Physical and physicochemical factors effecting transport of chlorohydrocarbon gases from lung alveolar air to blood as measured by the causation of narcosis

This systematic investigation examines gas transport in the lung for two sets of chlorohydrocarbons (CHCs): the chloromethanes (C1) and chloroethanes (C2). The C1 series includes chloromethane, methylene chloride, chloroform, and carbon tetrachloride, and the C2 series includes chloroethane, 1,2-dichloroethane, 1, 1, 2-trichloroethane, and 1, 1, 2, 2-tetrachloroethane. Most CHC gases cause narcosis. The comprehensive narcosis work of Lehmann and colleagues on CHCs was used as a basis for the narcosis endpoint in the present examination. The sites for narcosis are located in the brain (midline cortex and posterior parietal area), the spine, and at many peripheral nerve sites. Central nervous system (CNS) exposure executes a multisite, neural transmission set of inhibitions that promotes rapid loss of consciousness, sensory feeling, and current and stored memory while providing temporary amnesia. Absorption into the system requires dissolution into many lipid membranes and binding to lipoproteins. Lipophilicity is a CHC property shared with many anesthetics according to the Meyer-Overton Rule. Many structurally different lipid chemicals produce the narcosis response when the lipid concentration exceeds -67 mM. This suggests narcotic or anesthetic dissolution into CNS membranes until the lipid organization is disrupted or perturbed. This perturbation includes loading of Na(+)- and K(+)-channel transmembrane lipoprotein complexes and disrupting their respective channel functional organizations. The channel functions become attenuated or abrogated until the CHC exposure ceases and CHC loading reverses. This investigation demonstrates how the CHC physical and chemical properties influence the absorption of these CHCs via the lung and the alveolar system on route to the blood. Narcosis in test animals was used here as an objective biological endpoint to study the effects of the physical factors Bp, Vp, Kd (oil: gas) partition, Henry's constant (HK), and water solubility (S%) on gas transport. Narcosis is immediate after gas exposure and requires no chemical activation only absorption into the blood and circulation to CNS narcotic sites. The three physical factors Bp, K(d) (oil: air), and S% vary directly with unitary narcosis (UN) whereas Vp and HK vary inversely with UN in linear log-log relationships for the C2 series but not for the C1 series. Physicochemical properties of C1 series gases indicate why they depart from what is usually assumed to be an Ideal Gas. An essential discriminating process in the distal lung is the limiting alveolar film layer (AFL) and the membrane layer of the alveolar acini. The AFL step influences gas uptake by physically limiting the absorption process. Interaction with and dissolution into aqueous solvent of the AFL is required for transport and narcotic activity. Narcotics or anesthetics must engage the aqueous AFL with sufficient strength to allow transport and absorption for downstream CNS binding. CHCs that do not engage well with the AFL are not narcotic. Lipophilicity and amphipathicity are also essential solvency properties driving narcotics' transport through the alveolar layer, delivery to the blood fats and lipoproteins, and into critical CNS lipids, lipoproteins, and receptor sites that actuate narcosis. AFL disruption is thought to be strongly related to a number of serious pulmonary diseases such acute respiratory distress syndrome, infant respiratory distress syndrome, emphysema, chronic obstructive pulmonary disease, asthma, chronic bronchitis, pneumonia, pulmonary infections, and idiopathic pulmonary fibrosis. The physical factors (Bp, Vp, Kd [oil: gas] partition, Henry's constant, and water solubility [S%]) combine to affect a specific transport through the AFL if lung C > C(0) (threshold concentration for narcosis). The degree of blood CHC absorption depends on dose, lipophilicity, and lung residence time. AFL passage can be manipulated by physical factors of increased pressure (kPa) or increased gas exposure (moles). Molecular lipophilicity facilitates narcosis but lipophilicity alone does not explain narcosis. Vapor pressure is also required for narcosis. Narcotic activity apparently requires stereospecific processing in the AFL and/or down-stream inhibition at stereospecific lipoproteins at CNS inhibitory sites. It is proposed that CHCs likely cannot proceed through the AFL without perturbation or disruption of the integrity of the AFL at the alveoli. CHC physicochemical properties are not expected to allow their transport through the AFL as physiological CO(2) and O(2) naturally do in respiration. This work considers CHC inspiration and systemic absorption into the blood with special emphasis on the CHC potential perturbation effects on the lipid, protein liquid layer supra to the alveolar membrane (AFL). A heuristic gas transport model for the CHCs is presented as guidance for this examination. The gas transport model can be used to study absorption for other gas delivery endpoints of environmental concern such as carcinogens.

