Introduction

The anaesthetic conserving device (ACD) AnaConDa® (Sedana Medical, Sundbyberg, Sweden) facilitates the administration of isoflurane or sevoflurane using conventional ventilators avoiding circle systems, vaporizers and soda lime. Its clinical use for anaesthesia has first been described by Enlund et al. [1], whereas Sackey et al. [2] reported its safe use for inhalational sedation in the intensive care unit (ICU). The device has been licensed in the European Union and Canada and is increasingly used for ICU sedation [35]. It is crucial to understand the principles of operation to become aware of pitfalls and achieve correct dosing of anaesthetics as the use of the ACD has little in common with the conventional vaporizer—circle system technique, the closed anaesthesia system or the dosing regimen of intravenous drugs. Therefore even for anaesthetists, the new method of application and its dependencies may be difficult to understand. When introducing the method into clinical practice, gas monitoring and some sort of gas scavenging must be available, and all staff involved must be properly trained. Some pitfalls and proper handling of the device have been described by our group [6].

A crucial ACD component is the anaesthetic reflector consisting of activated charcoal fibres. It conserves exhaled anaesthetic and re-supplies it during inspiration. This is similar to a heat moisture exchanger reflecting water vapour. However, in addition to reflecting, the ACD must also deliver anaesthetic. Therefore liquid anaesthetic is infused by a syringe pump into a porous rod called an evaporator. Evaporated anaesthetic in combination with reflected anaesthetic becomes the total inhaled anaesthetic.

It was the purpose of this bench study to determine the influence of both anaesthetic delivery and ventilatory settings on the concentrations of isoflurane and sevoflurane in a test lung. By comparing these with the corresponding concentrations on the ventilator side of the device we describe the technical performance of the reflector in a calculation model.

Methods And Materials

Experimental setup

A Puritan Bennett 840 ICU ventilator (Pleasanton, California, USA) was set up and checked according to the manufacturer’s instructions. In the performance verification test, the inaccuracy of volume measurement was determined to be below 10% for all calibration volumes (0.025, 0.2, 0.6 and 2.5 l). The ventilator compensates volume measurement for body temperature pressure saturated conditions as well as for the compliance of hoses that was determined to be 2.27 ml cm H2O−1 in the short self test. Leakage was negligible. An anaesthesia gas scavenging system with reservoir (AGS 33 300, Dräger Medical, Lübeck, Germany) was connected to the expiratory port of the ventilator to avoid contamination of the workplace.

Y-piece, ACD, a catheter mount with a bronchoscopy port and a 3 l chloroprene bag for manual ventilation from an anaesthesia machine (Dräger Medical) were assembled in line, the latter serving as a test lung (Figure 1). Through the bronchoscopy port a thin catheter was inserted into the test lung for side stream gas monitoring with the monitor Vamos® (Dräger Medical) at a sampling rate of 0.15 l min−1. The sample gas was returned to the patient side of the ACD through the port intended for gas sampling. All materials used were for single use and had never been in contact with volatile anaesthetics except the ventilator, the test lung and the gas monitor.

Fig. 1
figure 1

Experimental setup. (1) Anaesthesia gas scavenging, (2) ICU ventilator, (3) inspiratory hose, (4) expiratory hose, (5) Y-piece, (6) anaesthetic conserving device, (7) catheter mount (with bronchoscopy port), (8) test lung (3 l chloroprene bag), (9) thin catheter, (10) gas sampling tube, (11) gas monitor, (12) redelivery of sample gas, (13) serial communication cable, (14) notebook computer for online data sampling, (15) syringe pump (16) syringe filled with liquid isoflurane or sevoflurane. MV expiratory minute ventilation, carrying anaesthetic vapour through the anaesthetic reflector. Closs mean anaesthetic concentration in the gas expired through the anaesthetic reflector. Cpat mean anaesthetic concentration inside the 3 l bag under steady state conditions.

Liquid isoflurane or sevoflurane (Abbott Laboratories, Illinois, USA) were filled into a special syringe from the bottle using the appropriate adapter (Sedana Medical) in a separate room to avoid air pollution. The syringe (Sedana Medical), made of special material inert to the agents used, was fitted into a syringe pump before connecting it to the infusion line of the ACD. The syringe pump (Ivac®, Cardinal Health—Alaris Products, Dublin, Ohio, USA) adjusted for Becton Dickinson Plastipak syringes with a high cut off pressure (120 kPa) was installed on a constant level below the ACD to avoid gravity effects as described by Berton et al. [7] and our group [6].

