Effects of acute and chronic dimethylamine exposure on the nasal mucociliary apparatus of F-344 rats

Eosinophilic globules (syn. hyaline inclusions) and protein crystalloids in the nasal mucosa of rats treated with synthetic amorphous silica, an unspecific chitinase-like-protein-positive background lesion

In a 13-week inhalation toxicity study with three recovery periods (3, 6, and 12 months), Crl: WI rats were allocated to nine groups, each containing 25 animals per sex. Eight groups were treated daily by inhalation with the test items at concentrations of 0.5, 1.0, 2.5, or 5.0 mg/m3 (SAS 1 groups 2, 3, 4, or 5, respectively; SAS 2 groups 6, 7, 8, or 9, respectively). Controls (group 1) were treated with air only. In nasal cavities, the major lesions consisted of increased eosinophilic globules and chitinase-3-like-protein-positive crystalloids* in the nasal mucosa, mainly in nasal cavity levels 2-4 up to week 26 of recovery without any further injury in olfactory mucosa, mainly in SAS 1-treated animals. Eosinophilic globules in the rodent nasal cavity are common and increase with age; they represent a particular finding of the rodent nasal mucosa. The relevance of chitinase-3-like protein (Ym1 + Ym2) expression in the rodent nasal mucosa is unknown but is normal in control animals. Both findings developed without any indicator for inflammatory processes. The increase of these unspecific background findings is considered an indicator of minor irritative effects. Due to the clear lack of nasal tissue injury or concurrent changes (degeneration, necrosis, inflammatory infiltrate, dysplasia, and/or neoplasia) following repeated inhalation exposure to SAS, it is deemed that the eosinophilic globules (hyaline inclusions) combined with the formation of eosinophilic protein crystalloids in this study represent an adaptive response.

Olfactory epithelium and ontogeny of the nasal chambers in the bowhead whale (Balaena mysticetus)

In a species of baleen whale, we identify olfactory epithelium that suggests a functional sense of smell and document the ontogeny of the surrounding olfactory anatomy. Whales must surface to breathe, thereby providing an opportunity to detect airborne odorants. Although many toothed whales (odontocetes) lack olfactory anatomy, baleen whales (mysticetes) have retained theirs. Here, we investigate fetal and postnatal specimens of bowhead whales (Balaena mysticetus). Computed tomography (CT) reveals the presence of nasal passages and nasal chambers with simple ethmoturbinates through ontogeny. Additionally, we describe the dorsal nasal meatuses and olfactory bulb chambers. The cribriform plate has foramina that communicate with the nasal chambers. We show this anatomy within the context of the whole prenatal and postnatal skull. We document the tunnel for the ethmoidal nerve (ethmoid foramen) and the rostrolateral recess of the nasal chamber, which appears postnatally. Bilateral symmetry was apparent in the postnatal nasal chambers. No such symmetry was found prenatally, possibly due to tissue deformation. No nasal air sacs were found in fetal development. Olfactory epithelium, identified histologically, covers at least part of the ethmoturbinates. We identify olfactory epithelium using six explicit criteria of mammalian olfactory epithelium. Immunohistochemistry revealed the presence of olfactory marker protein (OMP), which is only found in mature olfactory sensory neurons. Although it seems that these neurons are scarce in bowhead whales compared to typical terrestrial mammals, our results suggest that bowhead whales have a functional sense of smell, which they may use to find prey.

Proliferative and nonproliferative lesions of the rat and mouse respiratory tract

The INHAND Project (International Harmonization of Nomenclature and Diagnostic Criteria for Lesions in Rats and Mice) is a joint initiative of the Societies of Toxicologic Pathology from Europe (ESTP), Great Britain (BSTP), Japan (JSTP) and North America (STP) to develop an internationally-accepted nomenclature for proliferative and non-proliferative lesions in laboratory animals. The purpose of this publication is to provide a standardized nomenclature for classifying microscopic lesions observed in the respiratory tract of laboratory rats and mice, with color photomicrographs illustrating examples of some lesions. The standardized nomenclature presented in this document is also available electronically on the internet (http://www.goreni.org/). Sources of material included histopathology databases from government, academia, and industrial laboratories throughout the world. Content includes spontaneous developmental and aging lesions as well as lesions induced by exposure to test materials. A widely accepted and utilized international harmonization of nomenclature for respiratory tract lesions in laboratory animals will decrease confusion among regulatory and scientific research organizations in different countries and provide a common language to increase and enrich international exchanges of information among toxicologists and pathologists.