Analysis of chloroethane toxicity and carcinogenicity including a comparison with bromoethane

Chloroethane (CE) gas carcinogenicity is analyzed and determined from a National Toxicology Program (NTP) bioassay where an inhalation concentration of 15,000 ppm CE gas in air produced the highest incidence of an uncommon-to-rare tumor ever observed by the NTP. Persistently inhaled CE produces endometrial cancers in female mice. The first-tumor-corrected uterine endometrial incidence (I) in B6C3F1 mice is 90%, but no significant tumors occurred in F344 rats. The endometrial cancers dispersed by 1) migrating locally to the adjacent myometrium, 2) then migrating to the bloodstream by intravasation, 3) entering 17 distal organs by extravasation and adapting to the new tissue environment. Distal cancers retained sufficient endometrial cell features to be recognized at each metastatic site. CE produced one of the highest metastasis rates ever observed by NTP of 79%. Comparing CE with bromoethane (BE), a structural analogue, it was found that BE too produced rare murine endometrial cancers yielding the second highest NTP incidence rate of I = 58% with a similar high malignancy rate of 56%. Because of the historical rarity of endometrial tumors in the B6C3F1 mouse, both of these SAR haloethanes seem to be evoking a strong, related carcinogenic potential in B6C3F1 mice, but not in F344 rats. The question of whether humans are similar to mice or to rats is addressed here and in Gargas, et al., 2008. The powerful carcinogenesis caused by these halohydrocarbons may have been caused by excessive and metabolically unresolved acetaldehyde (AC) which is directly generated by Cyp2E1 in the oxidative elimination of CE. With >95% AC metabolic production, as predicted from pharmacokinetic (PK) studies depending on CE exposure, AC is the main elimination intermediate. AC is a known animal carcinogen and a strongly suspected human carcinogen. Also, CE causes incipient decreases of tissue essential glutathione pools [GSH] by Phase II conjugation metabolic elimination of CE (and BE), by glutantione transferase (GST), in most organs (except brain) exposed to high circulating CE and it metabolites. In three laboratories, an excessive stress reaction of hyperkinesis was observed only during 15,000 ppm gas exposure but not when the exposure ceased or when exposure was presented at 150 ppm. Test rodents other than the female mice did not exhibit a pattern of visible stress nor did they have a carcinogenic response to CE gas. Unremitting stress has been documented to contribute a feedback to the hypothalamus which stimulates the hypothalamic-pituitary-axis (HPA), which in turn, induces the adrenal glands. Because estrus and estrogen and progesterone levels were unaltered by CE gas, the adrenal over stimulation, causing high steroid output, may be the penultimate step in this extraordinary carcinogenic response. High adrenal production of corticosteroids could adversely promote endometrial cells to cancers in mice − a mechanism that has already been observed in humans.

Framework analysis for the carcinogenic mode of action of nitrobenzene

Nitrobenzene (CASRN: 98-95-3) has been shown to induce cancers in many tissues including kidney, liver, and thyroid, following chronic inhalation in animals. However, with a few exceptions, genotoxicity assays using nitrobenzene have given negative results. Some DNA binding/adduct studies have brought forth questionable results and, considering the available weight of evidence, it does not appear that nitrobenzene causes cancer via a genotoxic mode of action. Nitrobenzene produces a number of free radicals during its reductive metabolism, in the gut as well as at the cellular level, and generates superoxide anion as a by-product during oxidative melabolism. The reactive species generated during nitrobenzene metabolism are considered candidates for carcinogenicity. Furthermore, several lines of evidence suggest that nitrobenzene exerts its carcinogenicity through a non-DNA reactive (epigenetic) fashion, such as a strong temporal relationship between non-, pre-, and neoplastic lesions leading to carcinogenesis. In this report, we first describe the absorption, distribution, metabolism, and excretion of nitrobenzene followed by a summary of the available genotoxicity studies and the only available cancer bioassay. We subsequently refer to the mode of action framework of the U.S. Environmental Protection Agency's 2005 Guidelines for Carcinogen Risk Assessment as a basis for presenting possible modes of action for nitrobenzene-induced cancers of the liver, thyroid, and kidney, as supported by the available experimental data. The rationale(s) regarding human relevance of each mode of action is also presented. Finally, we hypothesize that the carcinogenic mode of action for nitrobenzene is multifactorial in nature and reflective of free radicals, inflammation, and/or altered methylation.

