BACKGROUND: Nitric oxide (NO) is a very reactive agent with potentially toxic oxidation products such as nitrogen dioxide (NO2). Therefore, during NO inhalation a constant inspired concentration and accurate measurement of NO and NO2 concentrations are essential. The objective of this study was to test the NO concentrations at various positions along the inspiratory limb of the breathing circuit using a recently developed system to administer NO in phase with inspiratory flow during mechanical ventilation (Servo 300 NO-A, Siemens, Sweden). Furthermore, we tested whether an active heating system would interfere with inspired NO concentrations. RESULTS: A sharp decline in the NO concentration was found between the respirator's inspiratory outlet and more distal points along the inspiratory limb of the circuit. This finding was most evident when an active heating system was mounted between those points. CONCLUSIONS: The concentrations of NO and NO2 should be measured as near to the patient as possible, as significant fluctuations of these concentrations might be found along the inspiratory limb of the respiratory circuit especially when an active heating system is used.
BACKGROUND:Nitric oxide (NO) is a very reactive agent with potentially toxic oxidation products such as nitrogen dioxide (NO2). Therefore, during NO inhalation a constant inspired concentration and accurate measurement of NO and NO2 concentrations are essential. The objective of this study was to test the NO concentrations at various positions along the inspiratory limb of the breathing circuit using a recently developed system to administer NO in phase with inspiratory flow during mechanical ventilation (Servo 300 NO-A, Siemens, Sweden). Furthermore, we tested whether an active heating system would interfere with inspired NO concentrations. RESULTS: A sharp decline in the NO concentration was found between the respirator's inspiratory outlet and more distal points along the inspiratory limb of the circuit. This finding was most evident when an active heating system was mounted between those points. CONCLUSIONS: The concentrations of NO and NO2 should be measured as near to the patient as possible, as significant fluctuations of these concentrations might be found along the inspiratory limb of the respiratory circuit especially when an active heating system is used.
Inhalation of nitric oxide (NO) has been shown to selectively dilate
the pulmonary vascular bed in animals as well as in humans [1,2,3,4]. Therefore, it has been used to reduce pulmonary
hypertension in neonates [5,6] or
after cardiac surgery [7,8]. In
contrast to intravenously administered vasodilators, inhaled NO does not exert
any vasodilating effect on the systemic circulation due to its rapid
inactivation by haemoglobin when it enters the bloodstream [9,10]. When given via inhalation in
severe acute respiratory distress syndrome (ARDS), NO predominantly produces
vasodilation in the ventilated areas of the lung. Therefore, it does not only
reduce pulmonary hypertension but it also redistributes blood flow towards the
ventilated areas, thereby reducing intrapulmonary shunt and improving arterial
oxygenation [11].For these reasons NO inhalation may become a widespread adjunctive
treatment for severe hypoxaemia or pulmonary hypertension. However, the
administration of gaseous NO is complicated by the fact that NO reacts with
oxygen (O2) to form nitrogen dioxide (NO2) [9,10], which is known to be a toxic
agent causing pulmonary epithelial damage [12,13]. Since the conversion of NO to NO2 is dependent
on the concentration of NO and O2 as well as on their contact time,
the concentrations of both gases and their contact time should be generally
minimized to avoid potential toxic NO2 concentrations [14]. For the clinical use of inhaled NO it is therefore
necessary to monitor the inspiratory gas concentrations carefully.Obviously, it is important to ensure a constant inspired NO
concentration. This might be problematic when NO is administered continuously
from a gas cylinder into the inspiratory limb of the breathing system. Sydow
et al [15] reported significant fluctuations of
NO concentrations along the inspiratory limb of the respiratory tubing using a
simple system to administer NO continuously into the circuit of a phasic flow
ventilator [15]. These fluctuations were dependent on
the measurement site. To our knowledge, no data are available to show that
fluctuations in the NO concentrations occur along the inspiratory limb when
using a system to administer NO only during inspiration and in proportion to
flow.Therefore, the aim of our study was to evaluate the NO and
NO2 concentrations along the inspiratory limb of the respiratory
tubing during mechanical ventilation and NO inhalation. For that investigation
we used a recently developed NO delivery system which is integrated into a
standard respirator (Servo 300 NO-A, Siemens, Lund, Sweden) and which has been
shown to be accurate for the administration of NO between 1 and 100 parts per
million (ppm) [16].
Material and methods
Technique of NO administration
For the administration of NO during mechanical ventilation we used a
prototype of the Servo 300 NO-A. With this device, NO is added into the part of
the inspiratory circuit which is inside the ventilator just before the
inspiratory outlet. An electronically controlled valve is used to add a
NO/nitrogen (N2) mixture proportional to flow into the inspiratory
gas stream. The NO/N2 mixture is delivered from a cylinder. On the
front panel of the ventilator the inspired NO concentration can be adjusted
between 0.3 and 25ppm. The scale is calibrated for a cylinder containing
exactly 2500ppm NO in N2. For any different NO/N2 mixture
the administered NO concentration would have to be calculated accordingly.
