Project description:Extreme preterm infants are a growing population in the neonatal intensive care unit. Multiple factors play a role in preterm birth, resulting in complications including severe bronchopulmonary dysplasia (sBPD) without or with and pulmonary hypertension (BPD-PH). The goal of this study was to identify biomarker signatures associated with sBPD and BPD-PH. We analyzed profiles in tracheal aspirates (TAs) from 46 extremely preterm infants receiving invasive mechanical ventilation (25 sBPD, 21 BPD-PH) . We found specific miRNA signatures in TAs that may serve as biomarkers for the two disease phenotypes.

Project description:Tracheal aspirate (TAs) samples were collected from intubated preterm infants with hemodynamically significant intracardiac shunt (ICS), and a diagnosis of ICS-BPD/ICS-BPD-PH. 36 TA samples were analyzed. Small RNAs were extracted and the expression miRNAs was detected with PCR arrays.

Project description:Extreme preterm infants are a growing population in neonatal intensive care units who carry a high mortality and morbidity. Multiple factors play a role in preterm birth, resulting in major impact on organogenesis leading to complications including bronchopulmonary dysplasia (BPD). The goal of this study was to identify biomarker signatures associated with BPD severity. We analyzed profiles in tracheal aspirates (TAs) from 25 extremely preterm infants receiving invasive mechanical ventilation. Eight infants were diagnosed with mild/moderate BPD, and 17 were diagnosed with severe BPD, according to the NHLBI consensus conference classification . We found specific miRNA signatures in TAs that may serve as biomarkers for BPD severity.

Project description:Extreme preterm infants are a growing population in neonatal intensive care units who carry a high mortality and morbidity. Multiple factors play a role in preterm birth, resulting in major impact on organogenesis leading to complications including bronchopulmonary dysplasia (BPD). The goal of this study was to identify biomarker signatures associated with prematurity and BPD. We analyzed miRNA and mRNA profiles in tracheal aspirates (TAs) from 51 infants receiving invasive mechanical ventilation. 25 infants were extremely preterm and diagnosed with BPD, and 26 were term babies receiving invasive mechanical ventilation for elective procedures. We found specific mRNA-miRNA signatures in TAs that may serve as biomarkers for BPD pathogenesis, a consequence of extreme prematurity.

Project description:miRNA expression in tracheal aspirates in mild/moderate and severe BPD

Project description:miRNA expression in tracheal aspirates

Project description:We analyzed mRNA profiles in tracheal aspirates from 53 newborns receiving invasive mechanical ventilation. Twenty-six infants were extremely preterm diagnosed with BPD and twenty-seven were term babies receiving invasive mechanical ventilation for elective procedure. Specific mRNA signatures in TAs may serve as potential biomarkers for extreme prematurity and BPD pathogenesis.

Project description:Sorted human monocytes, isolated from tracheal aspirates from intubated premature infants.

Project description:Bronchopulmonary dysplasia remains one of the most common complication of prematurity, despite significant improvements in perinatal care. Functional modeling of human lung development and disease, like BPD, is limited by our ability to access the lung and to maintain relevant stem cell populations in culture. Single cell RNA-sequencing confirmed the presence of epithelial cells in tracheal aspirates obtained from intubated neonates. Using combined SMAD signaling inhibition and mTOR inhibition neonatal tracheal-aspirate derived (nTAD) basal stem cells can be expanded long-term and retain the ability to differentiate into pseudo-stratified airway epithelium. Conclusions: Our data demonstrate that neonatal tracheal aspirate-derived epithelial cells can provide a novel ex vivo human cellular model to study neonatal lung development and disease.

Project description:Bronchopulmonary dysplasia remains one of the most common complication of prematurity, despite significant improvements in perinatal care. Functional modeling of human lung development and disease, like BPD, is limited by our ability to access the lung and to maintain relevant stem cell populations in culture. Single cell RNA-sequencing confirmed the presence of epithelial cells in tracheal aspirates obtained from intubated neonates. Using combined SMAD signaling inhibition and mTOR inhibition neonatal tracheal-aspirate derived (nTAD) basal stem cells can be expanded long-term and retain the ability to differentiate into pseudo-stratified airway epithelium. Conclusions: Our data demonstrate that neonatal tracheal aspirate-derived epithelial cells can provide a novel ex vivo human cellular model to study neonatal lung development and disease.