Nasal Nitric Oxide Across Mutations in Primary Ciliary Dyskinesia

Phase

N/A

Condition

Dyskinesias

Treatment

N/A

Clinical Study ID

NCT04949308

JR_nNO_PCD_09_2020

All Genders

Study Summary

Primary Ciliary Dyskinesia (PCD) is a rare genetic disorder characterized by dysfunction of motile cilia associated with recurrent infections of the airways, laterality defects (Situs inversus totalis in about 50% of cases) and fertility problems. At present, mutations in > 45 genes associated with PCD and mucociliary clearance disorders have been identified, representing most likely two thirds of all human cases.

The aims of this study are:

Correlation between nasal NO levels and distinct PCD genotypes
Determination of further parameters potentially associated with nasal NO levels in genotyped PCD individuals
1. course of clinical manifestations (e.g. neonatal distress, infections, bronchiectasis)
2. diagnostic results (HVMA, TEM, IF)
3. lung function outcome (FVC, FEV1)

Eligibility Criteria

Inclusion

Inclusion Criteria:

Patients with a genetically confirmed diagnosis of PCD (bi-allelic mutations in agene, known to cause PCD) with typical clinical symptoms of PCD
PCD individuals of all age groups with at least one nNO measurement performedaccording to diagnostic guidelines. Serial nNO measurements should be included ifavailable (e.g. yearly), at least for infants and young children

Exclusion

Exclusion Criteria:

Study Design

January 01, 2021

December 31, 2022

Study Description

Nasal Nitric Oxide (nNO) concentration is usually low or very low in patients with Primary Ciliary Dyskinesia (PCD) for yet unknown reasons (1).

Measured nNO holds a strong ability to separate healthy subjects from patients with PCD in both childhood and adulthood and across several different nNO sampling modalities (2) (3-5) and nNO is widely used as an important supplementary diagnostic test for PCD work up in both Europe (6) and North America (7). Low nNO in PCD was first reported 26 years ago (8). Nasal NO has been associated with host paranasal sinus defense as sufficient nNO production in non-PCD subjects is thought to play a role in maintaining paranasal sinus sterility (9). Furhermore, ciliary beating seems to be upregulated by a NO dependent pathway in bovine airway epithelium (10), influencing mucociliary clearance. However, human in vitro studies of ciliated airway cells in air-liquid-interface (ALI) culture have been ambiguous as to whether the biosynthesis of NO in PCD is impaired (11) (12) or not (13; 14) and the etiology of low nNO in PCD and presumed link to ciliary beating remains unclear. So far, attempts to link PCD phenotype and genotype has indicated that patients with PCD harboring CCDC39 and CCDC40 mutations may have a poorer lung function development (15).

In rare cases of PCD (<5%) (16) nNO concentration is within normal range. More than 14 different PCD-causing genes (e.g RSPH1, GAS8, RPGR, CCNO, CCDC103, CFAP221, DNAH9, FOXJ1, GAS2L2, LRRC56, NEK10, SPEF2, STK36, TTC12) has been associated with nNO values above the agreed cut off for nNO-production rate of 77 nL/min in a few patients with PCD (16). However, individuals with NEK10 or FOXJ1 mutations, for example, display a very severe respiratory phenotype (17), but making a diagnosis is challenging because of normal nNO values as well as apparently normal ciliary beating.

Since nNO also holds potential as an outcome parameter in future clinical trials of PCD, better understanding of nNO in PCD is warranted.

Demand of large number of patients with PCD is crucial, keeping the rareness of nearnormal and normal nNO levels in PCD in mind. Motivated by the analysis of lung function in a large cohort of genotyped PCD-patients, this multicenter Involvement across international PCD centers is an obvious opportunity for gaining such further knowledge with the focus on nasal NO.