyme is responsible for the formation of both isomers. Different ratios of conformeric forms of gamma-hydroxyNO-HEX produced by liver and lung microsomes indicate that these organs have different enzymes that perform the same functions. Anti-syn (E-Z) configurational assignments for the conformers were based on data obtained from 13C-n.m.r. studies. Although isolated conformers were stable at room temperature, when heated above 70 degrees C or dissolved in aprotic solvents, after several hours an equilibrium mixture was formed. The conformers of beta-hydroxyNO-HEX reached equilibrium in less than half the time required by gamma-hydroxy conformers. The results of i.r. spectroscopic studies suggest that hydrogen bonding may be involved in the stabilization of the conformers. Upon modification of the hydroxy group separable conformers are not detected; this is consistent with the suggestion that the hydroxy group may be involved in the stabilization of separable conformeric forms. We speculate that the occurrence of relatively stable and separable conformers may be due to intramolecular hydrogen bonding between the hydroxy and nitroso groups.

Synthesis and properties of novel bifunctional nitrosamines with omega-chloroalkyl groups

Novel N-nitroso-N-(acetoxymethyl)-omega-chloroalkylamines were synthesized and their chemical and biological properties were evaluated. The nitrosamines were expected to decompose through omega-chloroalkyldiazohydroxides in aqueous solution, and then to alkylate various cellular macromolecules. N-Nitroso-N-(acetoxymethyl)-2-chloroethylamine rapidly decomposed in aqueous solution, and the reaction rate was apparently independent of the pH of the solution. On the other hand, the rate of decomposition of chloropropyl and chlorobutyl homologs was pH-dependent, and increased in alkaline solution. When mutagenicity was assayed in Salmonella typhimurium TA1535 and TA92 for preliminary evaluation, all three compounds were directly mutagenic. The mutagenicity in Salmonella typhimurium TA1535, which can detect base-pair change mutation, clearly showed that these compounds induced DNA alkylation in vivo. The increase of alkyl chain length in chloroalkyl compounds increased the mutagenic activity, and the activities were stronger than those of the corresponding simple alpha-acetoxy nitrosamines lacking a chloro group, N-nitroso-N-(acetoxymethyl)alkylamines. Furthermore, the positive result in TA92 suggested that chlorinated nitrosamines cross-linked DNA like antitumor chloroethylnitrosoureas and that they are expected to be new lead compounds for antitumor agents.

O-Alkylation of cupferron: aiming at the design and synthesis of controlled nitric oxide releasing agents

O-Alkylation of N-nitroso-N-phenylhydroxylamine ammonium salt (cupferron) was studied for the synthesis of novel nitric oxide (NO) releasing agents. The alkylation occurred regioselectively at the terminal oxygen, leading to a single product N-(alkyloxy)-N'-phenyldiimide N'-oxide as indicated by NMR and X-ray analysis. The O-alkyl derivatives exhibited significantly improved stability compared to their parent compound, cupferron. It was demonstrated that the cupferron O-alkyl derivatives could function as photoreleasing NO donor compounds. N-(N"-acetylphenylalanylmethylenyloxy)-N'-phenyldiimide N'-oxide), which linked the cupferron portion with an amino acid via an acetal moiety, was synthesized as an model NO prodrug where controlled NO release would occur either by increasing pH or by a protease-catalyzed hydrolysis.

Metabolism of N'-nitrosonornicotine enantiomers by cultured rat esophagus and in vivo in rats

