Abstract:The inspired sine-wave technique (IST) is a new method that can provide simple, non-invasive cardiopulmonary measurements. Over successive tidal breaths, the concentration of a tracer gas (i.e. nitrous oxide, N O) is sinusoidally modulated in inspired air. Using a single-compartment tidal-ventilation lung model, the resulting amplitude/phase of the expired sine wave allows estimation of end-expired lung volume (ELV), pulmonary blood flow and three indices for ventilatory heterogeneity (VH; ELV /FRC , ELV /FRC … Show more
“…IST measurements of absolute ELV are below those measured by SF 6 and CT by 12e13% and do not fall within 5% of the reference method recommended by the European Respiratory Society/American Thoracic Society consensus statement. 33 These results are consistent with a previous study of IST, in which Bruce and colleagues 17 showed that IST underestimated functional residual capacity (FRC) by 32% (1080 ml) compared with body plethysmography in humans, where the mean FRC was 3.4 L. The underestimation was smaller in our study, with a mean bias of e12 to e13% (e129 to e161 ml), where the overall mean ELV was 809 ml. IST measures the volume of ventilated regions of the lung, and it is expected that IST will underestimate lung volume compared with CT, which estimates the entire thoracic gas volume.…”
Section: Discussionsupporting
confidence: 92%
“…IST uses commercially available components commonly used in anaesthetic/intensive care practice, and has proven efficacy in spontaneously ventilating healthy volunteers. 17,18 To date, IST's ability to measure ELV in mechanically ventilated lungs has not been tested.…”
mentioning
confidence: 99%
“…The repeatability of IST measurements of ELV in the same subject under the same conditions was within the reported international acceptable limits of coefficient of variation (<10%) 34 and consistent with studies of IST in other circumstances. 17 IST has good repeatability and minimal bias compared with CT (mean bias¼e1 ml) when measuring changes in lung volume. This provides support for the use of IST to monitor trends in lung volume, where the change (or lack of) in volume after a change in ventilator setting is potentially of most interest to the bedside clinician.…”
Background: Bedside lung volume measurement could personalise ventilation and reduce driving pressure in patients with acute respiratory distress syndrome (ARDS). We investigated a modified gas-dilution method, the inspired sinewave technique (IST), to measure the effective lung volume (ELV) in pigs with uninjured lungs and in an ARDS model. Methods: Anaesthetised mechanically ventilated pigs were studied before and after surfactant depletion by saline lavage. Changes in PEEP were used to change ELV. Paired measurements of absolute ELV were taken with IST (ELV IST) and compared with gold-standard measures (sulphur hexafluoride wash in/washout [ELV SF6 ] and computed tomography (CT) [ELV CT ]). Measured volumes were used to calculate changes in ELV (DELV) between PEEP levels for each method (DELV IST , DELV SF6 , and DELV CT). Results: The coefficient of variation was <5% for repeated ELV IST measurements (n¼13 pigs). There was a strong linear relationship between ELV IST and ELV SF6 in uninjured lungs (r 2 ¼0.97), and with both ELV SF6 and ELV CT in the ARDS model (r 2 ¼0.87 and 0.92, respectively). ELV IST had a mean bias of e12 to 13% (95% limits¼±17 e 25%) compared with ELV SF6 and ELV CT. DELV IST was concordant with DELV SF6 and DELV CT in 98e100% of measurements, and had a mean bias of e73 to e77 ml (95% limits¼±128 e 186 ml) compared with DELV SF6 and e1 ml (95% limits ±333 ml) compared with DELV CT. Conclusions: IST provides a repeatable measure of absolute ELV and shows minimal bias when tracking PEEP-induced changes in lung volume compared with CT in a saline-lavage model of ARDS.
“…IST measurements of absolute ELV are below those measured by SF 6 and CT by 12e13% and do not fall within 5% of the reference method recommended by the European Respiratory Society/American Thoracic Society consensus statement. 33 These results are consistent with a previous study of IST, in which Bruce and colleagues 17 showed that IST underestimated functional residual capacity (FRC) by 32% (1080 ml) compared with body plethysmography in humans, where the mean FRC was 3.4 L. The underestimation was smaller in our study, with a mean bias of e12 to e13% (e129 to e161 ml), where the overall mean ELV was 809 ml. IST measures the volume of ventilated regions of the lung, and it is expected that IST will underestimate lung volume compared with CT, which estimates the entire thoracic gas volume.…”
Section: Discussionsupporting
confidence: 92%
“…IST uses commercially available components commonly used in anaesthetic/intensive care practice, and has proven efficacy in spontaneously ventilating healthy volunteers. 17,18 To date, IST's ability to measure ELV in mechanically ventilated lungs has not been tested.…”
mentioning
confidence: 99%
“…The repeatability of IST measurements of ELV in the same subject under the same conditions was within the reported international acceptable limits of coefficient of variation (<10%) 34 and consistent with studies of IST in other circumstances. 17 IST has good repeatability and minimal bias compared with CT (mean bias¼e1 ml) when measuring changes in lung volume. This provides support for the use of IST to monitor trends in lung volume, where the change (or lack of) in volume after a change in ventilator setting is potentially of most interest to the bedside clinician.…”
Background: Bedside lung volume measurement could personalise ventilation and reduce driving pressure in patients with acute respiratory distress syndrome (ARDS). We investigated a modified gas-dilution method, the inspired sinewave technique (IST), to measure the effective lung volume (ELV) in pigs with uninjured lungs and in an ARDS model. Methods: Anaesthetised mechanically ventilated pigs were studied before and after surfactant depletion by saline lavage. Changes in PEEP were used to change ELV. Paired measurements of absolute ELV were taken with IST (ELV IST) and compared with gold-standard measures (sulphur hexafluoride wash in/washout [ELV SF6 ] and computed tomography (CT) [ELV CT ]). Measured volumes were used to calculate changes in ELV (DELV) between PEEP levels for each method (DELV IST , DELV SF6 , and DELV CT). Results: The coefficient of variation was <5% for repeated ELV IST measurements (n¼13 pigs). There was a strong linear relationship between ELV IST and ELV SF6 in uninjured lungs (r 2 ¼0.97), and with both ELV SF6 and ELV CT in the ARDS model (r 2 ¼0.87 and 0.92, respectively). ELV IST had a mean bias of e12 to 13% (95% limits¼±17 e 25%) compared with ELV SF6 and ELV CT. DELV IST was concordant with DELV SF6 and DELV CT in 98e100% of measurements, and had a mean bias of e73 to e77 ml (95% limits¼±128 e 186 ml) compared with DELV SF6 and e1 ml (95% limits ±333 ml) compared with DELV CT. Conclusions: IST provides a repeatable measure of absolute ELV and shows minimal bias when tracking PEEP-induced changes in lung volume compared with CT in a saline-lavage model of ARDS.
