The bias flow nitrogen washout technique for measuring the functional residual capacity in infants

Concept

The open circuit N₂ washout method for assessment of FRC_N2 entails measuring the volume of nitrogen expired after end-tidal expiratory switching of the inspired gas from room air to 100% O₂. At a constant bias flow that exceeds the infant's inspiratory peak flow during tidal breathing, the integrated mixed expired FN₂ (area under the curve of the N₂ concentration (F=fractional concentration) versus time (t)) is multiplied by the constant flow of O₂ (V′), to obtain the volume of expired N₂ (V_N2) 3, 5, 6:Therefore, the accuracy of the method depends on two conditions: 1) the background of O₂ flow remaining constant; and 2) the exhaled N₂ being well mixed with the bias flow of O₂ before the N₂ concentration is analysed 5.

A two-point calibration is performed with known air volumes. With the amount of N₂ washed out measured and the initial fractional alveolar N₂ concentration (F_Ai,N2) known (F_Ai,N2: room air=0.79), then the lung volume at which the washout was initiated can be calculated:The value of 0.02 is subtracted from F_Ai,N2 because the washout is terminated at an end-tidal FN₂ of 0.02 at the airway opening. Since the N₂ is diluted within a mixing chamber (see later), the washout is actually continued until the nitrogen analyser reads an FN₂ of ≤0.0065 in the chamber, which corresponds to the end-tidal FN₂ of 0.02. This dilution effect will depend upon the flow of gas through the N₂ mixing chamber and the size of the chamber. The end-tidal FN₂ cut-off of 0.02 reduces the overestimation of FRC, since previous tissue N₂ elimination studies during pure O₂ breathing in adults and animals suggested that FRC_N2 includes tissue-N₂ dissolved into the lung during prolonged washout 4, 22–24.

Corrections are made for the dead space of the mask and apparatus, the switching error above FRC and body temperature, pressure and saturation (BTPS) (see later).

Face mask

The face mask and the estimation of the effective dead space have been described in detail elsewhere 20, 25.

Three-way switching valve

The three-way switching valve allows the infant to breathe either room air through the PNT or 100% O₂ through a T‐piece. Computer-controlled electronic switching of the three-way valve via a computer keyboard stroke is preferred. The PNT is connected to one of the two-inlet/outlet ports of the three-way valve (fig. 1⇓). The other inlet/outlet port is attached to the T‐piece which carries the constant O₂ bias flow from the flowmeter, through the T‐piece, tubing and N₂ mixing chamber. The infant breathes room air through the face mask, mask port of the three-way valve and PNT. When switched into pure O₂ during the washout, the infant no longer breathes through the PNT (fig. 1⇓) 7, 12. Connecting the PNT to the inlet/outlet port of the three-way valve is the preferred placement because this decreases the dead space and resistance during the washout. The PNT may be placed within the washout circuit by connecting it to the mask port, which is useful in preterm infants with unstable breathing patterns. However, variations in gas temperature, composition and viscosity need to be accounted for as well as the phase shift between the flow and N₂ concentration signals 3.

The operator should be able to choose one of two switching modes: 1) automatic, whereby the software programme monitors stability of the tidal volume (V_T) and expiatory time (t_E) so that when the user triggers the activation of the slide valve, it occurs at the end of the next expiration provided that V_T and t_E of that breath are within a set percentage (e.g. 10%) of the previous mean of 5–10 breaths. This may be difficult to achieve in small babies with rapid or irregular breathing, and it may therefore, be necessary to allow user adjustment of the selected percentage. Nevertheless, this mode has the advantage of being simple to use and minimizing inter-observer variability. For a detailed discussion regarding the use of automatic breath identification, see Bates et al. 26. 2) Manual, whereby the operator waits until a stable tidal breathing (end-expiratory level) pattern is observed in real time on the computer monitor and activates the slide valve as close as possible to end-expiration in a chosen breath 3, 7, 12. This mode requires an experienced operator but is useful if the infant has irregular breathing.

Nitrogen analyser

N₂ concentration is usually measured using emission spectrophotometry in a low-pressure ionization chamber under conditions of constant flow, although a mass spectrometer can also be used. An adjustable needle valve mounted on the mixing chamber is connected to a vacuum pump in order to provide the optimum negative pressure and constant flow for the ionization of nitrogen. The analyser should have: a linear output with a range 0–100% N₂; an accuracy of 1% full range; a resolution of 0.01%; a drift <0.2% N₂·h⁻¹ (stability close to zero N₂ concentration is particularly important); a range of gas sampling rate 9–50 mL·min⁻¹; a recorder output of 0–10 Volts Direct Current (VDC) full scale; a response time (10–90% full scale) of <100 ms.

The manufacturer should provide details regarding the necessary warming time for the equipment 11.