People who use tobacco products are exposed to considerable amounts of N'-nitrosonornicotine (NNN), a well-established esophageal carcinogen in rats. NNN is believed to play a significant role as a cause of esophageal and oral cavity cancer in smokers and snuff dippers. The carcinogenicity of NNN is dependent on its metabolic activation. However, virtually all studies carried out to date on NNN metabolism have used racemic material. In this study, we examined the metabolism of [5-(3)H]-(S)-NNN and [5-(3)H]-(R)-NNN in cultured rat esophagus and in vivo in rats. Cultured rat esophagus metabolized (S)-NNN (1 microM) predominantly to products of 2'-hydroxylation, 4-oxo-4-(3-pyridyl)butanoic acid (keto acid) and 4-hydroxy-1-(3-pyridyl)-1-butanone (keto alcohol). In contrast, the major metabolite of (R)-NNN under these conditions was 4-hydroxy-4-(3-pyridyl)butanoic acid (hydroxy acid), a product of NNN 5'-hydroxylation. The 2'-hydroxylation:5'-hydroxylation metabolite ratio ranged from 6.22 to 8.06 at various time intervals in the incubations with (S)-NNN, while the corresponding ratios were 1.12-1.33 in the experiments with (R)-NNN. These differences were statistically significant (P<0.001). Since 2'-hydroxylation is believed to be the major metabolic activation pathway of NNN in the rat esophagus, the results demonstrate that (S)-NNN is metabolically activated more extensively than (R)-NNN in this tissue, and therefore may be more carcinogenic. Rats were treated with 0.3 mg/kg of [5-(3)H]-(R)-NNN, [5-(3)H]-(S)-NNN, or racemic [5-(3)H]NNN by gavage, and the urinary metabolites were analyzed. The major metabolites were hydroxy acid and keto acid. As in the in vitro studies, products of 2'-hydroxylation predominated in the urine of the rats treated with (S)-NNN while products of 5'-hydroxylation were more prevalent in the rats treated with (R)-NNN. 2'-Hydroxylation:5'-hydroxylation metabolite ratios ranged from 1.66 to 2.04 in the urine at various times after treatment with (S)-NNN, while the ratios were 0.398-0.450 for the rats treated with (R)-NNN (P<0.001). The results of this study provide new insights into NNN metabolism in rats and suggest that the carcinogenicity of (S)-NNN, the predominant enantiomer in tobacco products, may be greater than that of (R)-NNN or racemic NNN.

In vitro DNA deamination by alpha-nitrosaminoaldehydes determined by GC/MS-SIM quantitation

The deamination of DNA bases by three alpha-nitrosaminoaldehydes, butylethanalnitrosamine, methylethanalnitrosamine, and N-nitroso-2-hydroxymorpholine (NHMOR), the direct metabolite of potent animal carcinogen N-nitrosodiethanolamine, was demonstrated by a set of in vitro experiments. The deamination of guanine, adenine, and cytosine bases in nucleotides, oligonucleotides, and calf thymus DNA gave xanthine, hypoxanthine, and uracil, respectively. The order of relative reactivities of the bases was as listed above. Deamination of cytosine to uracil was detected by the reaction of (32)P-labeled oligonucleotide ([5'-(32)P]CGAT) followed by enzymatic hydrolysis. Quantitative analysis of deamination of guanine and adenine in calf thymus DNA was performed by a gas chromatography/mass spectrometry-selected ion monitoring method. Both the extent and the rate of the deamination reactions which occur by transnitrosation from the alpha-nitrosaminoaldehyde to the base were determined for formation of xanthine and hypoxanthine. The deamination of guanine by NHMOR remained significant at low substrate levels.

2-Nitrosoimino-3,6-dihydro-2H-1,3,4-thiadiazines with antiplatelet and antithrombotic properties

The successful synthesis of 17 nitrosimines of 2 H-1,3,4-thiadiazines is reported. They are best characterized by their electronic spectra (lambda max = 504-522 nm). Some of the compounds were able to inhibit the aggregation of blood platelets in the Born-test (inducer collagen). The most active compound was the 3-nonyl-5-phenyl-derivative 10c which showed an IC50 = 6.5 mumol.l-1. In mesenteric arterioles of rats after p.o. administration (60 mg/kg) a 13% inhibition of thrombus formation is observed. The reason for the rather small effects is the high chemical stability of the title compounds and the fact that decomposition occurs mainly by the evolution of molecular nitrogen. Only small yields of NO are formed.

