Inhalation dosimetry of hexamethylene diisocyanate vapor in the rat and human respiratory tracts

Schroeter, Jeffry D.; Kimbell, Julia S.; Asgharian, Bahman; Tewksbury, Earl W.; Sochaski, Mark A.; Foster, Melanie L.; Dorman, David C.; Wong, Brian A.; Andersen, Melvin E.

doi:10.3109/08958378.2013.768314

Cited by 11 publications

(11 citation statements)

References 43 publications

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“…The protocols applied focused on the analysis of the concentration × time ( C × t )–response relationship on elicitation-based endpoints by employing a highly rationalized dose-escalation-like protocol. For the HDI-vapor, a C const × t var regimen was selected with a “ C” high enough to overcome the scrubbing capacity of the nasal passages of the obligate nasal breathing rats (Schroeter et al., 2013 ; Shiotsuka et al., 2006 , 2010 ). Ancillary pre-studies served the purpose of identifying that “ C ” of HDI-vapor gains access to the lower airways at stable breathing conditions.…”

Section: Methodsmentioning

confidence: 99%

“…The workday and ppmV-adjusted equivalent were estimated to be 23 (mg/m 3 × min) × 1/7 (conversion from mg to ppmV) × 1/480 min −1 = 0.007 ppmV. The derivation of the rat to human conversion factor assumed that bronchial airways of oronasally breathing humans are subjected to a 3-times higher dose as compared with nasally breathing rats (Schroeter et al., 2013 ). Likewise, due to the reflexively-induced depression of ventilation occurring in rats, the inhaled dose of rats exposed to HDI-vapor at concentrations penetrating the lower respiratory tract is likely to be about one-third of normally breathing rats.…”

Section: Methodsmentioning

confidence: 99%

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Analysis of the interrelationship of the pulmonary irritation and elicitation thresholds in rats sensitized with 1,6-hexamethylene diisocyanate (HDI)

Pauluhn

2015

Inhalation Toxicology

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This paper summarizes a range of experimental data central for developing a science-based approach for hazard identification of monomeric and polymeric aliphatic 1,6-hexamethylene diisocyanate (HDI). The dose–response curve of HDI-induced pulmonary responses in naïve or dermally sensitized rats after one or several inhalation priming exposures was examined in the Brown Norway (BN) rat asthma model. Emphasis was directed to demonstrate the need and the difficulty in selecting an appropriate pulmonary dose when much of the inhaled chemically reactive vapor may concentration dependently be retained in the upper airways of obligate nose-breathing rats. The course taken acknowledges the experimental challenges in identifying an elicitation threshold for HDI-monomer near or above the saturated vapor concentration or in the presence of a HDI-polymer aerosol. The inhalation threshold dose on elicitation was determined based on a fixed concentration (C) × variable exposure duration (t) protocol for improving inhalation dosimetry of the lower airways. Neutrophilic granulocytes (PMN) in bronchoalveolar lavage (BAL) fluid in equally inhalation primed naïve and dermally sensitized rats were used to define the inhalation elicitation threshold C × t. Sensitized rats elaborated markedly increased PMN challenged sensitized rats relative to equally challenged naïve rats at 5625 mg HDI/m3 × min (75 mg/m3 for 75 min). PMN were essentially indistinguishable at 900 mg HDI/m3 × min. By applying adjustment factors accounting for both inter-species differences in inhalation dosimetry and intra-species susceptibility, the workplace human-equivalent threshold C × t was estimated to be in the range of the current ACGIH TLV® of HDI. Thus, this rat “asthma” model was suitable to demonstrate elicitation thresholds for HDI-vapor after one or several inhalation priming exposures and seems to be suitable to derive occupational exposure values (OELs) for diisocyanates in general.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Analysis of the interrelationship of the pulmonary irritation and elicitation thresholds in rats sensitized with 1,6-hexamethylene diisocyanate (HDI)

Pauluhn

2015

Inhalation Toxicology

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“…An in silico model, such as the Multiple Path Particle Dosimetry Model (MPPD) is a wellestablished, validated, and accepted model that can help identify the location of a particular droplet/particle size is expected to reach and deposit and where lesions of cellular damage may occur. [61][62][63][64][65] A mass per unit surface area can then be applied to both in vivo (which has been done successfully for validation purposes) and in vitro applications for establishing the appropriate droplet/particle size to emulate the intended exposure scenario that investigators wish to assess for potential exposure effects.…”

Section: Test Bed System For Immunotoxicological Responsesmentioning

confidence: 99%

Optimizing a Test Bed System to Assess Human Respiratory Safety After Exposure to Chemical and Particle Aerosolization

