Use of siliconised infant endotracheal tubes reduces work of breathing under turbulent flow

Stankiewicz, B.; Rawicz, M.; Darowski, M.; Zielinski, K.; Kozarski, M.; Chwojnowski, A.

doi:10.1016/j.bbe.2016.11.002

Artykuł - szczegóły

Tytuł artykułu

Use of siliconised infant endotracheal tubes reduces work of breathing under turbulent flow

Autorzy

Stankiewicz B. , Rawicz M. , Darowski M. , Zielinski K. , Kozarski M. , Chwojnowski A.

Wybrane pełne teksty z tego czasopisma

Identyfikatory

DOI

10.1016/j.bbe.2016.11.002

Warianty tytułu

Języki publikacji

Abstrakty

The high resistance of an infant endotracheal tube (ETT) can markedly impair ventilation and gas exchange. Since some manufacturers cover the inner surface of their ETTs with a silicon layer in order to diminish deposition and ease mucous evacuation from airway, via surface roughness decrease, we assessed whether the silicon layer may affect tube resistance, work of breathing and other parameters of ventilation. We compared SUMI (Poland) non-siliconised and siliconised polyvinyl chloride ETTs (2.5, 3.0 and 4.0 mm ID), twenty of each type and size combination. Simulating volume-controlled ventilation with the hybrid (numerical–physical) lung models of a premature infant and a 3-month-old baby peak inspiratory pressure (PIP), peak inspiratory and expiratory flow (PIF, PEF), (patient + ETT) inspiratory and expiratory airway resistance (Rins, Rexp) and work of breathing by ventilator (WOB_vt) were measured. Additionally, images of the both type surfaces were taken using Hitachi TM-1000 electron microscope. When 2.5 and 3.0 mm ID ETTs were examined, laminar flow (Re <2300) across the tube was observed, and there were no clinically significant differences in the ventilation param-eters between non-siliconised and siliconised tubes. Whereas, when 4 mm ID ETTs were tested, turbulent flow was observed, and PIP, R_ins, R_exp and WOB_vt were significantly lower (5%, 17%, 17%, and 7%, respectively) (P < 0.05), but PIF and PEF were significantly higher (8%, 14%) (P < 0.05). Thus, the silicone inner surface of ETT offers less resistance and WOB_vt in presence of turbulent flow. However, artifacts observed on the surface of non-siliconised and siliconised ETTs can potentially impair ventilation.

Słowa kluczowe

laminar turbulent gas flow endotracheal tube resistance work of breathing

turbulentny przepływ gazu intubacja dotchawicza oddychanie

Wydawca

Nałęcz Institute of Biocybernetics and Biomedical Engineering of the Polish Academy of Sciences
Elsevier

Czasopismo

Biocybernetics and Biomedical Engineering

Rocznik

2017

Tom

Vol. 37, no. 1

Strony

59--65

Opis fizyczny

Bibliogr. 30 poz., rys., tab., wykr.

Twórcy

autor

Stankiewicz B.

bstankiewicz@ibib.waw.pl

Nalecz Institute of Biocybernetucs and Biomedical Engineering, Polish Academy of Sciences, 4 Ks. Trojdena Street, 02-109 Warsaw, Poland

autor

Rawicz M.

marcin.rawicz@wsdz.pl

Warsaw Children Hospital, Warsaw, Poland

autor

Darowski M.

mdar@ibib.waw.pl

Nalecz Institute of Biocybernetucs and Biomedical Engineering, Polish Academy of Sciences, 4 Ks. Trojdena Street, 02-109 Warsaw, Poland

autor

Zielinski K.

kzielinski@ibib.waw.pl

Nalecz Institute of Biocybernetucs and Biomedical Engineering, Polish Academy of Sciences, 4 Ks. Trojdena Street, 02-109 Warsaw, Poland

autor

Kozarski M.

mkozarski@ibib.waw.pl

Nalecz Institute of Biocybernetucs and Biomedical Engineering, Polish Academy of Sciences, 4 Ks. Trojdena Street, 02-109 Warsaw, Poland

autor

Chwojnowski A.

achwojnowski@ibib.waw.pl

Nalecz Institute of Biocybernetucs and Biomedical Engineering, Polish Academy of Sciences, 4 Ks. Trojdena Street, 02-109 Warsaw, Poland