NO and NO2 measurement
A chemiluminescence analyser (CLD 700, Eco Physics, Duernten,
Switzerland) was used for measuring NO and NO2 concentrations. With
this device, the response time for NO measurements is dependent on the
measurement range. At 0.1 ppm NO the response time is > 30s and at 100 ppm NO
it is > 6s. A 50-cm gas sampling line of this machine was connected to
measurement ports mounted at four different positions along the inspiratory
limb of the respiratory system (Pos. 1–4). Pos. 1 was immediately after the
inspiratory outlet of the respirator; Pos. 2, 3 and 4 were each 25cm more
distal along the inspiratory limb. When an active humidification system was
placed in the inspiratory limb, it was mounted between Pos. 1 and Pos.2. For
details of the measurement design see Figure 1. Prior to
the measurements the chemiluminescence analyzer was calibrated using defined
calibration gases.
Figure 1
Schematic presentation of the experimental design used. At four
positions (Pos. 1 to Pos. 4) along the inspiratory limb of the respiratory
tubing, NO and NO2 concentrations were measured by means of
chemiluminescence (CLD 700 AL chemiluminometer). The upper part of the figure
demonstrates the measurement design without a humidification system. In the
lower part the site of the active humidification system is indicated between
Pos. 1 and Pos. 2.
Study protocol
Using the pressure controlled mode of mechanical ventilation, NO was
administered in increasing doses of 0.1, 1, 10 and 100 ppm into an
FiO2 of 0.21, without any humidifier mounted into the system. Each
NO concentration was administered for 10min before the first measurement was
taken. NO/NO2 was measured at each position (Pos. 1–4) by
chemiluminescence for at least 2 min to obtain stable values.To investigate the effect of increasing O2 concentrations
the same set of measurements was then repeated for an FiO2 of 0.5
and 1.0.To investigate the effect of additional volume due to the
humidification system, the same set of measurements for all NO concentrations
and all FiO2 values was obtained with an active humidification
system (Concha Therm III with Aerodyne humidification column, Kendall,
Neustadt, Germany) mounted into the respiratory tubing between Pos. 1 and Pos.
2 (Fig 1). In order to discriminate between the possible
effect of the additional volume alone and a possible reaction of NO with water
in the humidification system, all NO concentrations at all FiO2
values were administered when the heating column of the humidifier was empty
and not active and repeated for a water-filled heating column.
Data analysis
Data for NO and NO2 concentrations are given for each
individual set of measurements, in other words for each NO dose, for each
FiO2, for the setup without humidification system (nohum), and for
the setup including the inactive humidification system (inacthum) as well as
for the active humidification system (acthum) in place. NO measurements are
presented as percentages of the NO concentration set on the respirator.
NO2 concentrations are given as absolute values (ppm). To compare
the NO concentrations at the different positions and for the different setups,
data for all FiO2 values and NO concentrations from 1 to 100 ppm were
averaged and tested by means of the paired students t-test. Data in
figures are given as mean ± standard deviation.Schematic presentation of the experimental design used. At four
positions (Pos. 1 to Pos. 4) along the inspiratory limb of the respiratory
tubing, NO and NO2 concentrations were measured by means of
chemiluminescence (CLD 700 AL chemiluminometer). The upper part of the figure
demonstrates the measurement design without a humidification system. In the
lower part the site of the active humidification system is indicated between
Pos. 1 and Pos. 2.Individual NO measurements for the different NO concentrations set
(x-axis, NO) and the different FiO2 values as well as the different
circuit setups. The NO concentrations are expressed as a percentage of the set
NO concentration (y-axis). Each line of figures represents the different
settings for FiO2. Each column of figures represents the different
setups for the heating system.
Results
The individual measurements of NO concentrations at the four different
positions for the different FiO2 values and for the different setups
concerning the humidification system are shown in Figure 2. We found a sharp decline for all NO concentrations between
Pos. 1 and Pos. 2 that obviously was not influenced by the FiO2. For
the setup with an inactive or without humidification system, this finding was
strongly influenced by the high NO values at Pos. 1 for 0.1 ppm NO when
expressed as a percentage of the adjusted NO dose. Therefore, the values for
0.1 ppm NO were excluded from the statistical analysis of mean values, which is
shown in Figure 3. For all setups, a significantly lower
NO concentration was found at Pos. 2–4 when compared to Pos. 1. The differences
for the NO values between Pos. 1 and 2 as well as between Pos. 1 and 4 are
shown in Figure 4. Again, for this analysis all NO
measurements except for 0.1 ppm NO were averaged for the different
FiO2 settings. The difference between Pos. 1 and 2 was significantly
less pronounced when the inactive or no humidification system were used.