“…Details of the IST and inspired sinewave device (ISD) have been detailed elsewhere, 15 but in brief: at the start of each inhalation a small volume of N 2 O is injected into inspired gas by a mass flow controller (Alicat Scientific, Inc., Tucson, AZ, USA). Airflow is measured using an ultrasonic flowmeter (VenThor 22/2A; Thor Laboratories, Budapest, Hungary), and N 2 O concentration using a rapid mainstream infrared sensor (Square One Technology, Boulder, CO, USA).…”
Section: Methodsmentioning
confidence: 99%
“…S1.Fig 1A typical example of recorded data, with inspired N 2 O concentration oscillating sinusoidally around a fixed mean (4%), with a predetermined amplitude (3%) and period (180 s). Green line is the expired N 2 O concentration; the blue and red crosses are the N 2 O concentrations in inspired gas and end-tidal gas, respectively; the blue and red lines are the inspired and expired N 2 O sinewaves, respectively (reproduced from Bruce and colleagues 15 ). …”
Background
Cardiac output
monitoring can support the management of high-risk surgical patients, but the pulmonary artery catheterisation required by the current ‘gold standard’—bolus thermodilution
—has the potential to cause life-threatening complications. We present a novel noninvasive and fully automated method that uses the inspired sinewave technique to continuously monitor cardiac output
.
Methods
Over successive breaths the inspired nitrous oxide (N
2
O) concentration was forced to oscillate sinusoidally with a fixed mean (4%), amplitude (3%), and period (60 s).
was determined in a single-compartment tidal ventilation lung model that used the resulting amplitude/phase of the expired N
2
O sinewave. The agreement and trending ability of
were compared with
during pharmacologically induced haemodynamic changes, before and after repeated lung lavages, in eight anaesthetised pigs.
Results
Before lung lavage, changes in
and
from baseline had a mean bias of –0.52 L min
−1
(95% confidence interval [CI], –0.41 to –0.63). The concordance between
and
was 92.5% as assessed by four-quadrant analysis, and polar plot analysis revealed a mean angular bias of 5.98° (95% CI, –24.4°–36.3°). After lung lavage, concordance was slightly reduced (89.4%), and the mean angular bias widened to 21.8° (–4.2°, 47.6°). Impaired trending ability correlated with shunt fraction (
r
=0.79,
P
<0.05).
Conclusions
The inspired sinewave technique provides continuous and noninvasive monitoring of cardiac output, with a ‘marginal–good’ trending ability compared with cardiac output based on thermodilution. However, the trending ability can be reduced with increasing shunt fraction, such as in acute lung injury.
The degree of specific ventilatory heterogeneity (spatial unevenness of ventilation) of the lung is a useful marker of early structural lung changes which has the potential to detect early-onset disease. The Inspired Sinewave Test (IST) is an established noninvasive ‘gas-distribution’ type of respiratory test capable of measuring the cardiopulmonary parameters. We developed a simulation-based optimisation for the IST, with a simulation of a realistic heterogeneous lung, namely a lognormal distribution of spatial ventilation and perfusion. We tested this method in datasets from 13 anaesthetised pigs (pre and post-lung injury) and 104 human subjects (32 healthy and 72 COPD subjects). The 72 COPD subjects were classified into four COPD phenotypes based on ‘GOLD’ classification. This method allowed IST to identify and quantify heterogeneity of both ventilation and perfusion, permitting diagnostic distinction between health and disease states. In healthy volunteers, we show a linear relationship between the ventilatory heterogeneity versus age ($${R}^{2}=0.42$$
R
2
=
0.42
). In a mechanically ventilated pig, IST ventilatory heterogeneity in noninjured and injured lungs was significantly different (p < 0.0001). Additionally, measured indices could accurately identify patients with COPD (area under the receiver operating characteristic curve is 0.76, p < 0.0001). The IST also could distinguish different phenotypes of COPD with 73% agreement with spirometry.
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