Bromoethane, chloroethane and ethylene oxide induced uterine neoplasms in B6C3F1 mice from 2-year NTP inhalation bioassays: pathology and incidence data revisited

Chloroethane, bromoethane and ethylene oxide represent a unique set of chemicals that induce endometrial neoplasms in the uterus of B6C3F1 mice following an inhalation route of exposure. The results of the NTP's chronic bioassays with these three compounds resulted in an unusually high incidence of uterine epithelial neoplasms in B6C3F1 mice (chloroethane 86%, bromoethane 56%) and a lower incidence for ethylene oxide (10%). The uterine neoplasms were classified as adenomas, adenocarcinomas, and squamous cell carcinomas for bromoethane, and as adenocarcinomas for both chloroethane and ethylene oxide. The adenocarcinomas and squamous cell carcinomas were invasive into the myometrium and the serosa, and metastasized to a wide variety of organs. Metastatic sites included most commonly the lung, lymph nodes, and ovary at unusually high rates of metastases (79% for chloroethane and 38% for bromoethane). Because of the dramatically high rates of uterine neoplasms (induced by chemicals given by the inhalation route) and metastases, a re-evaluation of the pathology and incidence data was undertaken. The earlier results were confirmed. The mechanism of uterine carcinogenesis by chloroethane, bromoethane and ethylene oxide is unclear.

Nitrobenzene carcinogenicity in animals and human hazard evaluation

Nitrobenzene (NB) human cancer studies have not been reported, but animals studies have. Three rodent strains inhaling NB produce cancer at eight sites. B6C3F1 mice respond with mammary gland malignant tumors and male lung and thyroid benign tumors, F344/N male rats respond with liver malignant tumors and thyroid and kidney benign tumors, while females respond with endometrial polyps. Male Sprague-Dawley rats (CD strain) respond with liver benign tumors. NB is oxidized to various phenolic metabolites, while also being reduced in the cecum and systemically in the microsomes to nitrosobenzene (NOB), phenylhydroxylamine (PH), related free radicals, and aniline (AN). Based on structural and mechanistic similarities, NB compares with other animal and human carcinogenic nitroarenes and aromatic amines. Reduced NB first forms the nitroanion free radical, which can react with O2 to form superoxide O2*. Repeated NB dosing produces a persistent redox couple NOB<==>PH in red blood cells (RBCs) that generates met-Hb and expends NAD(P)H. NOB forms activated glutathione (GSH) conjugates. These biochemical effects may lead to critical redox imbalances and macromolecular binding. Known NB effects are hemosiderosis, methemoglobinemia, and anemia--and now dispersed cancer in rodents. On the basis of animal, metabolic and structure-activity studies, NB is determined to be a probable human carcinogen by any route of exposure.

