Épithélium respiratoire

Respiratory epithelium, or airway epithelium, is a type of ciliated columnar epithelium found lining most of the respiratory tract as respiratory mucosa, where it serves to moisten and protect the airways. It is not present in the vocal cords of the larynx, or the oropharynx and laryngopharynx, where instead the epithelium is stratified squamous. It also functions as a barrier to potential pathogens and foreign particles, preventing infection and tissue injury by the secretion of mucus and the action of mucociliary clearance. The respiratory epithelium lining the upper respiratory airways is classified as ciliated pseudostratified columnar epithelium. This designation is due to the arrangement of the multiple cell types composing the respiratory epithelium. While all cells make contact with the basement membrane and are, therefore, a single layer of cells, their nuclei are not aligned in the same plane. Hence, it appears as though several layers of cells are present and the epithelium is called pseudostratified (falsely layered). The respiratory mucosa transitions to simple ciliated cuboidal epithelium and finally to simple squamous epithelium in the alveolar ducts and alveoli. The cells in the respiratory epithelium are of five main types: a) ciliated cells, b) goblet cells, c) brush cells, d) airway basal cells, and e) small granule cells (NDES) Goblet cells become increasingly fewer further down the respiratory tree until they are absent in the terminal bronchioles; club cells take over their role to some extent here. Another important cell type is the pulmonary neuroendocrine cell. These are innervated cells that only make up around 0.5% of the respiratory epithelial cells. The ciliated cells are columnar epithelial cells with specialized ciliary modifications. The ciliated cells make up between 50 and 80 per cent of the epithelium.

Stability of influenza A virus in droplets and aerosols is heightened by the presence of commensal respiratory bacteria

Inactivation of influenza A virus in expiratory droplets and aerosol particles and the associated physicochemical drivers

The neuraminidase activity of influenza A virus determines the strain-specific sensitivity to neutralization by respiratory mucus

Stability of influenza A virus in droplets and aerosols is heightened by the presence of commensal respiratory bacteria

Inactivation of influenza A virus in expiratory droplets and aerosol particles and the associated physicochemical drivers

The neuraminidase activity of influenza A virus determines the strain-specific sensitivity to neutralization by respiratory mucus