Chest wall thickness and depth to vital structures in paediatric patients – implications for prehospital needle decompression of tension pneumothorax

Terboven, Tom; Leonhard, Georg; Wessel, Lucas; Viergutz, Tim; Rudolph, Marcus; Schöler, Michael; Weis, Meike; Haubenreisser, Holger

doi:10.1186/s13049-019-0623-5

Cited by 19 publications

(24 citation statements)

References 20 publications

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“…[9][10][11][12] The studies advancing the clinical translation of GASMAS into respiratory healthcare have focused on neonates as the thickness of protective organs surrounding their lungs is within the limits of penetration depth for near-infrared light. 13,14 GASMAS exploits the fact that the absorption signal of gases is unique against the tissue background. The absorption bands of O 2 and H 2 O are typically 0.001 nm, 15 which can be distinguished from the absorption imprint of the organs around the lungs (both liquid and solid), which is generally in the 10 nm range.…”

Section: Gas In Scattering Media Absorption Spectroscopymentioning

confidence: 99%

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Lung tissue phantom mimicking pulmonary optical properties, relative humidity, and temperature: a tool to analyze the changes in oxygen gas absorption for different inflated volumes

et al. 2021

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Section: Gas In Scattering Media Absorption Spectroscopymentioning

confidence: 99%

“… 9 – 12 The studies advancing the clinical translation of GASMAS into respiratory healthcare have focused on neonates as the thickness of protective organs surrounding their lungs is within the limits of penetration depth for near-infrared light. 13 , 14 …”

Section: Introductionmentioning

confidence: 99%

Lung tissue phantom mimicking pulmonary optical properties, relative humidity, and temperature: a tool to analyze the changes in oxygen gas absorption for different inflated volumes

et al. 2021

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“…This is a very wide range compared to the normal respiratory rate in adults (12 to 16 breaths/min). In addition, the smaller thoracic cage, relatively larger heart, and higher conductance of the chest wall in young children result in higher degrees of interference of heart sounds during chest auscultation than in adults 19 , 20 . Therefore, the majority of the recorded lung sounds will have heart sounds in the background.…”

Section: Discussionmentioning

confidence: 99%

A machine learning approach to the development and prospective evaluation of a pediatric lung sound classification model

Park

Kim

et al. 2023

Sci Rep

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Auscultation, a cost-effective and non-invasive part of physical examination, is essential to diagnose pediatric respiratory disorders. Electronic stethoscopes allow transmission, storage, and analysis of lung sounds. We aimed to develop a machine learning model to classify pediatric respiratory sounds. Lung sounds were digitally recorded during routine physical examinations at a pediatric pulmonology outpatient clinic from July to November 2019 and labeled as normal, crackles, or wheezing. Ensemble support vector machine models were trained and evaluated for four classification tasks (normal vs. abnormal, crackles vs. wheezing, normal vs. crackles, and normal vs. wheezing) using K-fold cross-validation (K = 10). Model performance on a prospective validation set (June to July 2021) was compared with those of pediatricians and non-pediatricians. Total 680 clips were used for training and internal validation. The model accuracies during internal validation for normal vs. abnormal, crackles vs. wheezing, normal vs. crackles, and normal vs. wheezing were 83.68%, 83.67%, 80.94%, and 90.42%, respectively. The prospective validation (n = 90) accuracies were 82.22%, 67.74%, 67.80%, and 81.36%, respectively, which were comparable to pediatrician and non-pediatrician performance. An automated classification model of pediatric lung sounds is feasible and maybe utilized as a screening tool for respiratory disorders in this pandemic era.

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“…As sites for US and X-ray measurements, crossings of the 4th and 5th ICSs with a line laterally to the anterior axillar line were defined, based on the pertinent literature [13][14][15]. While the US scanner could be positioned directly at the puncture site, the measuring point for the PHD had to be defined separately based on 2-dimensional X-ray images, offering only an approximation to the 3-dimensional chest.…”

Section: Discussionmentioning

confidence: 99%

Safely Inserting Neonatal Chest Drains

et al. 2021

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Background: Inserting a chest drain for a left-sided neonatal pneumothorax carries a risk of penetrating the pericardium. We identified reference ranges for the chest wall thickness (CWT) and distance between the pericardium and parietal pleura to improve safety of chest tube insertion. Method: We prospectively measured the CWT using ultrasound in 20 neonates (body weight [BW] 640–2,700 g, age <10 days) at the usual site of puncture in the 4th and 5th intercostal space (ICS). Furthermore, we measured the minimal distance between the parietal pleura and the cardiac silhouette in 131 neonatal chest X-rays (birth weight, 420–4,930 g [divided into 11 weight groups]; age <10 days). Both data sets were transformed into weight-dependent percentiles (Ps). We considered the difference between the sum of P 2.5 for the CWT plus P 2.5 for pleura-heart distance minus P 97.5 for the CWT as a safe corridor for placing the tip of the needle. Results: At both ICSs, curves for the above metrics did not cross, indicating a narrow but safe corridor for each BW with at least 97.5% probability. This safety corridor was 4.6–5.2 mm wide for the 4th and 2.8–3.4 mm for the 5th ICS. Conclusion: These data offer a reference for left-sided chest drain insertion for BW <2,700 g, which may help to improve safety of the procedure.

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Chest wall thickness and depth to vital structures in paediatric patients – implications for prehospital needle decompression of tension pneumothorax

Cited by 19 publications

References 20 publications

Lung tissue phantom mimicking pulmonary optical properties, relative humidity, and temperature: a tool to analyze the changes in oxygen gas absorption for different inflated volumes

Lung tissue phantom mimicking pulmonary optical properties, relative humidity, and temperature: a tool to analyze the changes in oxygen gas absorption for different inflated volumes

A machine learning approach to the development and prospective evaluation of a pediatric lung sound classification model

Safely Inserting Neonatal Chest Drains

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