It is anticipated that these requirements will need to be amended for use with newer generations of equipment or alternative ways of measuring FRC_N2, such as those based on CO₂ and O₂ subtraction techniques, which have not yet been validated or sufficiently tried in infant testing. Time characteristics of these systems may have to be assessed using Fast Fourier Transform (FFT) analysis of the N₂ signal using a rapid N₂ analyser.

Nitrogen mixing chamber

The mixing chamber should contain at least three serial channels with baffles to recirculate and mix the gas prior to exiting the chamber. A long (∼2.0 m), low resistance tubing is attached to the outlet port of the mixing chamber to prevent ambient air from diffusing back into the mixing chamber. A chamber volume of about 500 mL would be adequate, even in toddlers, particularly if a collapsible breathing bag is incorporated in the circuit (see later) 11, 12.

Collapsible breathing bag

A collapsible breathing bag (0.5 L) can be incorporated into the washout circuit via a second T‐connection. It should be placed between the infant and the O₂ source but closer to the former. This has been reported to enhance the reproducibility of measurements by acting as a buffer reservoir. This minimizes flow swings within the N₂ mixing chamber during the breathing cycle as well as the retrograde movement of mixed O₂ and N₂ gas after it passes beyond the N₂ sampling needle port. In addition, the bag can be used to monitor the infant's breathing pattern both during the washout and when determining the “end of test” (see later) 11, 12.

Bias flow of oxygen

The bias flow of O₂ should be standardized to facilitate comparison of washout times between laboratories: 10 L·min⁻¹ and 5 L·min⁻¹ are suitable for infants weighing ≥5.0 kg, respectively 3, 12. Nevertheless, the volume of the washout circuit may influence the circuit time constant.

Flowmeter

This has been described elsewhere 20, 26, 27.

Calibration syringe

The exact dead space of the calibration syringe should be known. The combined volume of the syringe once connected to the mask port is generally less than the sum of their individual volumes as determined by water replacement. If both have been made by the same manufacturer, the latter can provide these data, but further confirmation by the investigator using water displacement with the equipment assembled as for use in vivo is recommended 11.

Measurements in infants who require an oxygen supplement

In infants who require an O₂ supplement, FRC can be measured in one of two ways: calibration is performed with gas volumes of the same FN₂ as the infant is breathing, and FRC is calculated as described earlier; calibration is performed with room air, with the calculated volume subsequently being multiplied by a correction factor that accounts for the difference in FN₂ between calibration and alveolar gas 3.

The bias flow N₂ washout technique becomes inaccurate when the fractional concentration of inspired oxygen is >0.7 3.

Helium/O₂ (80/20%) has been used in premature infants to prevent exposure to high O₂ concentration 28 but may not be used interchangeably 29. In addition, the effect of a helium/oxygen mixture on gas mixing, equilibration time and lung volume have yet to be evaluated 3. While pure O₂ has been suggested to decrease tidal breathing significantly 30, 31, there are no data indicating that any potentially harmful effects could result from such short exposures to pure O₂ as during FRC measurement.

Data acquisition

Data acquisition requirements are dealt with elsewhere in this series 21, 26, 27, 32. Particular points of relevance to lung volume measurements are: 1) a sampling rate of 100 Hz is normally adequate for the acquisition of FRC_N2 data. However, 200 Hz may be required for rapidly breathing infants or the washout volume/time measurements (see later). 2) Prior to data acquisition, the operator should be prompted to enter whether a subject is being tested or anin vitro assessment performed, so that any body temperature, pressure and saturation (BTPS) corrections can be switched on or off, respectively. The type of measurement should be indicated in the report 11, 12. 3) Prior to the FRC measurements, tidal flow and hencevolume should be corrected to BTPS conditions, assuming that inspired air is at ambient temperature, pressure and saturation conditions (ATPS) and expired air at BTPS conditions 26. 4) Volume drift, any drift of the tidal volume signal prior to switching the infant into O₂ during FRC measurement should be minimized. 5) A representative end expiratory level must be established (see later). 6) In the absence of any injected air into the O₂ circuit, there should be no drift in the baseline of the integrated nitrogen signal (INS), that is the INS should read zero (arbitrary units), after the three-way valve is activated. When testing patients with airway obstruction, the period during which there is no drift must persist for at least 90–120 seconds 11, 12. 7) End of test should be operator-controlled rather than automatic. End of test is defined by a FN₂ decreasing to 0.0065 within the mixing chamber and N₂ analyser, in the presence of regular breathing. Before ending the washout, the operator must ensure that this low N₂ concentration has been recorded during regular breathing. This can be confirmed by watching the movements of a collapsible breathing bag provided this has been incorporated in the washout circuit (see earlier) 11. In the absence of such movements the test should continue, since the low N₂ concentration may simply be due to a brief apnoea. The infant's head may need to be repositioned if there is any suggestion thatsuch an apnoea could be due to a temporary upper airway obstruction rather than periodic breathing 11. 8) For calculation of FRC_N2 see later. Measured FRC must be converted to BTPS conditions.