[Hygienic aspects of the study of the synthesis of nitrosamines from their precursors]

The paper presents data on the content of nitrosamines (NA), such an nitrosodimethylamine, nitrosodiethylamine, and their precursors (NO2 and amines) in the ambient air of different functional zones of a city. A high correlation between NA and NO2 in the air was established. NO2 was shown to have the leading role as a nitrosating agent in the model system and air during exogenous synthesis. The findings support the possible endogenous production and the role of NO2 in this process.

Determination of 2-ethylhexyl 4-(N-methyl-N-nitrosamino) benzoate in commercial sunscreens and cosmetic products

An analytical method has been developed for determination of 2-ethylhexyl 4-(N-methyl-N-nitrosamino) benzoate (NMPABAO), a nitrosamine contaminant in sunscreen products containing 2-ethylhexyl 4-(N,N-dimethylamino) benzoate (Padimate O). The method involves extraction of NMPABAO by column chromatography followed by liquid chromatographic separation and analysis wit a nitric oxide detector. To confirm the presence of NMPABAO in sunscreen products, the N-nitrosamine was synthesized and its structure was determined by infrared spectrophotometry, nuclear magnetic resonance spectrometry, and mass spectrometry (MS). For method validation, recovery studies were performed on a commercial suntan lotion, cream, and gel. Recoveries of NMPABAO added to representative test samples averaged 83%. The method has an estimated detection limit of 30 ppb. The method was used to analyze 25 commercial cosmetic and sunscreen products containing Padimate O. Eleven products contained NMPABAO at levels ranging from 160 to 21000 ppb. NMPABAO presence in 4 products was confirmed by MS at levels > or = 4000 ppb. The highest levels of NMPABAO were associated with products that contained the nitrite-releasing preservative 2-bromo-2-nitro-1,3-propanediol.

New NO-donors with antithrombotic and vasodilating activities, IX: Thiadiazole nitrosimines

Twenty 1,3,4-thiadiazole-2-nitrosimines and two 1,2,4-thiadiazole-5-nitrosimines were synthesized and assayed in the Born-test for their antiplatelet activity. Only two 1,3,4-thiadiazoles inhibited the aggregation at IC50 < 10 mumol/L. In an in vivo thrombosis model only in arterioles a small inhibition of thrombus formation was observed. The poor test results correspond to a very high chemical stability of the titel nitrosimines.

New NO-donors with antithrombotic and vasodilating activities, VIII: Benzothiazole-2(3H)-nitrosimines

Thirty title compounds were prepared and tested for their antiplatelet activity in the Born-test. Five nitrosimines inhibit the aggregation induced by collagen in concentrations below 10 mumol/L halfmaximally. Four compounds were investigated in an in vivo thrombosis model. An inhibition of thrombosis between 29 and 53% was observed in mesenteric arterioles of rats 2 h after p.o. administration (60 mg/kg). The effect in venoles was less pronounced (10-22%). For one compound these effects could still be demonstrated 4 h after oral application.

New NO-donors with antithrombotic and vasodilating activities, VII: Z/E-isomerism in thiazole- and 1,3,4-thiadiazole-2-nitrosimines

In thiazole- (23 compounds) and 1,3,4-thiadiazole-2-nitrosimines (20 compounds) Z/E-isomers were described by 1H-NMR-spectroscopy. There is a mutual conversion of the isomers. The coalescence temp. (Tc) mostly is 310 K. In the thiazole series, however, for five compounds higher energy barriers are observed. This is due to substituents in 4-position with electron withdrawing properties. The Tc is increased when the compounds are dissolved in water instead of DMSO. Hereby it is concluded that the isomers have Ze or Ee configuration. It is made probable that the low field signal for the substituent in 3-position corresponds to the Ze-isomer, which has a slight preference. The free enthalpy of rotation, calculated approximately, is between 56.0 (1m) and 73.7 kJ/mol (1r).

