BACKGROUND: The respiratory mass spectrometer is the current gold-standard technique for performing multiple-breath inert gas washout (MBW), but is expensive and lacks portability. A number of alternative techniques have recently been described. OBJECTIVES: We aimed to validate, using an in vitro lung model, an open-circuit MBW system that utilises a portable photoacoustic gas analyser, with sulphur hexafluoride (SF6) as the inert tracer gas. METHODS: An acrylic glass lung model was utilised to assess the accuracy of functional residual capacity (FRC) measurements derived from MBW. Measurements were performed in triplicate at 20 combinations of simulated FRC, tidal volume and respiratory rate. FRC measured using MBW (FRCmbw) was compared to FRC calculated from the known dimensions of the model (FRCcalc). MBW was also performed in 10 healthy subjects and 14 patients with asthma. RESULTS: The MBW system measured FRC with high precision. The mean bias of FRCmbw with respect to FRCcalc was -0.4% (95% limits of agreement of -4.6 and 3.9%). The mean coefficient of variation of triplicate FRC measurements was 4.0% in vivo and 1.0% in vitro. MBW slightly underestimated low lung volumes and overestimated high lung volumes, but this did not cause a significant error in lung clearance index except at lung volumes below 1,500 ml. CONCLUSIONS: The open-circuit MBW system utilising SF6 as the inert tracer gas and a photoacoustic gas analyser is both accurate and repeatable within the adult range of lung volumes. Further modifications would be required before its use in young children or infants.
BACKGROUND: The respiratory mass spectrometer is the current gold-standard technique for performing multiple-breath inert gas washout (MBW), but is expensive and lacks portability. A number of alternative techniques have recently been described. OBJECTIVES: We aimed to validate, using an in vitro lung model, an open-circuit MBW system that utilises a portable photoacoustic gas analyser, with sulphur hexafluoride (SF6) as the inert tracer gas. METHODS: An acrylic glass lung model was utilised to assess the accuracy of functional residual capacity (FRC) measurements derived from MBW. Measurements were performed in triplicate at 20 combinations of simulated FRC, tidal volume and respiratory rate. FRC measured using MBW (FRCmbw) was compared to FRC calculated from the known dimensions of the model (FRCcalc). MBW was also performed in 10 healthy subjects and 14 patients with asthma. RESULTS: The MBW system measured FRC with high precision. The mean bias of FRCmbw with respect to FRCcalc was -0.4% (95% limits of agreement of -4.6 and 3.9%). The mean coefficient of variation of triplicate FRC measurements was 4.0% in vivo and 1.0% in vitro. MBW slightly underestimated low lung volumes and overestimated high lung volumes, but this did not cause a significant error in lung clearance index except at lung volumes below 1,500 ml. CONCLUSIONS: The open-circuit MBW system utilising SF6 as the inert tracer gas and a photoacoustic gas analyser is both accurate and repeatable within the adult range of lung volumes. Further modifications would be required before its use in young children or infants.
Authors: Jonathan Grønbæk; Henrik Wegener Hallas; Lambang Arianto; Knud Pedersen; Arne Thomsen; Bo Lund Chawes; Hans Bisgaard Journal: Pediatr Res Date: 2016-03-22 Impact factor: 3.756
Authors: Frederik Trinkmann; Johannes Götzmann; Daniel Saur; Michele Schroeter; Katharina Roth; Ksenija Stach; Martin Borggrefe; Joachim Saur; Ibrahim Akin; Julia D Michels Journal: BMC Pulm Med Date: 2017-12-11 Impact factor: 3.317
Authors: Nina Lenherr; Kathryn A Ramsey; Kerstin Jost; Linn Hornwall; Florian Singer; Sophie Yammine; Philipp Latzin Journal: ERJ Open Res Date: 2018-02-23
Authors: Frederik Trinkmann; Steffi A Lenz; Julia Schäfer; Joshua Gawlitza; Michele Schroeter; Tobias Gradinger; Ibrahim Akin; Martin Borggrefe; Thomas Ganslandt; Joachim Saur Journal: Sci Rep Date: 2020-01-30 Impact factor: 4.379