Calibration of the nitrogen analyser

Equipment calibration has a significant influence on the calculated results and should be performed with utmost care and according to the manufacturer's recommendations. It is essential that: adequate equipment warming times be used according to the manufacturer's recommendation; calibration is performed with the same equipment configuration as during measurements; the calibration tools are checked periodically; qualified personnel, who understand boththe procedure and data acquisition, perform thecalibration; manual calibration is performed intermittently to check automatic calibration procedures.

After stabilization of the INS baseline, calibration with known low (LV) and a high (HV) room air volumes, below and above the infant's expected FRC, is performed. For a computerized system, integration of the mixed F_N2 signal (INS) (arbitrary units) begins when the mixed F_N2 value is >0.006. Washout is complete when F_N2 falls <0.0065 in the mixing chamber 3.

The slope and intercept of the calibration line are calculated as follows 3:

With any BTPS correction switched off, calibration should be confirmed by using the same syringe volume on two consecutive occasions; the calculated washout volume should be within 1% of the known volume. After infant testing has been completed, calibration should again be confirmed with a known volume after installing a clean N₂ circuit to avoid contamination of the calibrating syringe. This is important to check that there has been no drift of the N₂ analyser during the testing period. The use of calibration volumes equivalent to the infant's measured FRC is recommended, as is the use of similar V_T/FRC ratios and respiratory rates to those of the infant 7, 9, 11, 12.

Monitor display

See also Frey et al. 10.

Tidal breathing parameters

The tidal breathing parameters that need calculating include (see also Bates et al. 26, 32): End expiratory level (EEL); tidal volume; respiratory rate.

The end expiatory level (i.e. FRC) should be established over at least 5 breaths prior to switching the infant into O₂, after correcting for any volume drift. For consistency, it is suggested that the EEL is calculated as the mean of all selected end expiratory points after drift correction, and that the selected level is clearly displayed on a time based trace for verification of accuracy by the operator. Some user flexibility may be required in those cases where EEL is particularly variable.

Calculation of FRC_N2

As described earlier, the integrated mixed expired FN₂ versus time (t) is multiplied by the constant flow of O₂ (V′) to obtain the volume of expired N₂ (V_N2): The total volume (V_tot) measured by the washout, which is at ATPS, is calculated (see earlier): The volume of apparatus dead space (V_ds,app (mL)), including the face mask (see earlier), (assumed to be at ATPS) is subtracted from V_tot to obtain the effective washout volume (V_eff): The V_eff is converted to BTPS (V_eff-BTPS) 24.

The switching errors above FRC should be corrected for by subtracting any volume above EEL (previously converted to BTPS conditions) from the Veff-BTPS to obtain FRC_N2 7, 12: Switching errors should be negligible if automatic switching into O₂ has been employed and the infant has regular breathing (see earlier).

FRC should be calculated from at least two technically acceptable measurements that are within 10% or 10 mL of each other, whichever is the larger or, in the presence of increased variability, the mean of three technically satisfactory trials.

Quality control parameters

FRC_N2 is the only “outcome measure” that will be routinely reported from the nitrogen washout technique. Calibration and raw data of FRC should be saved in ASCII or similar format. Data that should be retrievable for validation purposes by the user, but not necessarily visible, include the uncalibrated analogue-to-digital (A/D) signal and all intermediate calculations leading to the final results. The parameters that should be displayed/available for each individual trial to assist in user or automated selection ofthe “best” data and to provide overall quality assurance, are listed below. Since many of these quality control features need to be summarized in publications describing FRC_N2 measurements in infants, it is essential that such information can be automatically saved and, if required, exported to a suitable spreadsheet.

The use of standard abbreviations as indicated would be of considerable benefit and is strongly recommended. The quality control and other parameters include: number of acceptable measurements (n); total number of measurements performed (n-tot); volume of apparatus dead space (V_ds,app) (mL); type and size of mask e.g. Rendall Baker size; mean tidal volume prior to FRC measurement (V_T (mL)); mean respiratory rate prior to FRC measurement (RR (min⁻¹)); minute ventilation (expired minute ventilation) prior to FRC measurement, calculated as RR×V_T (V'_E; also referred to as MV); stability of EEL prior to switching the infant into O₂, expressed as % variability of end expiratory points over “n” (five) breaths prior to each switching of the infant into O₂ during FRC measurement (EEL%) 26, 27; stability of EEL prior to each switching into O₂ during FRC measurement, expressed as the SD of the end expiratory points relative to the baseline over “n” (five) breaths prior to each manoeuvre (EEL-s, (mL)) 26, 27; volume above EEL reflecting the switching error above FRC (V_>FRC (mL)); FRC washout time (t_FRCN2 (s)); cumulative volume washed out at 50, 75, and 85% of the (total) washout time, FRC_50N2, FRC_75N2, FRC_85N2 (the potential usefulness of such parameters have yet to be explored).