Imaging of pulmonary fibrosis in children: A review, with proposed diagnostic criteria.

Computed tomography (CT) imaging findings of pulmonary fibrosis are well established for adults and have been shown to correlate with prognosis and outcome. Recognition of fibrotic CT findings in children is more limited. With approved treatments for adult pulmonary fibrosis, it has become critical to define CT criteria for fibrosis in children, to identify patients in need of treatment and those eligible for clinical trials. Understanding how pediatric fibrosis compares with idiopathic pulmonary fibrosis and other causes of fibrosis in adults is increasingly important as these patients transition to adult care teams. Here, we review what is known regarding the features of pulmonary fibrosis in children compared with adults. Pulmonary fibrosis in children may be associated with genetic surfactant dysfunction disorders, autoimmune systemic disorders, and complications after radiation, chemotherapy, transplantation, and other exposures. Rather than a basal-predominant usual interstitial pneumonia pattern with honeycombing, pediatric fibrosis is primarily characterized by reticulation, traction bronchiectasis, architectural distortion, or cystic lucencies/abnormalities. Ground-glass opacities are more frequent in children with fibrotic interstitial lung disease than adults, and disease distribution appears more diffuse, without clearly defined axial or craniocaudal predominance. Following discussion and consensus amongst a panel of expert radiologists, pathologists and physicians, distinctive disease features were integrated to develop criteria for the first global Phase III trial in children with pulmonary fibrosis.

Estimating the effect of nintedanib on forced vital capacity in children and adolescents with fibrosing interstitial lung disease using a Bayesian dynamic borrowing approach.

BACKGROUND: The rarity of childhood interstitial lung disease (chILD) makes it challenging to conduct powered trials. In the InPedILD trial, among 39 children and adolescents with fibrosing ILD, there was a numerical benefit of nintedanib versus placebo on change in forced vital capacity (FVC) over 24 weeks (difference in mean change in FVC % predicted of 1.21 [95% confidence interval: -3.40, 5.81]). Nintedanib has shown a consistent effect on FVC across populations of adults with different diagnoses of fibrosing ILD. METHODS: In a Bayesian dynamic borrowing analysis, prespecified before data unblinding, we incorporated data on the effect of nintedanib in adults and the data from the InPedILD trial to estimate the effect of nintedanib on FVC in children and adolescents with fibrosing ILD. The data from adults were represented as a meta-analytic predictive (MAP) prior distribution with mean 1.69 (95% credible interval: 0.49, 3.08). The adult data were weighted according to expert judgment on their relevance to the efficacy of nintedanib in chILD, obtained in a formal elicitation exercise. RESULTS: Combined data from the MAP prior and InPedILD trial analyzed within the Bayesian framework resulted in a median difference between nintedanib and placebo in change in FVC % predicted at Week 24 of 1.63 (95% credible interval: -0.69, 3.40). The posterior probability for superiority of nintedanib versus placebo was 95.5%, reaching the predefined success criterion of at least 90%. CONCLUSION: These findings, together with the safety data from the InPedILD trial, support the use of nintedanib in children and adolescents with fibrosing ILDs.

Initiatives to improve lung and sleep health in children: Delphi consensus from the pediatrics, pulmonary, and sleep conference.

BACKGROUND AND OBJECTIVES: The lung and sleep health of adults is heavily influenced by early factors, both genetic and environmental; therefore, optimizing respiratory health begins in childhood. Multiple barriers impede improvements in lung and sleep health for children. First, the traditional siloing between general pediatric care in the community, pediatric pulmonary and sleep subspecialty care, and the research community limits the translation of knowledge into practice. Additionally, identifying and addressing health disparities remains a challenge. The 2021 NHLBI-sponsored workshop "Defining and Promoting Pediatric Pulmonary Health (DAP3H)" was a first step in defining critical gaps in our current healthcare system in identifying and optimizing lung and sleep health in children. The workshop identified key opportunities including measuring pulmonary function in young children, sleep-focused outcomes, developing biomarkers, and longitudinal research cohorts. To expand on the work of DAP3H and continue initiatives to improve childhood lung and sleep health, the Pediatrics & Pulmonary Network: Improving Health Together conference was held in 2023. STUDY DESIGN: A modified Delphi process was applied to form consensus surrounding gaps, barriers, and action items, with the goal of identifying the most urgent opportnities for improving childhood lung and sleep health. RESULTS: Cross-cutting foundational principles were identified as: (1) Authentic Stakeholder Collaboration & Engagement, (2) Reach & Implementation in Real World Settings, (3) Understanding Current Landscape & Resources and (4) Purposeful Diversity, Equity, & Inclusion Initiatives. CONCLUSIONS: To improve lung and sleep health in children, these principles should be the foundation for research design, development, and implementation.

Delivery and actuation of aerosolized microbots.

For disease of the lung, the physical key to effective inhalation-based therapy is size; too large (10's of µm) and the particles or droplets do not remain suspended in air to reach deep within the lungs, too small (subµm) and they are simply exhaled without deposition. µBots within this ideal low-µm size range however are challenging to fabricate and would lead to devices that lack the speed and power necessary for performing work throughout the pulmonary network. To uncouple size from structure and function, here we demonstrate an approach where individual building blocks are aerosolized and subsequently assembled in situ into µbots capable of translation, drug delivery, and mechanical work deep within lung mimics. With this strategy, a variety of pulmonary diseases previously difficult to treat may now be receptive to µbot-based therapies.