Estimates of primary ciliary dyskinesia prevalence: a scoping review.

Background: Primary ciliary dyskinesia (PCD) is a rare multisystem genetic disease caused by dysfunctional motile cilia. Despite PCD being the second most common inherited airway disease after cystic fibrosis, PCD continues to be under-recognised globally owing to nonspecific clinical features and the lack of a gold standard diagnostic test. Commonly repeated prevalence estimates range from one in 10 000 to one in 20 000, based on regional epidemiological studies with known limitations. The purpose of this scoping review was to appraise the PCD literature, to determine the best available global PCD prevalence estimate and to inform the reader about the potential unmet health service needs in PCD. The primary objective of the present study was to systematically review the literature about PCD prevalence estimates. Methods: A scoping review was conducted following the Preferred Reporting Items for Systematic reviews and Meta-Analyses extension for scoping reviews (PRISMA-ScR) methodology. Included studies estimated PCD prevalence and used cohort, clinical or genomic data. Case reports, conference abstracts, review articles, animal studies or non-English articles were excluded. Results: A literature review identified 3484 unique abstracts; 34 underwent full-text review and eight met the inclusion/exclusion criteria. Seven articles were based on epidemiological studies of specific geographical regions and provided prevalence estimates that ranged from approximately one to 44.1 in 100 000. Only one study estimated global prevalence, using two large genomic databases, and calculated it to be ∼13.2 in 100 000 (based on pathogenic variants in 29 disease-causing genes). Conclusions: A population-based genomic approach for estimating global prevalence has found that PCD is much more prevalent than previously cited in the literature. This highlights the potential unmet health service needs of people living with PCD.

Primary Ciliary Dyskinesia.

Primary ciliary dyskinesia (PCD) is a rare, genetic disease characterized by dysfunctional motile cilia and abnormal mucociliary clearance, resulting in chronic sino-oto-pulmonary disease, neonatal respiratory distress, subfertility, and organ laterality defects. Over the past 2 decades, research and international collaborations have led to an improved understanding of disease prevalence, classic and variable phenotypes, novel diagnostics, genotype-phenotype correlations, long term morbidity, and innovative therapeutics. However, PCD is often underrecognized in clinical settings and the recent analyses of genetic databases suggest that only a fraction of these patients are being accurately diagnosed. Knowledge of significant advancements, from pathophysiology to the expanded range of clinical manifestations, will have important clinical impacts. These may include increasing disease recognition, improving diagnostic testing and management, and establishing an adequate pool of affected patients to enroll in upcoming clinical therapeutic trials. The objective of this state-of-the-art review is for readers to gain a greater understanding of the clinical spectrum of motile ciliopathies, cutting-edge diagnostic practices, emerging genotype-phenotype associations, and currently accepted management of people with PCD.

Mortality of Pediatric Surgical Lung Biopsies in Ontario, Canada, 2000-2019.