Computer simulation of inspiratory airflow in all regions of the F344 rat nasal passages

Data from laboratory animal experiments are often used in setting guidelines for safe levels of human exposure to inhaled materials. The F344 rat has been used extensively in laboratory experiments to determine effects of exposure to inhaled materials in the nasal passages. Many inhaled materials induce toxic responses in the olfactory (posterior) region of the rat nasal passages. The location of major airflow routes has been proposed as playing a dominant role in determining some olfactory lesion location patterns. Since nasal airflow patterns differ significantly among species, methods are needed to assess conditions under which these differences may significantly affect extrapolation of the effects of local dose in animals to potential disease outcome in humans. A computational fluid dynamics model of airflow and inhaled gas uptake has been used to predict dose to airway walls in the anterior F344 rat nasal passages (Kimbell et al., Toxicol. Appl. Pharmacol., 1993; 121, 253-263). To determine the role of nasal airflow patterns in affecting olfactory lesion distribution, this model was extended to include the olfactory region. Serial-step histological sections of the nasal passages of a F344 rat were used to construct the computer model. Simulations of inspiratory airflow throughout the rat nasal passages were consistent with previously reported experimental data. Four of the five major simulated flow streams present in the anterior nose (dorsal lateral, middle, ventral lateral, and ventral medial streams) flowed together to exit ventrally at the nasopharyngeal duct, bypassing the ethmoid recesses. The remaining dorsal medial stream split to flow both medially and laterally through the olfactory-epithelium-lined ethmoid recesses in a Z-shaped pattern when viewed sagitally. Simulated flow in the ethmoid recesses was more than an order of magnitude slower than flow in the anterior and ventral parts of the nasal passages. Somewhat higher volumes of flow were predicted in the dorsal medial stream when the nasal vestibule was reshaped to be upturned, and more flow was allocated to the dorsal medial stream with increased inspiratory airflow rate, suggesting that rats may be able to allocate more airflow to this stream by both modifying the shape of the nasal vestibule and increasing inhaled air velocity during sniffing. The present study provides the first description of flow in the complex olfactory region of the nose of the F344 rat. This model will be used to evaluate the role of airflow patterns in determining the distribution of xenobiotically induced olfactory mucosal lesions. This information, combined with models of disposition in the airway lining, will provide comprehensive dosimetry models for extrapolating animal response data to humans.

Nasal diagrams: a tool for recording the distribution of nasal lesions in rats and mice

Knowledge of patterns of lesion distribution can provide insight into the relative roles played by regional tissue dose and local tissue susceptibility in toxic responses to xenobiotics in the nose and assist assessment of potential human risk. A consistent approach is needed for recording lesion distribution patterns in the complex nasal airways of rats and mice. The present work provides a series of diagrams of the nasal passages of the Fischer-344 rat and B6C3F1 mouse, designed for mapping nasal lesions. The diagrams present each of the major cross-sectional airway profiles, provide adequate space for nasal mucosal lesion recording, and are suitable for duplication in a commercial photocopier. Sagittal diagrams are also provided to permit transfer of lesion location data observed in transverse sections onto the long axis of the nose. The distribution of lesions induced by a selected range of xenobiotics is presented. Approaches to application of the diagrams and interpretation of results obtained are discussed in relation to factors responsible for lesion distribution in the nose and their relevance to interspecies extrapolation. A modified approach to anatomical classification of the ethmoturbinates of the rodent is also presented.

Sensory and pulmonary irritation of aliphatic amines in mice: a structure-activity relationship study

The expiratory bradypnea indicative of upper airway irritation in mice was evaluated during a 15-min oronasal exposure to increasing concentrations of sixteen aliphatic amines. The airborne concentration resulting in a 50% decrease in the respiratory rate of mice (RD50) was calculated for each test compound. Moreover, the sixteen amines were tested for pulmonary irritation by measuring the decrease in respiratory rate of (non-anaesthetized) tracheally cannulated mice (RD50 TC). The RD50 and RD50 TC values and their ratios were related to n-octanol/water partition coefficients (log P). The RD50 values associated with exposure to saturated amines ranged from 17 to 300 ppm. The RD50TC values for these saturated amines ranged from 35 to 489 ppm. The RD50 and RD50TC values of saturated amines were closely related to the n-octanol/water partition coefficient, indicating that the more lipophilic amines are more irritant for the upper and lower respiratory tracts. The RD50TC/RD50 values were much less closely related to the n-octanol/water partition coefficient. Based on the results, tentative standards are suggested for the studied amines.