Nitrobenzene potential human cancer risk based on animal studies

Inhaled nitrobenzene (NB) in animals produces cancer at eight sites in three rodent strains. B6C3F1 mice respond with mammary gland malignant tumors and male lung and thyroid benign tumors, and F344/N male rats respond with liver malignant tumors and thyroid and kidney benign tumors, while females respond with endometrial polyps. Male Sprague-Dawley male rats (CD strain) respond with liver benign tumors. NB is oxidized to various phenolic metabolites, while also being reduced to nitrosobenzene (NOB), phenylhydroxylamine (PH), related free radicals, and aniline (AN) in the cecum by bacteria and in the body by the microsomes. In reduction, NB first forms the nitroanion free radical, which can react with O2 to form O2*-. Repeated NB dosing produces a persistent redox couple NOB<==>PH in red blood cells that generates met-Hb and expends NAD(P)H. NOB forms activated glutathione conjugates. These biochemical effects may lead to critical redox imbalances and macromolecular binding. Known effects are hemosiderosis, methemoglobinemia, and anemia--and now dispersed cancer in rodents. Based on structural and mechanistic similarities, NB compares with other animal and human carcinogenic nitroarenes and aromatic amines. The cancer hazard evaluation of NB is that it is a probable human carcinogen by any route of exposure. The maximum response is in F344/N male rats which is used for dose-response modelling. The model to estimate the upper 95% confidence limit (UCL95%) of NB human carcinogenicity is a no-threshold, linear low-dose, and multistaged animal model (LMS). The UCL95% of cancer slope is estimated to be 0.11(6) mg/kg/day (mkd). At de minimus risk (1:10(6)), the virtually safe dose (VSD) is estimated to be 9.1 ng/kg/day (nkd).

Gap junction function and cancer

Gap junctions (GJs) provide cell-to-cell communication of essential metabolites and ions. GJs allow tissues to average responses, clear waste products, and minimize the effects of xenobiotics by dilution and allowing steady-state catabolism. Many chemicals can adversely affect the membrane GJ assembly causing reversible alterations in GJ intercellular communication. During toxicity essential metabolites, ions, and regulators are not shared homeostatically throughout a tissue community. Alterations in metabolic circuits are thought to interrupt organ integration. Persistent GJ perturbation can cause chronic effects (e.g., cancer), and many tumor promoters inhibit GJ intercellular communication. Liver precancerous foci intracommunicate (but at a reduced level) and intercommunicate improperly (or not at all) across the foci boundary to normal cells. In time, foci can become less regulated and more isolated within the tissue. GJs remain reduced quantitatively in the tumor progression stage and may be qualitatively altered in metastasis since connections are made between the primary tumor cells and foreign host cells at the secondary metastatic site. Cell sorting and binding mechanisms by the cell adhesion molecules and integrins may also be altered at secondary sites. This may allow the relocation of primary tumor cells and nurturance via GJs at the secondary site.

Ethylene dibromide residues in biscuits and commercial flour

Flour and biscuit samples from a school lunch program were analyzed for ethylene dibromide (EDB). Flour samples were extracted with hexane at room temperature with maximum extraction of EDB in 4 days. Biscuits were extracted by steam distillation with hexane; optimum recoveries were obtained by a triple extraction of the sample. Recoveries of EDB from flour and biscuits ranged from 85 to 103% as determined by gas-liquid chromatography on a 15% OV-17 column and a 63Ni electron capture detector. Random samples were confirmed by gas chromatography-mass spectrometry. From less than 8 ppb to 4 ppm EDB were determined in flour and less than 0.5 ppb to 260 ppb in biscuits. Possible sources for the higher values are discussed.

Ethylene Dibromide Residues in Biscuits and Commercial Flour

Flour and biscuit samples from a school lunch program were analyzed for ethylene dibromide (EDB). Flour samples were extracted with hexane at room temperature with maximum extraction of EDB in 4 days. Biscuits were extracted by steam distillation with hexane; optimum recoveries were obtained by a triple extraction of the sample. Recoveries of EDB from flour and biscuits ranged from 85 to 103% as determined by gas-liquid chromatography on a 15% OV-17 column and a 63Ni electron capture detector. Random samples were confirmed by gas chromatography- mass spectrometry. From &lt;8 ppb to 4 ppm EDB were determined in flour and &lt;0.5 ppb to 260 ppb in biscuits. Possible sources for the higher values are discussed.

