Changes in pulmonary oxygen content are detectable with laser absorption spectroscopy: proof of concept in newborn piglets
Autor: | Vineta Fellman, Jim Larsson, Joakim Bood, Dennis Leander, Emilie Krite Svanberg, Gorm Greisen, Martin Bo Rasmussen, Marcus Larsson, Sara Bergsten |
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Rok vydání: | 2020 |
Předmět: |
Swine
Atelectasis 03 medical and health sciences Esophagus 0302 clinical medicine 030225 pediatrics Fraction of inspired oxygen medicine Animals Lung Skin Tunable diode laser absorption spectroscopy Phantoms Imaging business.industry Chemistry Lasers Spectrum Analysis Balloon catheter Water respiratory system Pleural cavity medicine.disease Basic Science Article Respiration Artificial respiratory tract diseases Oxygen medicine.anatomical_structure Animals Newborn Pneumothorax Spectrophotometry Fluoroscopy Pediatrics Perinatology and Child Health Room air distribution Blood Gas Analysis Nuclear medicine business 030217 neurology & neurosurgery |
Zdroj: | Pediatric Research |
ISSN: | 1530-0447 0031-3998 |
Popis: | Background Using an optical method based on tunable diode laser absorption spectroscopy, we previously assessed oxygen (O2) and water vapor (H2O) content in a tissue phantom of the preterm infant lung. Here we applied this method on newborn piglets with induced lung complications. Methods Five mechanically ventilated piglets were subjected to stepwise increased and decreased fraction of inspired oxygen (FiO2), to atelectasis using a balloon catheter in the right bronchus, and to pneumothorax by injecting air in the pleural cavity. Two diode lasers (764 nm for O2 gas absorption and 820 nm for H2O absorption) were combined in a probe delivering light either externally, on the skin, or internally, through the esophagus. The detector probe was placed dermally. Results Calculated O2 concentrations increased from 20% (IQR 17−23%) when ventilated with room air to 97% (88−108%) at FiO2 1.0. H2O was only detectable with the internal light source. Specific light absorption and transmission patterns were identified in response to atelectasis and pneumothorax, respectively. Conclusions The optical method detected FiO2 variations and discriminated the two induced lung pathologies, providing a rationale for further development into a minimally invasive device for real-time monitoring gas changes in the lungs of sick newborn infants. Impact Optical spectroscopy can detect pulmonary complications in an animal model.Oxygen concentrations can be evaluated in the lungs.Presents a novel minimally invasive method to detect lung oxygenation and complications.Potential to be developed into a lung monitoring method in newborn infants.Potential for bed-side detection of pulmonary complications in newborn infants. |
Databáze: | OpenAIRE |
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