Fluorogenic N-nitrosoamides: active-site labeling reagents for chymotrypsin-like proteases

Two fluorogenic N-nitrosoamides, N-nitroso-N-((7-methoxycoumarin-4-yl)methyl)-N'-isobutyrylalaninamide (6a) and N-nitroso-N-((6-methoxyquinolin-2-yl)methyl)-N'-isobutyrylalani namide (6b), were synthesized. Both N-nitrosoamides inhibited alpha-chymotrypsin irreversibly; they show promise as labeling reagents for the active sites of chymotrypsin-like proteases.

New NO-donors with antithrombotic and vasodilating activities, VI: thiazole-2-nitrosimines

24 new thiazole-2-nitrosimines were prepared and described by means of spectroscopical methods (NMR, IR, MS, UV). At pH 7 in cell free systems as well as in platelet rich plasma the compounds are stable against hydrolysis and do not react with the platelet glutathione. The chemical stability is underlined by the mass spectra: M+. is of high intensity and sometimes even forms the base peak (e.g. 8a). Thermal elimination of N2 is of minor importance. The =N-NO bond in solution is susceptible to cleavage by visible light. The metabolite so formed is able to inhibit the platelet aggregation induced by collagen (Born-test). Five compounds exhibit this activity in concentrations below 10 mumol/L (IC50). This is due to the release of a NO species, as could be demonstrated by the stimulation of soluble guanylate cyclase in a cell free system (e.g. 8a, KM = 72 mumol/L). In vivo the nitrosimines show antithrombotic properties. Two h after a single oral dose of 8g (60 mg/kg) a 57% inhibition of the laser induced thrombus formation in the mesenteric arterioles of rats is observed. After 8 h a 43% inhibition still is seen.

The inhibitory effect of Chinese tea and its polyphenols on in vitro and in vivo N-nitrosation

The objective of this study is to evaluate the possible role of Chinese tea as a natural inhibitor of N-nitrosation, and to compare the relative inhibitory potency of various kinds of Chinese tea in vitro and in vivo. Studies on the inhibitory effect of 145 samples of Chinese tea on the formation of N-nitrosomorpholine (NMOR) showed that the inhibitory potency of the 7 types of Chinese tea differed greatly, the average blocking rate of green tea (89.04%, n = 60), crush, tear, and curl (CTC) black tea (86.99%, n = 13), brick tea (85.40%, n = 7), jasmine tea (84.99%, n = 21), Oolong tea (82.37%, n = 9), sun-dried tea (61.99%, n = 13) and Chinese Gongfu black tea (54.98%, n = 22), were positively correlated with their polyphenols contents. The inhibitory effect of green tea and black tea on endogenous N-nitrosation was also confirmed in 3 human volunteer experiments. Drinking tea after meal had a greater effect than drinking it before meal. It is concluded that Chinese tea can exert a relatively strong inhibitory potency for N-Nitroso compounds (NOC) formation both in vitro and in humans, and the active constituents may be related to their polyphenols contents, especially the tea catechin derivatives. The results also demonstrated that the amounts of NMOR formed in vitro depended on the molecular structure of tea catechin derivatives and their molar ratios to nitrite.

[The effect of ionizing radiation on nitrosamine formation from anthropogenic precursors]

The kinetics of formation of nitrosoamines from precursors under the effect of ionizing radiation has first been quantitatively estimated, and the optimal conditions of their formation determined. The possibility of formation of nitrosoamines under the effect of low-level radiation has been investigated. Using the mathematical functions obtained from the experiments, the number of nitrosoamines, that may form under the effect of radiation in the aqueous medium, has been determined.

Synthesis of (+/-)-N-2-methylpropyl-N-1'-methylacetonyl-nitrosamine

N-2-methylpropyl-N-1-methylacetonyl-nitrosamine (NMAMPA), first isolated from moldy and normal foods, was synthesized by chemical means. The structure and molecular weight of the synthetic NMAMPA were elucidated by spectrometry. A combination of spectral and chromatographic data indicated that the synthetic NMAMPA is identical to that obtained naturally. Synthetic NMAMPA is a racemic modification, and a carcinogen which can induce esophageal and forestomach cancer in rats.