Secondary structure of ovalbumin messenger RNA

The secondary structure of highly purified ovalbumin mRNA was studied by automated thermal denaturation techniques and the data were subjected to computer processing. Comparative studies with 20 natural and synthetic model nucleic acids suggested that the secondary structure of ovalbumin mRNA possesses the following features: the extent of base pairing of ovalbumin mRNA is similar to that found in tRNAs or ribosomal RNAs; the secondary structure of ovalbumin mRNA is more thermolabile than any of the model compounds tested, including the copolymer poly(A-U); ovalbumin mRNA does not have extensive G-C rich stems as found in tRNAs or ribosomal RNAs; the base composition of the double-stranded regions reveals 54% G-C residues which was significantly higher than that noted in the whole molecule (approximately 41.5% G-C). The presence of 46% A-U pairs in short stems of about five base pairs would have a very large destabilizing effect on the secondary structure of ovalbumin mRNA. However, at 0.175 M monovalent cations and 36 degrees C most of the secondary structure of ovalbumin mRNA is preserved. These data suggest that the double-stranded regions in ovalbumin mRNA are of sufficient length to provide the necessary stability for maintaining the open loop regions in an appropriate conformation which may be required for the biological function of ovalbumin mRNA. Furthermore, the lability of the double-stranded regions in ovalbumin mRNA may also be important for the biological function of this mRNA.

Determination of secondary structure in rabbit globin messenger RNA by thermal denaturation

The secondary structure of highly purified globin messenger RNA has been investigated by alkaline hydrolysis, nuclease digestion, and thermal denaturation. The thermal denaturation properties of globin messenger have been compared to poly(U), poly (A), and a synthetic random sequence RNA copolymer. From these studies it is concluded that globin mRNA contains considerable secondary structure and that the amount of helical structure is greater than that which occurs with a random sequence polyribonucleotide. Globin mRNA contains, by comparison to the secondary structures of native DNA, tRNAs, or 18S rRNA, helices with involve 55-62% of the bases or 58-68% if a correction is made for the 3'-terminal poly(A) segment. The helices of globin mRNA appear to be unique as differences in the NaCl stabilization of this RNA have been noted when compared to other naturally ooccurring and synthetic RNAs. Comparison of the hyperchromicity maxima, obtained at 260 and 280 nm for globin mRNA and 18S rRNA, indicates that the helices of the two RNAs contain similar numbers of G-C base pairs. Differential analysis of NaCl stabilization curves indicate three discrete thermally denaturable helix types in globin mRNA.

Preparation and preliminary characterization of purified ovalbumin messenger RNA from the hen oviduct

Preparation of milligram amounts of purified ovalbumin mRNA was accomplished by a sequential combination of precise sizing techniques with the selective purification of the poly(A) containing RNA by either affinity chromatography or adsorption to nitrocellulose filters. Several new techniques were applied to the purification of ovalbumin mRNA including Sepharose 4B chromatography and agarose gel electrophoresis in the presence of 6 M urea at pH 3.5. All the procedures used were adapted on a preparative sacle to the fractionation of large quantities of RNA. The purity of the ovalbumin mRNA was assessed by several independent criteria. (1) Purified ovalbumin mRNA migrated as a single band during both agarose-urea and formamide-polyacrylamide gel electrophoresis at pH 3.5 and 7.4, respectively. A single absorbance peak containing all of the ovalbumin mRNA activity was also found using linear formamide-sucrose gradients. (2) Determination of both total mRNA activity and ovalbumin mRNA activity in the wheat germ cell-free translation assay revealed that 92% of the total peptides synthesized were specifically immunoprecipitable with an ovalbumin antiserum. (3) Analysis of the total peptides synthesizied in the wheat germ assay by sodium dodecyl sulfate polyacrylamide gel electrophoresis demonstrated the presence of a single radioactive peak that corresponded exactly to a specifically immunoprecipitable ovalbumin standard. Thus, based on these observations ovalbumin mRNA appears to be greater than 95% pure. A preliminary estimation of the molecular weight of purified ovalbumin mRNA by formamide-containing sucrose gradients yielded a value of 520,000 or approximately 1600 nucleotides. This value was considerably less than the value of 900,000 obtained by gel electrophoresis under denaturing conditions. Analysis of the poly(A) content by a hybridization assay with (3H)poly(U) revealed the presence of a poly(A) region containing approximately 70 adenosine residues. Thus, the size of the ovalbumin mRNA is considerably greater than that required to code for a protein of 387 amino acids. The availability of large quantities of purified ovalbumin mRNA should now permit a more thorough analysis of its physical and chemical properties.