Anatomy and Bronchoscopy of the Porcine Lung. A Model for Translational Respiratory Medicine

Judge, Eoin P.; Hughes, Jennifer M.; Egan, Jim; Maguire, M. Helen; Molloy, Emer L.; O’Dea, Shirley

doi:10.1165/rcmb.2013-0453tr

Cited by 197 publications

(182 citation statements)

References 86 publications

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“…Thus, comparing relative volumes that use cartilage volume as the denominator is valid. Using cartilage as the reference volume has the added benefit of being efficient, as the pig trachea has more cartilaginous rings than the human trachea [36]. However, using cartilage as the reference volume will not work for animal models in which the cartilage is damaged [20].…”

Section: Discussionmentioning

confidence: 99%

A Design-Based Stereologic Method to Quantify the Tissue Changes Associated with a Novel Drug-Eluting Tracheobronchial Stent

et al. 2019

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Background: Granulation tissue is a common complication of airway stenting, but no published methods can quantify the volume and type of tissue that develops. Objective: To use design-based stereology to quantify changes in tissue volume and type associated with airway stenting. Methods: We compared drug-eluting stents (DES) filled with gendine to standard silicone stents in pigs in an assessor-blinded randomized trial. Tracheal stents were placed via rigid bronchoscopy. After 1 month, animals were euthanized and necropsies were performed. Antimicrobial effects of the DES were assessed in trachea tissue samples, on the DES surface, and with residual gel from the DES reservoir. Tracheal thickness was measured using orthogonal intercepts. Design-based stereology was used to quantify the volume density of tissues using a point-counting method. The volume of each tissue was normalized to cartilage volume, which is unaffected by stenting. Results: Pigs were randomized to DES (n = 36) or control stents (n = 9). The drug was successfully eluted from the DES, and the stent surface showed antibacterial activity. DES and controls did not differ in tissue microbiology, tracheal thickness, or granulation tissue volume. Compared to nonstented controls, stented airways demonstrated a 110% increase in soft-tissue volume (p = 0.005). Submucosal connective tissue (118%; p < 0.0001), epithelium (70%; p < 0.0001), submucosal glands (47%; p = 0.001), and smooth muscle (41%; p < 0.0001) increased in volume. Conclusion: Stenting doubles the volume of soft tissue in the trachea. Design-based stereology can quantify the tissue changes associated with airway stenting.

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Section: Discussionmentioning

confidence: 99%

A Design-Based Stereologic Method to Quantify the Tissue Changes Associated with a Novel Drug-Eluting Tracheobronchial Stent

et al. 2019

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“…Moreover, the number of Reversers implanted may have influenced their efficacy. Although the morphological structure and distribution of the porcine airways are broadly similar to the human lung, the segmental and subsegmental bronchi are usually shorter than human bronchi [28]. Some of the porcine airways are not long enough even for the smallest size of the Reverser.…”

Section: Discussionmentioning

confidence: 99%

A New-Designed Lung-Bending Device for Bronchoscopic Lung Volume Reduction of Severe Emphysema: A Feasibility Study in Pigs

Cheng

Zhang

et al. 2019

Respiration

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Background: Bronchoscopic therapies are less invasive alternatives of surgical lung volume reduction for severe emphysema. Bending of lung tissue by implanting metallic coils into bronchi is one of the procedures. A new-designed device with a similar rationale, Reverser, has been developed with some improvements. Objectives: The aim of the study was to evaluate the safety and feasibility of the Reversers. Methods: Twelve healthy pigs were randomly divided into 3 groups (groups A, B, and C). The Reversers were implanted bronchoscopically into the selected airways using a proprietary delivery system. Physical examination, chest fluoroscopy, computed tomography (CT) scans, and bronchoscopic observations were performed before implantation and during the follow-up period. Necropsy was performed respectively at 1 month (group A), 3 months (group B), and 6 months (group C) after implantation. Results: A total of 47 Reversers were implanted successfully. The procedure was feasible and well tolerated by all pigs. No severe complications, such as pneumothorax, abscesses, and airway hemorrhage, were found. No unintended injuries or death occurred. Mild granulation and inflammation were observed in the airway wall. Opacities around Reversers were shown on CT scans in some pigs. In the pigs with opacities, histological evaluation revealed widened alveolar septa due to inflammatory cell infiltration in the vicinity of the Reversers. On the analysis of CT data, there was a trend for volume reduction of the treated lung at 1 and 3 months after treatment compared with baseline. Conclusions: This study showed that Reversers were safe and feasible for bronchoscopic lung volume reduction in pigs.

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“…Unfortunately, the MMPD software has not been adapted to calculate deposition in pig's lung. Considering that human and porcine lungs have similar overall volume and the alveolar size as well as similar number of bronchial generations [17,18], we expect that the software developed for the human lungs will adequately describe deposition in the porcine lungs provided that the model parameters are chosen correctly.…”

Section: Comparison With Theoretical Predictionsmentioning

confidence: 99%

Dry Lung as a Physical Model in Studies of Aerosol Deposition

Морозов

Kanev

2015

Lung

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A new physical model was developed to evaluate the deposition of micro- and nanoaerosol particles (NAPs) into the lungs as a function of size and charges. The model was manufactured of a dry, inflated swine lung produced by Nasco company (Fort Atkinson, WI). The dry lung was cut into two lobes and a conductive tube was glued into the bronchial tube. The upper 1-2-mm-thick layer of the lung lobe was removed with a razor blade to expose the alveoli. The lobe was further enclosed into a plastic bag and placed within a metalized plastic box. The probability of aerosol deposition was calculated by comparing the size distribution of NAPs passed through the lung with that of control, where aerosol passed through a box bypassing the lung. Using this new lung model, it was demonstrated that charged NAPs are deposited inside the lung substantially more efficiently than neutral ones. It was also demonstrated that deposition of neutral NAPs well fits prediction of the Multiple-Path Particle Dosimetry (MPPD) model developed by the Applied Research Associates, Inc. (ARA).

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Anatomy and Bronchoscopy of the Porcine Lung. A Model for Translational Respiratory Medicine

Cited by 197 publications

References 86 publications

A Design-Based Stereologic Method to Quantify the Tissue Changes Associated with a Novel Drug-Eluting Tracheobronchial Stent

A Design-Based Stereologic Method to Quantify the Tissue Changes Associated with a Novel Drug-Eluting Tracheobronchial Stent

A New-Designed Lung-Bending Device for Bronchoscopic Lung Volume Reduction of Severe Emphysema: A Feasibility Study in Pigs

Dry Lung as a Physical Model in Studies of Aerosol Deposition

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