Rationale: Surgical lung biopsies are often required for the definitive diagnosis of nonmalignant pediatric diffuse lung diseases; however, the literature on mortality after surgical lung biopsy in pediatric patients is sparse. Objectives: To determine the 30-day postoperative mortality rate after surgical lung biopsies for nonmalignant lung disease in pediatric patients in Ontario, Canada, and to identify risk factors associated with mortality. Methods: We performed an observational cohort study using population-based health administrative data available from ICES in Ontario, Canada, from 2000 to 2019. Cases were identified using the Canadian Classification of Health Interventions. Inclusion criteria were first surgical lung biopsies between 2000 and 2019 and age <18 years. Individuals with lung cancer, lung transplant, or missing data were excluded. A multivariable logistic regression model with generalized estimating equation was used to estimate the 30-day odds of mortality after surgical lung biopsy and to identify patient characteristics associated with increased mortality while accounting for clustering by hospital. Results: We identified 1,474 pediatric patients who underwent surgical lung biopsy in Ontario between 2000 and 2019. The overall mortality rates decreased over the study duration from 6.6% (2000-2004) to 3.0% (2015-2019). The study cohort for multivariate analyses consisted of 1,342 patients who had complete data. The pediatric mortality 30 days after surgical lung biopsy was 5.1% but was <1% in elective cases. Risk factors for increased mortality included open surgical lung biopsy (vs. video-assisted) (odds ratio [OR], 13.13; 95% confidence interval [CI], 3.76, 45.87; P < 0.001), nonelective procedure (OR, 11.74; 95% CI, 3.51, 39.27; P < 0.001), younger age (<3 mo) (OR, 6.04; 95% CI, 2.40, 15.22; P < 0.001), and higher comorbidity score (OR, 1.15; 95% CI, 1.05, 1.26; P = 0.003). Conclusions: Pediatric mortality postsurgical lung biopsy is not insignificant, particularly in nonelective procedures. Other important risk factors to consider when pursuing pathologic diagnosis include surgical approach, younger age, and higher comorbidity.

Bronchodilator responsiveness in children with primary ciliary dyskinesia.

Background: Reversible airway obstruction is common in children with primary ciliary dyskinesia. However, the diagnostic value of adding bronchodilator (BD) response testing to routine spirometry is unclear. Methods: This is a retrospective analysis of pulmonary function test results obtained from children with primary ciliary dyskinesia seen as outpatients at the Hospital for Sick Children, Toronto. Spirometry results were collected for every appointment with BD response testing ("Visit", with pre-BD and post-BD measurements) as well as for the previous ("Baseline") and following ("Follow-up") encounters. Results: A positive BD response was seen in 86 out of 474 (18.1%) of the pulmonary function tests from 82 children with primary ciliary dyskinesia. BD responsiveness was associated with a significant absolute change (±sd) in % predicted forced expiratory volume in 1 s (FEV1) from Baseline to Visit pre-BD (-6.5±10.3%, p<0.001), but not from Baseline to Follow-up (0.4±10.8, p=0.757). Antimicrobial therapy was initiated more commonly following a Visit with a positive BD response (OR 3.8, 95% CI 2.2-6.6) compared to no BD response. Children with a positive BD response had a greater annual decline in FEV1 % predicted compared to those with no BD response (-0.9% per year versus -0.5% per year, p<0.001). The annual decline in FEV1 % predicted was greater in children with multiple compared to one measured positive BD responses (-1.3% per year versus -0.6% per year, p<0.001) and in those not treated with antibiotic therapy following a positive BD response compared to those treated with antibiotics (-1.1% versus -0.6%, p<0.001). Conclusion: A positive BD response in children with primary ciliary dyskinesia may help identify those at risk for accelerated lung disease progression.

Association of Neonatal Hospital Length of Stay with Lung Function in Primary Ciliary Dyskinesia.

Rationale: Primary ciliary dyskinesia (PCD), an inherited lung disease, is characterized by abnormal ciliary function leading to progressive bronchiectasis. There is wide variability in respiratory disease severity at birth and later in life. Objectives: To evaluate the association between neonatal hospital length of stay (neonatal-LOS) and supplemental oxygen duration (SuppO2) with lung function in pediatric PCD. We hypothesized that longer neonatal-LOS and SuppO2 are associated with worse lung function (i.e., forced expiratory volume in 1 second percent predicted [FEV1pp]). Methods: We performed a secondary analysis of the Genetic Disorders of Mucociliary Clearance Consortium prospective longitudinal multicenter cohort study. Participants enrolled, during 2006-2011, were <19 years old with a confirmed PCD diagnosis and followed annually for 5 years. The exposure variables were neonatal-LOS and SuppO2, counted in days since birth. The outcome, FEV1pp, was measured annually by spirometry. The associations of neonatal-LOS and SuppO2 with FEV1pp were evaluated with a linear mixed-effects model with repeated measures and random intercepts, adjusted for age and ciliary ultrastructural defects. Results: Included were 123 participants (male, 47%; mean enrollment age, 8.3 yr [range, 0 to 18 yr]) with 578 visits (median follow-up, 5 yr). The median neonatal-LOS was 9 d (range, 1 to 90 d), and median SuppO2 was 5 d (range, 0 to 180 d). Neonatal-LOS was associated with worse lung function (-0.27 FEV1pp/d [95% confidence interval, -0.53 to -0.01]; P = 0.04). SuppO2 was not associated with lung function. Conclusions: Neonatal-LOS is associated with worse lung function in pediatric PCD, independent of age and ultrastructural defects. Future research on the mechanisms of neonatal respiratory distress and its management may help us understand the variability of lung health outcomes in PCD.