Sayes

SingalMadhuri

2018

Applied In Vitro Toxicology

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In the last decade, there has been a movement within environmental health and toxicology research to progressively phase out animal testing and implement more rigorous and validated cell culture models. This movement is checked against the rapidly evolving field of immunotoxicology and measurement of immune-mediated cellular responses. Both trends are driven by many variables, some of which are common in both (i.e., increased time constraints; social, financial, and regulatory pressures; and general need to develop modern test bed systems for safety-by-design product development). The need for non-animal alternative test methodology is especially important in the field of immunotoxicology, where increased emphasis has been placed on distinguishing dermal, respiratory, and gastrointestinal sensitization and/or irritation, defining key markers for hazard identification, and developing potential high-throughput screening processes. With these drivers in mind, this article summarizes the key components of developing a prototype test bed system to rapidly determine immunotoxicological responses following exposure to aerosolized materials. Inhalation exposure to aerosolized substances (e.g., chemicals and particles) is a common occurrence for individuals working in research laboratories, engaged in industrial processes, in consumer use of household products, and during the waste disposal process. We recommend research priorities with emphasis on developing continuous flow testing systems, inclusive of aerosolization, cell culture exposure, and immunological endpoint analyses.

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“…Animal studies of HDI exposure to identify “self” reaction targets in the lower airway have been compromised by inherent species differences with humans; for example, rodents are obligate nose breathers and their upper airways are proportionally larger and possess a scrubbing effect or capacity for absorbing/capturing reactive vapors (Ferguson et al, 1988; Harkema et al, 2006; Kennedy et al, 1993; Morris & Buckpitt, 2009; Schroeter et al, 2013). Prior rat and guinea pig studies with several different radiolabeled monoand di-isocyanates demonstrated limited penetration into the lower airways and higher levels of upper airway and oral absorption (Ferguson et al, 1988; Gledhill et al, 2005; Kennedy et al, 1994; Schroeter et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Prior rat and guinea pig studies with several different radiolabeled monoand di-isocyanates demonstrated limited penetration into the lower airways and higher levels of upper airway and oral absorption (Ferguson et al, 1988; Gledhill et al, 2005; Kennedy et al, 1994; Schroeter et al, 2013). …”

Section: Introductionmentioning

confidence: 99%

Reaction products of hexamethylene diisocyanate vapors with “self” molecules in the airways of rabbits exposed via tracheostomy

et al. 2017

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Hexamethylenediisocyanate (HDI) is a widely used aliphatic diisocyanate and a well-recognized cause of occupational asthma.“Self” molecules (peptides/proteins) in the lower airways, susceptible to chemical reactivity with HDI, have been hypothesized to play a role in asthma pathogenesis and/or chemical metabolism, but remain poorly characterized.This study employed unique approaches to identify and characterize “self” targets of HDI reactivity in the lower airways. Anesthetized rabbits free breathed through a tracheostomy tube connected to chambers containing either, O2, or O2 plus ~200 ppb HDI vapors. Following 60 minutes of exposure, the airways were lavaged and the fluid was analyzed by LC-MS and LC-MS/MS.The low-molecular weight (<3 kDa) fraction of HDI exposed, but not control rabbit bronchoalveolar lavage (BAL) fluid identified 783.26 and 476.18 m/z [M+H]+ ions with high energy collision-induced dissociation (HCD) fragmentation patterns consistent with bis glutathione (GSH)-HDI and mono(GSH)-HDI. Proteomic analyses of the high molecular weight (>3 kDa) fraction of exposed rabbit BAL fluid identified HDI modification of specific lysines in uteroglobin (aka clara cell protein) and albumin.In summary, this study utilized a unique approach to chemical vapor exposure in rabbits, to identify HDI reaction products with “self” molecules in the lower airways.

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Inhalation dosimetry of hexamethylene diisocyanate vapor in the rat and human respiratory tracts

Cited by 11 publications

References 43 publications

Analysis of the interrelationship of the pulmonary irritation and elicitation thresholds in rats sensitized with 1,6-hexamethylene diisocyanate (HDI)

Analysis of the interrelationship of the pulmonary irritation and elicitation thresholds in rats sensitized with 1,6-hexamethylene diisocyanate (HDI)

Optimizing a Test Bed System to Assess Human Respiratory Safety After Exposure to Chemical and Particle Aerosolization

Reaction products of hexamethylene diisocyanate vapors with “self” molecules in the airways of rabbits exposed via tracheostomy

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