Evolutionary genetics of lifespan and mortality rates in two populations of the seed beetle, Callosobruchus maculatus.

The age at which individuals die varies substantially within and between species, but we still have little understanding of why there is such variation in life expectancy. We examined sex-specific and genetic variation in adult lifespan and the shape of mortality curves both within and between two populations of the seed beetle, Callosobruchus maculatus, that differ in a suite of life history characters associated with adaptation to different host species. Mean adult lifespan and the shape of the logistic mortality curves differed substantially between males and females (males had lower initial mortality rates, but a faster increase in the rate of mortality with increasing age) and between populations (they differed in the rate of increase in mortality with age). Larger individuals lived longer than smaller individuals, both because they had lower initial mortality rates and a slower increase in the rate of mortality with increasing age. However, differences in body size were not adequate to explain the differences in mortality between the sexes or populations. Both lifespan and mortality rates were genetically variable within populations and genetic variance/covariance matrices for lifespan differed between the populations and sexes. This study thus demonstrated substantial genetic variation in lifespan and mortality rates within and between populations of C. maculatus.

Longitudinal distribution of ozone and chlorine in the human respiratory tract: simulation of nasal and oral breathing with the single-path diffusion model.

In the single-path model of the respiratory system, gas transport occurs within a conduit of progressively increasing cross-sectional and surface areas by a combination of flow, longitudinal dispersion, and lateral absorption. The purpose of this study was to use bolus inhalation data previously obtained for chlorine (Cl(2)) and for ozone (O(3)) to test the predictive capability of the single-path model and to adjust input parameters for applying the model to other exposure conditions. The data, consisting of uptake fraction as a function of bolus penetration volume, were recorded on 10 healthy nonsmokers breathing orally as well as nasally at alternative air flows of 150, 250, and 1000 ml/s. By employing published data for airway anatomy, gas-phase dispersion coefficients, and gas-phase mass transfer coefficients while neglecting diffusion limitations in the mucus phase, the single-path model was capable of predicting the uptake distribution for O(3) but not the steeper distribution that was observed for Cl(2). To simultaneously explain the data for these two gases, it was necessary to increase gas-phase mass transfer coefficients and to include a finite diffusion resistance of O(3) within the mucous layer. The O(3) reaction rate constants that accounted for this diffusion resistance, 2 x 10(6) s(-1) in the mouth and 8 x 10(6) s(-1) in the nose and lower airways, were much greater than previously reported reactivities of individual substrates found in mucus.

A hybrid computational fluid dynamics and physiologically based pharmacokinetic model for comparison of predicted tissue concentrations of acrylic acid and other vapors in the rat and human nasal cavities following inhalation exposure.

To assist in interspecies dosimetry comparisons for risk assessment of the nasal effects of organic acids, a hybrid computational fluid dynamics (CFD) and physiologically based pharmacokinetic (PBPK) dosimetry model was constructed to estimate the regional tissue dose of inhaled vapors in the rat and human nasal cavity. Application to a specific vapor would involve the incorporation of the chemical-specific reactivity, metabolism, partition coefficients, and diffusivity (in both air and tissue phases) of the vapor. This report describes the structure of the CFD-PBPK model and its application to a representative acidic vapor, acrylic acid, for interspecies tissue concentration comparisons to assist in risk assessment. By using the results from a series of short-term in vivo studies combined with computer modeling, regional nasal tissue dose estimates were developed and comparisons of tissue doses between species were conducted. To make these comparisons, the assumption was made that the susceptibilities of human and rat olfactory epithelium to the cytotoxic effects of organic acids were similar, based on similar histological structure and common mode of action considerations. Interspecies differences in response were therefore assumed to be driven primarily by differences in nasal tissue concentrations that result from regional differences in nasal air flow patterns relative to the species-specific distribution of olfactory epithelium in the nasal cavity. The results of simulations with the seven-compartment CFD-PBPK model suggested that the olfactory epithelium of the human nasal cavity would be exposed to tissue concentrations of acrylic acid similar to that of the rat nasal cavity when the exposure conditions are the same. Similar analysis of CFD data and CFD-PBPK model simulations with a simpler one-compartment model of the whole nasal cavities of rats and humans provides comparable results to averaging over the compartments of the seven-compartment model. These results indicate that the general structure of the hybrid CFD-PBPK model applied in this assessment would be useful for target tissue dosimetry and interspecies dose comparisons for a wide variety of vapors. Because of its flexibility, this CFD-PBPK model is envisioned to be a platform for the construction of case-specific inhalation dosimetry models to simulate in vivo exposures that do not involve significant histopathological damage to the nasal cavity.