Going beyond the chest X-ray: Investigating laterality defects in primary ciliary dyskinesia.

BACKGROUND: Organ laterality defects in primary ciliary dyskinesia (PCD) are common, ranging from complete mirror image organ arrangement, situs inversus totalis (SIT), to situs ambiguus (SA), which falls along the spectrum of situs solitus (SS) and SIT. Targeted investigations for organ laterality defects are not universally recommended in PCD consensus statements. Without investigations beyond chest radiography (CXR), clinically significant defects may go undetected leading to increased morbidity. We hypothesize that clinically significant SA defects remain undetected on CXR and targeted investigations are needed to detect various laterality defects associated with morbidity. METHODS: This retrospective study collected data from PCD clinics at two Canadian children's hospitals from 2012 to 2020. Participants <30 years old with a confirmed or clinical diagnosis of PCD were enrolled. CXR images were reviewed, and reports of other targeted investigations, including chest computed tomography, abdominal ultrasound, echocardiogram, upper gastrointestinal series, and splenic function studies, were extracted from medical records. Situs classifications from CXR alone versus CXR with add-on targeted investigations were compared using Cochran's q and McNemar tests. RESULTS: One hundred and fifty-nine PCD patients were included, median age at PCD diagnosis of 6.1 years (range: 0-28). The situs classification differed significantly from CXR images alone versus CXR with add-on targeted investigations (p < 0.001); SS 88 (55%) versus 75 (47%), SIT 59 (37%) versus 46 (29%), and SA 12 (8%) versus 38 (24%). Identified SA defects were cardiovascular (21, 13%), intestinal (9, 6%), and/or splenic (16,10%). CONCLUSIONS: In PCD patients, clinically significant SA defects may not be detected by CXR alone. Our results suggest that the routine use of CXR with add-on targeted investigations may be justified.

Timing of Antenatal Corticosteroids for Optimal Neonatal Outcomes: A Markov Decision Analysis Model.

OBJECTIVE: Antenatal corticosteroids (ACSs) are administered to pregnant individuals at high risk of preterm delivery to reduce neonatal morbidity and mortality. ACSs have a limited timeframe of effectiveness, and timing of administration can be difficult because of uncertainty surrounding the likelihood of preterm delivery. The objective of the current study was to design a decision analysis model to optimize the timing of ACS administration and identify important model variables that impact administration timing preference. METHODS: We created a Markov decision analysis model with a base case of a patient at 240 weeks gestation with antepartum hemorrhage. Decision strategies included immediate, delayed, and no ACS administration. Outcomes were based on the neonatal perspective and consisted of lifetime quality adjusted life years (QALYs). Data for model inputs were derived from current literature and clinical recommendations. RESULTS: Our base case analysis revealed a preferred strategy of delaying ACSs for 2 weeks, which maximized QALYs (39.18 lifetime discounted), driven by reduced neonatal morbidity at the expense of 0.1% more neonatal deaths, when compared with immediate ACS administration. Sensitivity analyses identified that, if the probability of delivery within the next week was >6.19%, then immediate steroids were preferred. Other important variables included gestational age, ACS effectiveness, and ACS adverse effects. CONCLUSION: ACS timing involves a trade-off between morbidity and mortality, and optimal timing depends on probability of delivery, gestational age, and risks and benefits of ACSs. Clinicians should carefully consider these factors prior to ACS administration.