Blocking nitrosamine formation with polymers

A set of polymers have been synthesized in order to determine whether polymers containing nitrosation-reactive functional groups could effectively block nitrosamine formation. Polymers containing both hydrophobic backbones [poly[(chloromethyl)styrene], poly(ethylene oxide-co-epichlorohydrin), chloromethylated cross-linked polystyrene] and hydrophilic backbones [poly(ethylenimine) and poly(acryloyl chloride)] have been derivatized with pyrrole, 2,5-dimethylpyrrole, 2-[(methylamino)methyl]pyrrole, or hydroquinone. All of these polymers, as well as PEI itself, are effective at blocking the nitrosation of morpholine by nitrous acid. The hydrophilic polymers are much better able to compete for the available nitrosating agent in aqueous solution than are the hydrophobic polymers. Nevertheless, all of the polymers were highly effective in scavenging nitrous acid from aqueous solution prior to addition of the amine. The reaction products derived from the reactive, polymer-attached functional groups are retained on the polymer and are easily removed from mixtures of chemicals by physical means. Since nitrosamines and other N-nitroso compounds are known to be potent animal carcinogens, this work is of significance in the area of preventive chemical toxicology.

Pyrroles as effective agents for blocking amine nitrosation

The ability of 10 pyrroles to block the acidic nitrosation of morpholine has been determined by using an assay that measures their effectiveness in the presence of a 10-fold excess of amine. The log (% N-nitrosomorpholine) formed is a linear function of blocking agent concentrations ranging from 0.0 to 1.5 times the equivalents of initial nitrite. The negative slopes of these plots allow a ranking of the effectiveness of the blocking agent. Several of the pyrroles have been found to be much more effective than established blocking agents such as ascorbic acid. The following order of blocking ability has been determined: 2,5-dimethylpyrrole = 1-benzyl-2,5-dimethylpyrrole much greater than 4-methylcatechol greater than ascorbic acid = 1,2-phenylenediamine = pyrrole greater than 1,2,5-tribenzylpyrrole = 1-benzylpyrrole = octamethylporphine much greater than ammonium sulfamate = hydrazine = 2,5-diphenylpyrrole much much greater than beta-nicotyrine greater than 2-pyrrolecarboxylic acid. Pyrroles give complex mixtures devoid of N-nitroso compounds upon nitrosation.

Investigations on the origin of tobacco-specific nitrosamines in mainstream smoke of cigarettes

The origin of tobacco-specific nitrosamines (TSNA) in mainstream smoke and the possible contribution of synthesis during the smoking procedure was investigated. Addition of the nitrosamine precursors nitrate and nicotine to the tobacco prior to smoking did not change the mainstream smoke concentrations of N'-nitrosonornicotine (NNN) and 4-(methyl-nitrosamino)-1-(3-pyridyl)-1-butanone (NNK), whereas the mainstream smoke concentration of N'-nitrosoanabasine (NAB) and N'-nitrosoanatabine (NAT) increased after spiking the cigarettes with nitrate. Data for TSNA in tobacco and in mainstream smoke and for nitrate in tobacco of commercial cigarettes of the West German market, taken from previous investigations, were used to calculate the mainstream smoke/tobacco ratios for NNN and NNK. These ratios were corrected for ventilation and cigarette length. It is shown that the ratios are constant and neither depend on the nicotine level nor on the nitrate level of the tobacco except for NNK in the nitrate rich dark tobacco type cigarettes. For nonfilter cigarettes the transfer rates of NNN and NNK which had been corrected for ventilation and cigarette length amounted to 23 or 34% respectively. For filter cigarettes a transfer rate of 13% for NNN and 23% for NNK was calculated. Furthermore it is shown that the mainstream smoke/tobacco ratios for NNN and NNK are constant over the whole length of the cigarettes except for NNK in dark tobacco type cigarettes. The results of this investigation indicate that pyrosynthesis of NNN does not occur and that it is very unlikely for NNK at least for lower nitrate levels. Thus with few exceptions the TSNA burden of smokers is predominantly influenced by the amount of preformed NNN and NNK in tobacco.