BACKGROUND: In cystic fibrosis (CF), genetic mutations in the CF transmembrane conductance regulator (CFTR) gene cause reduced chloride efflux from ciliated airway epithelial cells. This results in a reduction in periciliary liquid (PCL) depth of the airway surface liquid due to associated reduced water efflux. PCL layer dehydration reduces mucociliary clearance (MCC), leading to airway obstruction (reduced airflow and inflammation due to pathogen invasion) with mucus plug formation. SUMMARY: Rehydrating mucus increases MCC. Mucus hydration can be achieved by direct hydration (administering osmotic agents to set up an osmotic gradient), using CFTR modulators to correct dysfunctional CFTR, or it can be achieved pharmacologically (targeting other ion channels on airway epithelial cells). Key Messages: The molecular mechanisms of several therapies are discussed in the context of pre-clinical and clinical trial studies. Currently, only the osmotic agent 7% hypertonic saline and the CFTR 'potentiator' VX-770 (ivacaftor) are used clinically to hydrate mucus. Emerging therapies include the osmotic agent mannitol (Bronchitol), the intracellular Ca(2+)-raising agent Moli1901/lancovutide, the CFTR potentiator sildenafil [phosphodiesterase type 5 (PDE5) inhibitor] and the CFTR 'corrector' VX-809 (lumacaftor). Other CFTR correctors (e.g. 'chemical chaperones') are also showing pre-clinical promise.
BACKGROUND: In cystic fibrosis (CF), genetic mutations in the CF transmembrane conductance regulator (CFTR) gene cause reduced chloride efflux from ciliated airway epithelial cells. This results in a reduction in periciliary liquid (PCL) depth of the airway surface liquid due to associated reduced water efflux. PCL layer dehydration reduces mucociliary clearance (MCC), leading to airway obstruction (reduced airflow and inflammation due to pathogen invasion) with mucus plug formation. SUMMARY: Rehydrating mucus increases MCC. Mucus hydration can be achieved by direct hydration (administering osmotic agents to set up an osmotic gradient), using CFTR modulators to correct dysfunctional CFTR, or it can be achieved pharmacologically (targeting other ion channels on airway epithelial cells). Key Messages: The molecular mechanisms of several therapies are discussed in the context of pre-clinical and clinical trial studies. Currently, only the osmotic agent 7% hypertonic saline and the CFTR 'potentiator' VX-770 (ivacaftor) are used clinically to hydrate mucus. Emerging therapies include the osmotic agent mannitol (Bronchitol), the intracellular Ca(2+)-raising agent Moli1901/lancovutide, the CFTR potentiator sildenafil [phosphodiesterase type 5 (PDE5) inhibitor] and the CFTR 'corrector' VX-809 (lumacaftor). Other CFTR correctors (e.g. 'chemical chaperones') are also showing pre-clinical promise.
Authors: R L Blackmon; S M Kreda; P R Sears; B S Chapman; D B Hill; J B Tracy; L E Ostrowski; A L Oldenburg Journal: Nanoscale Date: 2017-04-13 Impact factor: 7.790
Authors: Xiaojie Luan; Julian S Tam; George Belev; Santosh Jagadeeshan; Brendan Murray; Noman Hassan; Terry E Machen; L Dean Chapman; Juan P Ianowski Journal: Sci Rep Date: 2019-01-24 Impact factor: 4.379
Authors: Anita Balázs; Zsolt Balla; Balázs Kui; József Maléth; Zoltán Rakonczay; Julia Duerr; Zhe Zhou-Suckow; Jolanthe Schatterny; Matthias Sendler; Julia Mayerle; Jens-P Kühn; László Tiszlavicz; Marcus A Mall; Peter Hegyi Journal: Front Physiol Date: 2018-05-29 Impact factor: 4.566
Authors: Génesis Vega; Anita Guequén; Amber R Philp; Ambra Gianotti; Llilian Arzola; Manuel Villalón; Olga Zegarra-Moran; Luis Jv Galietta; Marcus A Mall; Carlos A Flores Journal: JCI Insight Date: 2020-08-20