Dry Powder Inhaler Delivery of Tobramycin in In Vitro Models of Tracheostomized Children.

BACKGROUND: Pediatric tracheostomies are not uncommon and aerosols allow for targeted lung therapy. However, there is little literature that quantifies aerosol delivery through tracheostomies. Nebulizers are commonly used in delivering tobramycin, but there are drawbacks, for example, time burden. Dry powder inhalers (DPIs) can deliver higher payloads in less time. However, no data exist assessing DPIs with tracheostomies. OBJECTIVE: The study's aim was to quantify the amount of aerosolized tobramycin delivered to the lungs of in vitro tracheostomized spontaneously breathing pediatric models with the TOBI® Podhaler™ (Podhaler) and the PARI LC Plus® (LC Plus). METHODS: In vitro tracheostomized models of a 6- and 12-year-old trachea were created. Tobramycin aerosol was delivered to the models using either the LC Plus or Podhaler and captured on a filter at the trachea's distal end. A colorimetric tobramycin assay was used to quantify the amount. Three devices of each type were tested in triplicate to ensure repeatability. RESULTS: A total of 36 runs were completed and showed that the Podhaler was more efficient compared with the LC Plus. Mass and percentage of nominal dose, mean ± standard deviation (LC Plus vs. Podhaler with single capsule), was 72.4 ± 11.1 mg (24.1% ± 3.7%) versus 24.2 ± 2.4 mg (86.6% ± 8.7%); p < 0.001. CONCLUSIONS: The study's results show that the Podhaler was significantly more efficient compared with the LC Plus, and three Podhaler capsules delivered approximately the same amount of drug as the Tobramycin inhalation solution. These results suggest that Podhaler's tobramycin delivery is a feasible option in tracheostomized pediatric patients and a clinical study is warranted.

Modeling breath-enhanced jet nebulizers to estimate pulmonary drug deposition.

BACKGROUND: Predictable delivery of aerosol medication for a given patient and drug-device combination is crucial, both for therapeutic effect and to avoid toxicity. The gold standard for measuring pulmonary drug deposition (PDD) is gamma scintigraphy. However, these techniques expose patients to radiation, are complicated, and are relevant for only one patient and drug-device combination, making them less available. Alternatively, in vitro experiments have been used as a surrogate to estimate in vivo performance, but this is time-consuming and has few "in vitro to in vivo" correlations for therapeutics delivered by inhalation. An alternative method for determining inhaled mass and PDD is proposed by deriving and validating a mathematical model, for the individual breathing patterns of normal subjects and drug-device operating parameters. This model was evaluated for patients with cystic fibrosis (CF). METHODS: This study is comprised of three stages: mathematical model derivation, in vitro testing, and in vivo validation. The model was derived from an idealized patient's respiration cycle and the steady-state operating characteristics of a drug-device combination. The model was tested under in vitro dynamic conditions that varied tidal volume, inspiration-to-expiration time, and breaths per minute. This approach was then extended to incorporate additional physiological parameters (dead space, aerodynamic particle size distribution) and validated against in vivo nuclear medicine data in predicting PDD in both normal subjects and those with CF. RESULTS: The model shows strong agreement with in vitro testing. In vivo testing with normal subjects yielded good agreement, but less agreement for patients with chronic obstructive lung disease and bronchiectasis from CF. CONCLUSIONS: The mathematical model was successful in accommodating a wide range of breathing patterns and drug-device combinations. Furthermore, the model has demonstrated its effectiveness in predicting the amount of aerosol delivered to "normal" subjects. However, challenges remain in predicting deposition in obstructive lung disease.