Understanding Respiratory Challenges in Preterm Infants
Preterm infants, born before 37 weeks of gestation, face significant respiratory vulnerabilities due to immature lung development. In Australia, approximately 8% of births—around 26,000 babies annually—are preterm, with very preterm infants (<32 weeks) at highest risk for conditions like respiratory distress syndrome (RDS) and bronchopulmonary dysplasia (BPD). BPD affects 20-45% of these vulnerable newborns, often stemming from ventilator-induced lung injury or inadequate aeration monitoring. Traditional tools like chest X-rays expose infants to radiation and lack real-time precision, while oxygenation indices like the oxygen saturation index (OSI) or S/F ratio provide indirect snapshots. Accurate, non-invasive monitoring remains a critical need in neonatal intensive care units (NICUs).
The University of Melbourne's Neonatal Research Centre has long championed innovative solutions, blending preclinical models with clinical trials to refine respiratory support.
The Emergence of Lung Ultrasound in Neonatal Care
Lung ultrasound (LUS) has revolutionized bedside assessment in neonatology, offering radiation-free, portable imaging that detects aeration patterns like B-lines (indicating interstitial syndrome) or consolidations. In preterm care, LUS guides surfactant therapy, predicts extubation success, and monitors bronchopulmonary dysplasia progression. Australian studies highlight its superiority over X-rays for dynamic changes, yet subjective visual scoring limits reproducibility across machines or operators.
Quantitative LUS (Q-LUS) addresses this by using computer-assisted analysis—measuring mean grey value (MGV) or textural features like grey-level correlation—to provide objective metrics. Early applications focused on animal models, paving the way for human translation.
University of Melbourne's Trailblazing Q-LUS Research
Researchers at the University of Melbourne, affiliated with the Murdoch Children's Research Institute and Royal Women's Hospital, have led Q-LUS advancements. Dr. Arun Sett, a neonatologist whose PhD explored LUS-guided respiratory management, spearheaded preterm lamb studies demonstrating Q-LUS detects subtle lung recruitment during ventilation.
Dr. Sheryle Rogerson and collaborators, including Prof. Peter Davis and Prof. David Tingay, validated LUS against gold standards like electrical impedance tomography, showing it outperforms oxygenation estimates in tracking lung volume.Excelling in neonatal research roles at institutions like Melbourne demands interdisciplinary skills in imaging and physiology.
New Breakthrough in Scientific Reports: Q-LUS and Oxygenation Correlation
Published today in Nature Scientific Reports, the study "Computer-assisted analysis of pleural and subpleural lung ultrasound correlates with oxygenation in preterm infants" analyzed 560 LUS images from 70 very preterm infants (<32 weeks) at Melbourne's Joan Kirner Women’s and Children’s Hospital.
Oxygenation was gauged via OSI and S/F ratio during routine NICU care with GE Venue systems. This prospective observational work builds on lamb models, marking a pivotal human validation.Read the full study.
Photo by John Torcasio on Unsplash
Key Findings: Strong, Machine-Independent Correlations
- MGV showed fair correlation with OSI (ρ=-0.46, p<0.01) and S/F (ρ=0.38, p<0.01), varying by machine.
- Q-LUS grey-level correlation excelled: moderate with OSI (ρ=0.48, p<0.01) and S/F (ρ=-0.54, p<0.01), consistent across Venue 50 and Go.
- Other textures like entropy offered insights but were less robust.
These metrics indirectly reflect lung aeration, enabling precise tracking without invasive measures. In BPD-prone infants, early detection of inhomogeneity could avert injury.
Overcoming Traditional Monitoring Limitations
Chest X-rays miss dynamic shifts, while OSI/S/F lag behind aeration changes. Q-LUS provides real-time, objective data:
- No radiation: Safer for frequent scans.
- Bedside portability: Fits NICU workflows.
- Objectivity: Reduces interobserver variability (ICC>0.87 in priors).
- Regional insight: Pleural/subpleural focus captures dependent lung recruitment.
Challenges persist: training needs, standardization. Australian surveys note barriers like supervisor shortages, yet 72% of clinicians seek POCUS education.Explore research assistant opportunities in neonatal imaging.
Clinical Implications for Australian NICUs
This Q-LUS advance could optimize ventilation strategies, reducing BPD (up to 45% incidence in extremes). By correlating with oxygenation independently of hardware, it democratizes advanced monitoring across regional centers. Integration with protocols for surfactant dosing or weaning could cut ventilator days, vital amid Australia's preterm burden.
Melbourne's NHMRC-funded work (e.g., Investigator Grant 2016662 to Brett Manley) exemplifies translational impact.Australian university jobs in neonatology are booming.
University announcementSpotlight on the Research Team
Dr. Arun Sett (Newborn Services, Western Health; U Melbourne) drives Q-LUS from lamb-to-bedside. Co-authors like Dr. Sheryle Rogerson (Newborn Research Centre) and Profs. Davis/Tingay bring decades of expertise. Their portfolio includes extubation prediction and regional aeration studies, positioning Melbourne as a global leader.Thrive in postdoc roles like theirs.
Photo by Darren Nunis on Unsplash
Future Outlook: Trials and Integration
Ongoing: LUNAR trial tests LUS in alveolar recruitment. Broader adoption hinges on guidelines, training. Q-LUS could personalize care, aligning with Australia's preterm prevention gains (8.6% rate, down via Every Week Counts). Watch for RCTs validating clinical endpoints like BPD reduction.
Why This Matters for Higher Education and Research Careers
U Melbourne's feat underscores interdisciplinary neonatology's allure. Aspiring researchers can leverage Rate My Professor for insights, pursue higher ed jobs, or access career advice. Explore university jobs or post a job to join such impactful teams.