Figure 2
Individual NO measurements for the different NO concentrations set
(x-axis, NO) and the different FiO2 values as well as the different
circuit setups. The NO concentrations are expressed as a percentage of the set
NO concentration (y-axis). Each line of figures represents the different
settings for FiO2. Each column of figures represents the different
setups for the heating system.
Figure 3
Nitric oxide (NO) concentrations as a percentage of the adjusted
NO dose (y-axis) for the different setups of the heating system (x-axis). The
different bars reflect the different measurement positions (see Fig
1). Data are given as mean± standard deviation.
*P < 0.05, compared to pos.1 for a given setup;
§P < 0.05, compared to the active humidification
system (acthum) for a given position, inacthum, Inactive humidification system;
nohum, no humidification system.
Figure 4
Differences in nitric oxide (NO) concentrations between different
positions as a percentage of the adjusted NO dose (y-axis) for the different
setups of the heating system (x-axis). The different bars reflect the different
measurement positions (see Fig 1). Data are given as
mean ± standard deviation. *P < 0.05, compared to the
active humidification system (acthum). inacthum, inactive humidification
system; nohum, no humidification system.
The corresponding NO2 concentrations are shown in Figure
5, again as individual measurements for all
FiO2 values and for the different setups of the humidification
system.
Figure 5
Individual nitrix dioxide (NO2) measurements in parts
per million (ppm, y-axis) for the different nitric oxide (NO) concentrations
adjusted (x-axis, NO) and the different FiO2 values as well as the
different circuit setups. Each line of figures represents the different
settings for FiO2. Each column of figures represents the different
setups for the heating system.
Nitric oxide (NO) concentrations as a percentage of the adjusted
NO dose (y-axis) for the different setups of the heating system (x-axis). The
different bars reflect the different measurement positions (see Fig
1). Data are given as mean± standard deviation.
*P < 0.05, compared to pos.1 for a given setup;
§P < 0.05, compared to the active humidification
system (acthum) for a given position, inacthum, Inactive humidification system;
nohum, no humidification system.Differences in nitric oxide (NO) concentrations between different
positions as a percentage of the adjusted NO dose (y-axis) for the different
setups of the heating system (x-axis). The different bars reflect the different
measurement positions (see Fig 1). Data are given as
mean ± standard deviation. *P < 0.05, compared to the
active humidification system (acthum). inacthum, inactive humidification
system; nohum, no humidification system.Individual nitrix dioxide (NO2) measurements in parts
per million (ppm, y-axis) for the different nitric oxide (NO) concentrations
adjusted (x-axis, NO) and the different FiO2 values as well as the
different circuit setups. Each line of figures represents the different
settings for FiO2. Each column of figures represents the different
setups for the heating system.
Discussion
The most obvious conclusion from the data is that a significant
variation of the NO concentrations can be found along the inspiratory limb of
the breathing system even when a device to administer NO proportional to
inspiratory flow, such as the Servo 300 NO-A, is used. The highest NO
concentrations were found immediately behind the respirator outlet with a sharp
decline to fairly stable values in the more distal parts of the respiratory
tubing. Although this observation could be generally made for all NO
concentrations (0.1–100 ppm) and for all different heating system setups, the
magnitude of this decrease in NO along the inspiratory limb was dependent on
the presence of an active humidification system.This pattern of inspiratory NO concentrations might be explained in
two different ways. The rather high NO concentrations adjacent to the
inspiratory outlet might be attributed to incomplete gas mixing inside the
ventilator which could result in potentially higher measured NO values than
those set. Alternatively, the sharp decline between Pos. 1 and Pos. 2 might be
explained by a rapid reaction of NO in between both points of measurement so
that the actual amount of NO decreased. Our data suggest that both possible
mechanisms may play a role.The observation that NO decreases significantly between Pos. 1 and
Pos. 2 even when no humidification system is present between those points might
suggest that incomplete gas mixing inside the small internal volume of the
respirator is responsible for that decline. Since no further changes in NO
concentration along the inspiratory limb of the tubing could be observed distal
to Pos. 2, it can be concluded that the small distance between the respirators
outlet and the measurement at Pos. 2 is sufficient to achieve a complete gas
mixing. Fluctuations of NO concentrations have been shown for continuous flow
delivery of NO into the inspiratory circuit of a phasic-flow ventilator [15]. These fluctuations could have been minimized by using a
mixing chamber. A study by Mourgeon et al [17]
showed that sequential NO delivery during controlled ventilation with constant
flow resulted in more stable NO concentrations than continuous NO delivery.
