Reduced toxicological activity of cigarette smoke by the addition of ammonium magnesium phosphate to the paper of an electrically heated cigarette: smoke chemistry and in vitro cytotoxicity and genotoxicity.

The effects of the addition of ammonium magnesium phosphate (AMP) to the paper of an electrically heated cigarette (EHC) prototype on smoke composition and toxicity were quantified and the underlying mechanisms investigated. Smoke from EHC prototypes with and without AMP and from conventional cigarettes, i.e. the University of Kentucky Standard Reference Cigarette 1R4F and eight American-blend market cigarettes, was compared. Endpoints for comparison were smoke chemistry, where toxic constituents were measured, cytotoxic activity, as measured in murine fibroblasts embryo cells by the Neutral Red Uptake Assay, and genotoxic activity, as measured in bacteria by the Salmonella Reverse Mutation Assay and in murine lymphoma cells by the TK Assay. The addition of AMP to the EHC led to a reduction of toxic substances and toxicological activity of approximately 30% compared to the EHC without AMP. Compared to the conventional cigarettes, the EHC with AMP showed reductions of 75-90%. Smoke from the EHCs generated in nitrogen atmospheres supplemented with different concentrations of ammonia and oxygen was assayed for its in vitro cytotoxicity and genotoxicity. The results indicate that the ammonia released by AMP at the heating site of the EHC is responsible for the reductions in cytotoxicity and mutagenicity for the EHC with AMP compared with the EHC without AMP. Thus, while the EHC approach distinctly reduces toxic smoke constituents compared to conventional cigarettes, the use of AMP in the paper of an EHC leads to further distinct reductions. In the study presented here, in vitro assays were used as quantitative tools to investigate toxicity-related mechanisms.

Chemical composition, cytotoxicity and mutagenicity of smoke from US commercial and reference cigarettes smoked under two sets of machine smoking conditions.

Eight blended US market cigarettes, two blended reference cigarettes, one Bright tobacco only reference cigarette and an electrically heated prototype cigarette (EHC) were smoked under US Federal Trade Commission (FTC)/International Organisation for Standardisation (ISO) conditions and under Massachusetts Department of Public Health (MDPH) conditions. Smoke was analysed for chemical composition and in vitro toxicity. Yields (quantity/cigarette) of smoke constituents were higher under MDPH conditions compared to FTC/ISO conditions (market and reference average approximately 2.5 times; EHC approximately 1.6 times). Consistent with the higher yields, in vitro toxicity per cigarette was also higher under MDPH conditions. Concentrations (quantity/mg TPM) of nearly all smoke constituents measured decreased with increasing total particulate matter (TPM) yields as regression analyses indicated. Higher TPM yields also tended to be associated with slightly less cytotoxic and mutagenic activity per milligram TPM. Blended reference cigarettes tracked market cigarettes with similar TPM yield. The Bright cigarette displayed high cytotoxicity but low mutagenicity, while in vitro activity of the EHC was remarkably low. The TPM-dependent decreases for the market range of 5-20 mg TPM/cigarette were about 20%, irrespective of whether the increased yields were due to smoking conditions or cigarette construction. At the same TPM yield, the smoke constituent concentrations and in vitro toxicity were similar for low- and high-yield cigarettes.

Toxicological evaluation of an electrically heated cigarette. Part 2: Chemical composition of mainstream smoke.

The chemical composition of mainstream smoke from an electrically heated cigarette (EHC) and that of mainstream smoke from the University of Kentucky Reference Cigarette 1R4F was analyzed. In contrast to the 1R4F, which is a conventional, lit-end cigarette, the EHC is smoked in a microprocessor-controlled lighter with electrical heater elements. The electrical heating causes the tobacco under the heater element to burn at a low temperature during each puff. A comprehensive list of chemical constituents was analyzed in mainstream smoke. The list is a combination of those compounds suggested for analysis in cigarette smoke by a US Consumer Product Safety Commission proposal in 1993, and those cigarette smoke constituents identified by the International Agency on Research on Cancer as being present in cigarette smoke and characterized as carcinogens. The low pyrolysis/combustion temperature of tobacco in the EHC causes distinct shifts in the composition of the smoke compared with a conventional cigarette. A significant drop was seen in the yields of almost all toxicologically relevant constituents. On a per cigarette basis almost two-thirds of the constituents were reduced by at least 80%, whereas on an equal total particulate matter basis about two-thirds of the constituents were reduced by at least 50%, with many constituents reduced by more than 90%.

Evaluation of the potential effects of ingredients added to cigarettes. Part 2: chemical composition of mainstream smoke.

Cigarette mainstream smoke from blended research cigarettes with and without the addition of ingredients was analyzed for its chemical composition. In total, 333 ingredients commonly used in cigarette manufacturing were assigned to three different groups. Each group of ingredients was introduced at a low and a high level to the test cigarettes. The list of the 51 smoke constituents determined is based on those analytes suggested for analysis in a US Consumer Product Safety Commission proposal for low ignition cigarettes and cigarette smoke constituents identified by the International Agency for Research on Cancer as worthy of concern and characterized as carcinogens. An increase in the yield of total particulate matter (TPM) in the range of 13 to 28% relative to the control cigarette without ingredients was observed for all test cigarettes. This was presumably caused by the higher transfer rates of the added ingredients to the smoke compared to the transfer from the tobacco part of the filler. When the yields of individual constituents were normalized to the TPM yields, a reduction in the majority of the constituents was observed when compared to the control. For one of the ingredient groups this reduction was especially high: for phenols a maximum of 70%, for polycyclic aromatic hydrocarbons 50%, and for N-nitrosamines 45%. An increase in the amount relative to TPM was observed for a few smoke constituents: hydrogen cyanide and cadmium (one ingredient group), formaldehyde (one ingredient group), and resorcinol and lead (two ingredient groups). These results are consistent with the lack of any increased activity in the in vitro and in vivo assays in this same series of studies (Food and Chemical Toxicology 2002, 40, 105-111; Food and Chemical Toxicology 2002, 40, 113-131). An overall assessment of our data suggests that these ingredients, when added to the tobacco, do not add to the toxicity of smoke, even at the elevated levels tested in this series of studies.

Hemoglobin adducts in rats chronically exposed to room-aged cigarette sidestream smoke and diesel engine exhaust.

Under controlled conditions with exaggerated concentrations of environmental aerosols, the biologically effective dose markers suggested in the literature as being specific for ETS (i.e., HPB Hb adducts for TSNA exposure) and DEE (i.e., l-aminopyrene Hb adducts for l-nitropyrene exposure) did not respond. A slight but dose-dependent increase in 4-ABP Hb adduct levels was seen in RASS-exposed rats.

5'-hydroxycotinine-N-oxide, a new nicotine metabolite isolated from rat urine.

1. 5'-Hydroxycotinine-N-oxide, 5-(3-pyridyl-N-oxide)-5-hydroxy-1-methyl-pyrrolidone-2, was identified as a new in vivo metabolite of nicotine. 2. The new metabolite was isolated from the urine of rats treated with S-nicotine and characterized using chemical and spectrometric methods. 3. 5'-Hydroxycotinine-N-oxide was synthesized and characterized by MS and by infrared as well as 1H- and 13C-NMR spectroscopy. 4. Identity of the new metabolite with synthetic 5'-hydroxycotinine-N-oxide was demonstrated by comparing the MS and 1H-NMR spectroscopy data as well as by co-chromatography of a spiked urine sample.