Approaches to the identification and recording of nasal lesions in toxicology studies

The identification, recording, and interpretation of nasal lesions can be a difficult task in toxicology studies. The objective of this article is to provide some guidelines for approaches to nasal toxicologic pathology, based on the author's experience and information available in the published literature. Identification of treatment-induced nasal lesions requires adequate in-life and post-mortem observation, and thorough histopathology. Histopathologic assessment is dependent upon high quality and consistent histologic preparations, adequate knowledge of nasal anatomy and histology, and experience with the range of aging, background, and treatment-induced lesions that may be encountered. In recent years there has been a marked increase in the number of articles reporting nasal pathology in studies for which materials were delivered by inhalation and by non-inhalation routes. Because of the increasing size of this database, it is recommended that standardized and systematic nomenclature be developed for these changes. The following points are considered to be particularly important: 1) alert animal care staff to clinical changes that may indicate nasal lesions; 2) screen animals for nasal disease, such as nasal nematodes in non-human primates; 3) record gross lesions during trimming of decalcified nasal tissues; 4) save spare tissue in fixative; 5) remember that the normal bilateral symmetry of the nose can be a valuable diagnostic aid; 6) avoid excessive lumping or splitting of diagnoses; 7) develop a logical order for recording of lesions (the approach preferred by the author is degenerative, inflammatory, regenerative, proliferative, for each of the epithelial types in a logical anatomical order, such as squamous, transitional, respiratory, and olfactory); 8) accurately determine the site of toxic responses; 9) keep a notebook of interesting or important observations and ideas if you are using a computerized data acquisition system; 10) consider the role of factors that may account for lesion distribution (regional dose and tissue susceptibility) during interpretation of tissue responses; and 11) during preparation of the descriptive narrative, clearly define what occurred, where and when it occurred, and consider the use of simple anatomical diagrams as an adjunct to the text. Adequate lesion detection and characterization by the toxicologic pathologist is often a critical feature of toxicology studies, and can play an important role in determination of human risks associated with exposure to xenobiotics. A systematic but flexible approach is recommended.

Airflow, gas deposition, and lesion distribution in the nasal passages

The nasal passages of laboratory animals and man are complex, and lesions induced in the delicate nasal lining by inhaled air pollutants vary considerably in location and nature. The distribution of nasal lesions is generally a consequence of regional deposition of the inhaled material, local tissue susceptibility, or a combination of these factors. Nasal uptake and regional deposition are are influenced by numerous factors including the physical and chemical properties of the inhaled material, such as water solubility and reactivity; airborne concentration and length of exposure; the presence of other air contaminants such as particulate matter; nasal metabolism, and blood and mucus flow. For certain highly water-soluble or reactive gases, nasal airflow patterns play a major role in determining lesion distribution. Studies of nasal airflow in rats and monkeys, using casting and molding techniques combined with a water-dye model, indicate that nasal airflow patterns are responsible for characteristic differences in the distribution of nasal lesions induced by formaldehyde in these species. Local tissue susceptibility is also a complex issue that may be a consequence of many factors, including physiologic and metabolic characteristics of the diverse cell populations that comprise each of the major epithelial types lining the airways. Identification of the principal factors that influence the distribution and nature of nasal lesions is important when attempting the difficult process of determining potential human risks using data derived from laboratory animals. Toxicologic pathologists can contribute to this process by carefully identifying the site and nature of nasal lesions induced by inhaled materials.

Nasal irritation and pulmonary toxicity of aliphatic amines in mice

The expiratory bradypnoea indicative of upper airway irritation in mice was evaluated during a 15-min oronasal exposure to increasing concentrations of twenty aliphatic amines. The airborne concentration resulting in a 50% decrease in the respiratory rate of mice (RD50) was calculated for each test compound. Moreover, eight out of the twenty amines were tested for pulmonary toxicity in mice and for the effects of a 120-min exposure on the respiratory rates of non-anaesthetized, tracheally cannulated mice (RD50TC). Both allylamine and diallylamine showed RD50 values of 9 ppm and 4 ppm, respectively, while the RD50 values associated with exposure to saturated amines ranged from 50 to 200 ppm. Among the eight amines tested for both upper airway irritation and pulmonary toxicity, diisopropylamine and di-n-butylamine showed a RD50TC/RD50 ratio of less than 1, indicating that the respiratory toxicity induced by these two amines would be related primarily to pulmonary effects. On the basis of prior predictions proposed for upper airway irritants, tentative standards are given for ten amines. Moreover, it is suggested that the basis of standards for industrial exposure to diisopropylamine and di-n-butylamine should be specified.