Bibliografia

[1] Fujino Y, Uchiyama A, Mashimo T, Nishimura M. Spontaneously breathing lung model comparison of work of breathing between automatic tube compensation and pressure support. Respir Care 2003;48(1):38–45.
[2] Manczur T, Greenough A, Nicholson GP, Rafferty GF. Resistance of pediatric and neonatal endotracheal tubes: influence of flow rate, size, and shape. Crit Care Med 2000;28(5):1595–8.
[3] Hatch DJ. Tracheal tubes and connectors used in neonates - dimensions and resistance to breathing. Br J Anaesth 1978;50(9):959–64.
[4] Okhuysen RS, Bristow F, Burkhead S, Kolobow T, Lally KP. Evaluation of a new thin-walled endotracheal tube for use in children. Chest 1996;109(5):1335–8. http://journal. publications.chestnet.org/pdfaccess.ashx?ResourceID= 2088946&PDFSource=13.
[5] Kolobow T, Berra L, DeMarchi L, Aly H. Ultrathin-wall, two- stage, twin endotracheal tube: a tracheal tube with minimal resistance and minimal dead space for use in newborn and infant patients. Pediatr Crit Care Med 2004;5(4):379–83.
[6] Cole F. A new endotracheal tube for infants. Anesthesiology 1945;6(1):87–8. http://anesthesiology.pubs.asahq.org/article. aspx?articleid=1972706.
[7] Stankiewicz B, Darowski M, Glapiński J, Rawicz M, Michnikowski M, Guć M, et al. A new endotracheal tube for infants – laboratory and clinical assessment: a preliminary study. Paediatr Anaesth 2013;23(5):440–5.
[8] Newth CJL, Venkataraman S, Willson DF, Meert KL, Harrison R, Dean JM, et al. Weaning and extubation readiness in pediatric patients. Pediatr Crit Care Med 2009;10(1):1–11.
[9] Brewis C, Pracy J, Albert D. Localized tracheomalcia as a complication of the Cole tracheal tube. Paediatr Anaesth 1999;9:531–3. http://onlinelibrary.wiley.com/doi/10.1046/ j.1460-9592.1999.00408.x/pdf.
[10] Mitchell M, Bailey C. Dangerous of neonatal intubation with the Cole tube. BMJ 1990;301(6752):602–3. http://www.ncbi. nlm.nih.gov/pmc/articles/PMC1663713/pdf/bmj00197-0044. pdf.
[11] Maeda Y, Fujino Y, Uchiyama A, Taenaka N, Mashimo T, Nishimura M. Does the tube-compensation function of two modern mechanical ventilators provide effective work of breathing relief? Crit Care 2003;7(5):R92–7.
[12] Oto J, Imanaka H, Nakataki E, Ono R, Nishimura M. Potential inadequacy of automatic tube compensation to decrease inspiratory work load after at least 48 hours of endotracheal tube use in the clinical setting. Respir Care 2012;57(5):697–703.
[13] Guttmann J, Kessler V, Mols G, Hentschel R, Haberthür C, Geiger K. Continuous calculation of intratracheal pressure in the presence of pediatric endotracheal tubes. Crit Care Med 2000;28(4):1018–26.
[14] Keszler M. State of the art in conventional mechanical ventilation. J Perinatol 2009;29:262–75.
[15] Douglas J, Gasiorek J, Swaffield J, Jack L. Fluid mechanics. 5th ed. Harlow: Pearson Education Ltd; 2006.
[16] Yang BH, Joseph DD. Virtual Nikuradse. J Turbul 2009;10 (4):1–24.
[17] Kozarski M, Ferrari G, Darowski M, Zielinski K, Palko K. Hybrid models. In: Darowski M, Ferrari G, editors. Compr. Model. Cardiovasc. Respir. Syst. Their Mech. Support Interact.. 1st ed. New York: Nova Science Publisher Inc; 2009 [chapter 8].
[18] Kozarski M, Zieliński K, Pałko KJ, Stankiewicz B, Bozewicz D, Darowski M. The new hybrid pneumo-piston model of lungs mechanics–preliminary tests. Biocybern Biomed Eng 2009;29(3):3–18.
[19] Heulitt M, Ouellet P. Respiratory system physiology. In: Slonim A, Pollack M, editors. Pediatr. Crit. Care Med.. 1st ed. Philadelphia: Lippincott Williams & Wilkins; 2006 [chapter 6].
[20] Hofman W, Meyer D. Respiratory physiology. In: Nosek T, editor. Essentials Hum. Physiol.. 1st ed. Tampa: Gold Standard Multimedia Inc; 2000 [chapter 4].
[21] Taylor JB, Carrano AL, Kandlikar SG. Characterization of the effect of surface roughness and texture on fluid flow - past, present, and future. Int J Therm Sci 2006;45(10):962–8.
[22] Colebrook CF. Turbulent flow in pipes, with particular reference to the transition region between the smooth and rough pipe laws. J ICE 1939;11(4):133–56.
[23] Nikuradse J. Laws of flow in rough pipes. J Appl Phys 1950;3:1–63.
[24] Moody LF. Friction factors for pipe flow. Trans ASME 1944;66:671–84. http://user.engineering.uiowa.edu/{~}me{_} 160/lecture{_}notes/MoodyLFpaper1944.pdf.
[25] Kandlikar SG, Schmitt D, Carrano AL, Taylor JB. Characterization of surface roughness effects on pressure drop in single-phase flow in minichannels. Phys Fluids 2005;17(10).
[26] Kandlikar SG. Roughness effects at microscale–reassessing Nikuradse's experiments on liquid flow in rough tubes. Bull Polish Acad Sci Tech Sci 2005;53(4):343–9. http://www.rit. edu/_w-taleme/Papers/Journal Papers/J050.pdf.
[27] Jarreau PH, Louis B, Dassieu G, Desfrere L, Blanchard PW, Moriette G, et al. Estimation of inspiratory pressure drop in neonatal and pediatric endotracheal tubes. J Appl Physiol 1999;87(1):36–46. http://jap.physiology.org/content/jap/87/ 1/36.full.pdf.
[28] Keszler M, Abukabar M. Physiologic principles. In: Goldsmith JP, Karotkin EH, editors. Assist. Vent. Neonate. 5th ed. St. Louis: Saunders Elsevier; 2011 [chapter 2].
[29] Cave P, Fletcher G. Resistances of nasotracheal tubes used in infants. Anesthesiology 1968;29(3):588–90. http://dx.doi.org/10.1097/00000542-196805000-00045.
[30] Wall MA. Infant endotracheal tube resistance: effects of changing length, diameter, and gas density. Crit Care Med 1980;8(1):38–40.

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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