Application of a hybrid computational fluid dynamics and physiologically based inhalation model for interspecies dosimetry extrapolation of acidic vapors in the upper airways.

This study provides a scientific basis for interspecies extrapolation of nasal olfactory irritants from rodents to humans. By using a series of short-term in vivo studies, in vitro studies with nasal explants, and computer modeling, regional nasal tissue dose estimates were made and comparisons of tissue doses between species were conducted. To make these comparisons, this study assumes that human and rodent olfactory epithelium have similar susceptibility to the cytotoxic effects of organic acids based on similar histological structure and common mode of action considerations. Interspecies differences in susceptibility to the toxic effects of acidic vapors are therefore assumed to be driven primarily by differences in nasal tissue concentrations that result from regional differences in nasal air flow patterns relative to the species-specific distribution of olfactory epithelium in the nasal cavity. The acute, subchronic, and in vitro studies have demonstrated that the nasal olfactory epithelium is the most sensitive tissue to the effects of inhalation exposure to organic acids and that the sustentacular cells are the most sensitive cell type of this epithelium. A hybrid computational fluid dynamics (CFD) and physiologically based pharmacokinetic (PBPK) dosimetry model was constructed to estimate the regional tissue dose of organic acids in the rodent and human nasal cavity. The CFD-PBPK model simulations indicate that the olfactory epithelium of the human nasal cavity is exposed to two- to threefold lower tissue concentrations of a representative inhaled organic acid vapor, acrylic acid, than the olfactory epithelium of the rodent nasal cavity when the exposure conditions are the same. The magnitude of this difference varies somewhat with the specific exposure scenario that is simulated. The increased olfactory tissue dose in rats relative to humans may be attributed to the large rodent olfactory surface area (greater than 50% of the nasal cavity) and its highly susceptible location (particularly, a projection of olfactory epithelium extending anteriorly in the dorsal meatus region). In contrast, human olfactory epithelium occupies a much smaller surface area (less than 5% of the nasal cavity), and it is in a much less accessible dorsal posterior location. In addition, CFD simulations indicate that human olfactory epithelium is poorly ventilated relative to rodent olfactory epithelium. These studies suggest that the human olfactory epithelium is protected from irritating acidic vapors significantly better than rat olfactory epithelium due to substantive differences in nasal anatomy and nasal air flow. Furthermore, the general structure of the hybrid CFD-PBPK model used for this study appears to be useful for target tissue dosimetry and interspecies dose comparisons for a wide range of inhaled vapors.

A CFD-PBPK hybrid model for simulating gas and vapor uptake in the rat nose.

In laboratory studies of rodents, the inhalation of organic vapors often results in preferential damage to olfactory epithelium. Such focal lesion formation may be due either wholly or in part to a corresponding nonuniformity in the spatial distribution of vapor uptake within the nasal cavities. As a tool for determining this dose distribution, a mathematical model based on a combination of computational fluid dynamics (CFD) and physiologically based pharmacokinetic (PBPK) modeling was developed for simulating toxicant vapor uptake in the rat nose. The nasal airways were subdivided into four distinct meatuses selected such that each contained a major air flow stream. Each meatus was further divided into four serial regions attached to separate tissue stacks containing mucus, epithelial, and subepithelial compartments. Values for the gas-phase mass transfer coefficients and gas flows in the 16 airway regions were determined by a solution of the Navier-Stokes and convection-diffusion equations using commercially available CFD software. These values were then input to a PBPK simulation of toxicant transport through the 16 tissue stacks. The model was validated by using overall uptake data from rodent inhalation studies for three "unreactive" vapors that were either completely inert (i.e., acetone), reversibly ionized in aqueous media (i.e., acrylic acid), or prevented from being metabolized by an enzyme inhibitor (i.e., isoamyl alcohol). A sensitivity analysis revealed that accurate values of the mass transfer coefficient were not necessary to simulate regional concentrations and uptake of unreactive vapors in the rat nose, but reliable estimates of diffusion coefficients in tissue were crucial for accurate simulations.

Longitudinal distribution of O3 absorption in the lung: gender differences and intersubject variability.