However, when pressure support ventilation was used even sequential NO delivery
did not provide stable NO concentrations [17]. In
accordance with these findings, an explanation for the fluctuations between
Pos. 1 and Pos. 2 in our study might be that, during pressure-controlled
ventilation, a decelerating flow pattern results which cannot be exactly
followed by the mass flow controller of the NO delivery device. As a result, a
small asynchrony between ventilator flow and NO flow would explain the
non-homogeneous gas mixing at Pos. 1.However, the comparison between the different setups for the heating
system suggests that a form of reaction of NO takes place between Pos. 1 and
Pos. 2, resulting in a decreased amount of NO at Pos. 2 in the presence of
water. As shown in Figure 3, the NO concentrations at the
positions distal to Pos. 1 were significantly higher for the setups including
no or an inactive humidification system, when compared to the active
water-filled heating column. Since inclusion of the inactive heating column in
between Pos. 1 and Pos. 2 did not change NO at Pos. 2 compared to the setup
without the humidification system, it might be concluded that the additional
mixing volume of the heating column as such does not play an important role for
the NO concentration. In contrast, for the water-filled column, the difference
between NO concentrations at Pos. 1 and Pos. 2 is significantly higher (Fig
4), which might indicate that NO reacts in the aqueous
phase or at the gaseous-aqueous interface of the humidification system. Since
NO is a very reactive chemical compound, a variety of potential reactions could
be responsible for the observed decrease of NO in the active heating column
[9,10]. NO reacts with
O2 in sequence with the end products HNO2 and
HNO3 which dissolves into NO2- and
NO3 + H+. NO2 formation should be increased
according to the kinetics of this reaction with higher concentrations of NO and
O2 and a longer contact time between NO and O2 [14]
which results from the additional gas volume of the heating column. This
hypothesis is supported by the NO2 measurements that show higher
NO2 levels for a given NO and FiO2 when the inactive
humidification system is compared to the setup without a heating column.
However, since this type of reaction alone does not explain the differing
findings for the active and the inactive heating system, a second type of
reaction might take place preferentially at the gas–liquid interface or in the
aqueous phase of the water-filled column. This second reaction type might be a
further reaction of NO with NO2 which produces
N2O3 dissolving again into HNO2 in the
presence of H2O [10]. With this second
reaction, the further consumption of NO in the water-filled heating system
could be explained as easily as the relatively lower NO2 values at
Pos. 2 for the active system when compared to the inactive heating column (Fig
5) as NO2 will also be decreased by this
reaction. NO2 increases in the more distal parts of the inspiratory
tubing probably as a result of the well known oxidation of NO to
NO2. Studies measuring further compounds of the above mentioned
reactions for different ventilator settings should clarify their importance for
NO delivery.In recent studies, the importance of measuring with fast response time
chemiluminescence machines has been shown to assess the true breath-by-breath
variability of NO delivery systems [15,17,18]. In this study, we used a
chemiluminescence machine with a rather slow response time. Therefore, we did
not measure breath-by-breath fluctuations of the inspired NO or even
fluctuations within one breath but instead mean NO and
NO2concentrations for the different positions along the inspiratory
tubing. This is clearly a drawback of the measurement device we used as we
cannot rule out that faster fluctuations of NO might have occurred. However,
there was a clear pattern even for these slow NO fluctuations depending on the
presence of an active heating device.In summary, we conclude that significant variations of NO
concentrations occur along the inspiratory limb of the respiratory tubing
during inhalation of NO from 0.1 to 100 ppm using the Servo 300 NO-A for NO
delivery during pressure-controlled ventilation. The major part of these
fluctuations occurs in the first 30 cm of the tubing after the inspiratory
outlet of the respirator. These fluctuations are due to incomplete gas mixing
in the small internal volume of the respirator. Furthermore, the chemical
reaction and dissolving of NO in the aqueous phase of an active heating system
may play a major role in the sharp decrease in NO concentrations across the
humidification and heating system. Since these data have been obtained in a
laboratory study, further clinical studies are needed to clarify whether this
phenomenon is clinically important. However, the presented data emphasize that
the NO and NO2 concentrations should be measured as distally as
possible in the inspiratory limb of the system to get the best estimate of the
real inhaled concentration. Furthermore, one should be aware that the inclusion
of an active heating and humidification system into the respiratory tubing
alters the administered NO concentrations. Finally, it could be speculated
that, along the humid atmosphere of the more distal parts of the respiratory
system of the patient, further NO is consumed by chemical reaction leading to a
decrease in the efficient NO concentration at the site of action which is the
alveolo–capillary interface.
Authors: E Mourgeon; L Gallart; G S Rao; Q Lu; J D Law-Koune; L Puybasset; P Coriat; J J Rouby Journal: Intensive Care Med Date: 1997-08 Impact factor: 17.440
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