Because the National Ambient Air Quality Standard for ozone (O3) is intended to protect the most sensitive individuals in the general population, it is necessary to identify sources of intersubject variation in the exposure-dose-response cascade. We hypothesize that differences in lung anatomy can modulate exposure-dose relationships between individuals, and this results in differences between their responsiveness to O3 at a fixed exposure condition. During quiet breathing, the conducting airways remove the majority of inhaled O3, so the volume of this region should have an important impact on O3 dose distribution. Employing the bolus inhalation method, we measured the distribution of O3 absorption with respect to penetration volume (Vp), and using the Fowler single-breath N2 washout method, we determined the dead space volume (VD) in the lungs of 10 men and 10 women at a fixed respiratory flow of 250 ml/s. On average, the women absorbed O3 at smaller Vp than the men, and the women had smaller VD than the men. When expressed in terms of Vp/VD, the absorption distribution of the men and women was indistinguishable. Moreover, an interpretation of the O3 distribution in terms of an intrinsic mass transfer parameter (Ka) indicated that differences between the O3 dosimetry in all subjects, whether men or women, could be explained by a unique correlation with anatomic dead space: Ka (in s-1) = 610 VD-105 (in ml). Application of this result to measurements of O3 exposure response indicated that previously reported gender differences may be due to a failure in properly accounting for tissue surface within the conducting airways.

Longitudinal distribution of ozone absorption in the lung: simulation with a single-path model.

A one-dimensional unsteady state diffusion model was used as a basis for simulating the absorption (lambda), breakthrough (V(B)), and dispersion (sigma2) of inhaled ozone boluses as a function of penetration (V(P)) into intact human lungs. The model idealized the respiratory system as a single equivalent tube with cross-sectional and surface areas that varied as a function of longitudinal position. Longitudinal gas transport in the lumen of the equivalent tube occurred by the joint action of bulk flow and a dispersion coefficient, D. Lateral absorption between respired gas and the tube wall was characterized by an overall mass transfer coefficient, K. By inputting published values of anatomic dimensions scaled to a 160-ml conducting airway volume, D values previously reported for inert insoluble gases, and K values equal to gas-phase transfer coefficients determined in physical lung models, a reasonable simulation of the lambda-V(P) distribution measured at a 250 ml/sec respiratory flow was obtained. Simulations of the corresponding V(B)-V(P) and sigma2-V(P) distributions both exhibited the correct shapes but underestimated the actual values. Although the addition of an estimated tissue resistance to K resulted in a poorer simulation of the data, an increase in conducting airway volume from a value of 160 ml estimated by the subjects' CO2 dead space to a value of 200 ml substantially improved the V(B)-V(P) and sigma2-V(P) simulations without sacrificing the quality of the lambda-V(P) simulation. We conclude that the inclusion of a tissue diffusion resistance is not necessary to properly simulate bolus inhalation data during quiet breathing, but a reliable measurement of conducting airway volume is crucial.

Activation of a neurofilament kinase, a tau kinase, and a tau phosphatase by decreased ATP levels in nerve growth factor-differentiated PC-12 cells.

Brain pathology in Alzheimer disease and in aged controls shows hyperphosphorylation of tau and of neurofilament proteins. Roder and Ingram [Roder, H.M. & Ingram, V.M. (1991) J. Neurosci. 11, 3325-3343 and Roder, H.M., Eden, P.A. & Ingram, V.M. (1993) Biochem. Biophys. Res. Commun. 193, 639-647] previously reported that the brain protein kinase PK40erk can hyperphosphorylate both tau and neurofilaments and interestingly, is strongly inhibited by ATP uncomplexed with Mg2+. We now report that the mitochondrial uncoupler carbonyl cyanide p-trifluoro-methoxyphenylhydrazone decreases ATP levels in rat pheochromacytoma (PC-12) cells differentiated with nerve growth factor and activates a neurofilament kinase, a tau kinase, and, unexpectedly, a tau phosphatase--either PP1 or PP2A. Such aberrant modulation of protein phosphorylation patterns could be the common biochemical basis for senile dementia and for Alzheimer disease and could explain the late-onset etiology of both conditions.

Retained barium n the appendix: diagnostic and clinical significance.

The significance of prolonged retention of barium in the appendix in an asymptomatic patient has been debated. Four patients, with retained barium in the appendix for several months after gastrointestinal barium studies, who then developed acute appendicitis, are reported and analyzed. Thirty-one patients who retained appendiceal barium longer than 72 hr after radiographic examination of the gastrointestinal tract were followed for over 1 year. No patient developed appendicitis. Five patients underwent abdominal surgery for other indications and there was no evidence of appendicitis. In 11 patients, who had abdominal radiographs 6 days to 4 months after detection of appendiceal barium, the barium had disappeared. The connotation of the term "barium appendicitis" as initially reported is questioned. Preliminary data in this report suggest that no causal relationship exists between prolonged retention of barium and future acute appendicitis and that normal appendices can expel barium in variable time periods. Etiologic connotation between prolonged appendiceal barium retention and future acute appendicitis should be erased. Retained barium in the appendix can be used as an acid in the precise radiographic diagnosis of acute appendicitis.