Respiratory rates (RR), tidal volumes (VT) and infusion pump rates (IR) were varied. RR were 5, 10, 20, and 40 breaths min−1, VT 0.3, 0.5, and 1.0 l, and IR were 3.33, 8.33, 16.6, 33.3, 83.3, 166.6, and 833.3 × 10−6 l min−1 (0.2, 0.5, 1.0, 2.0, 5.0, 10.0, and 50.0 ml h−1). For experiments with VT of 0.3 and 1.0 l, only a RR of 10 breaths min−1 was used. We used constant inspiratory flow at 33% of total cycle time, no inspiratory hold, an oxygen concentration of 21 vol% and a positive end expiratory pressure of 3 cm H2O to keep the test lung inflated.

Calculation of Closs

In our bench model we calculated the mean anaesthetic concentration on the ventilator side of the reflector (Closs). Under steady state conditions, confirmed by the stability of the concentration in the test lung, all anaesthetic delivered into the system per unit of time (V′delivered) must escape the system. The anaesthetic vapour cannot diffuse through the test lung because chloroprene is impermeable to volatile anaesthetics. Air leaks have been excluded during the setup of the method. Therefore the only way for anaesthetic vapour to escape the system is through the anaesthetic reflector that will reflect most, but not all anaesthetic molecules. Anaesthetic molecules reaching the ventilator side of the reflector will be flushed away, diluted in the unsteady flow of the expired minute volume. Closs can thus be calculated as follows:

$$ C_{loss} = \frac{{V_{delivered}^\prime }}{{MV}} \times 100 = \frac{{IR \times F}}{{RR \times V_T }} \times 100 \left( {vol\% } \right) $$
(1)

MV is the expired minute ventilation. F is the factor for calculating anaesthetic vapour from liquid anaesthetic: Using the ideal gas law, Avogadro’s law and the physical density of liquid isoflurane/sevoflurane, F can be calculated as 219.1 and 207.6 ml vapour per ml liquid anaesthetic under body temperature pressure saturated conditions for isoflurane and sevoflurane, respectively.

Measurement of Cpat

The mean anaesthetic concentration in the middle of the test lung in steady state was called “patient concentration” (Cpat). For all combinations of RR, VT and IR, both for isoflurane and for sevoflurane, experiments were performed twice: We expected Cpat to be related to Closs. Therefore the experiments were arranged in such an order that Closs, calculated in advance, was first increasing, and then decreasing. This was done to reach the steady state earlier and to avoid a possible carry over effect by the volatile anaesthetic dissolving in and being released from the materials used. The measurements of Cpat from the inand decreasing series were finally averaged.

Gas measurements displayed to the second decimal place were stored online on a notebook computer once every second with the data sampling program Visia® provided by the gas monitor’s manufacturer. For each experiment, data were sampled over a period of at least 30 min. The stability of the measured Cpat was confirmed visually by looking at a trend diagram. Only if a stable plateau was reached and maintained for at least 10 min, data from this plateau were averaged. The gas monitor Vamos® calibrates itself automatically every 2 h. We used two gas monitors of the same model and frequent exchanges did never result in different readings.

To describe the technical performance of the reflector, the ratio of Closs to Cpat was calculated (R C = C loss/C pat). Data are presented as mean (SD). For comparison of R C for isoflurane and sevoflurane Student’s t test for paired samples was used.

Results

Table 1 presents the measured values of Cpat and the ratio of the concentrations on both sides of the reflector (R C = C loss/C pat) at the different IR and ventilatory settings. Six settings yielding Cpat outside the measurement range of the gas monitor (4<0.1 vol%, 2>11 vol%) had to be discarded in the isoflurane and sevoflurane series (Table 1).

Table 1 Patient concentrations (Cpat) and concentration ratios (Closs/Cpat) and their dependence on the studied variables

In Figure 2a and b the calculated Closs is plotted against the measured Cpat for isoflurane and sevoflurane, respectively. At lower concentrations (Cpat ≤ 1 vol%) there is a linear relationship between Closs and Cpat independent of the ventilatory settings. At higher concentrations all curves bend upwards. In the isoflurane (sevoflurane) diagram the curve for the large VT of 1.0 l starts bending upwards between 0.77 and 1.42 vol% (0.69–1.31 vol%), the curve for the small VT of 0.3 l bends upwards between 2.30 and 4.44 vol% (2.17–4.06 vol%). The four curves with the middle VT of 0.5 l, but with differing RR, all bend upwards around 2 vol%. Thus the RR shows little influence on the progression of the curves. Exponential regression lines do not give good fits because in the lower concentration range all curves seem exactly linear.

Fig. 2
figure 2

(a) and (b) Characteristic curves of AnaConDa® for isoflurane (a) and sevoflurane (b) with different ventilatory settings. The mean anaesthetic concentrations on the ventilator side of the anaesthetic reflector (Closs, [vol%]) plotted against the mean anaesthetic concentrations in the test lung (Cpat, [vol%]). RR respiratory rates, VT tidal volumes. Each curve describes a different ventilatory setting, each point a different infusion pump rate. The straight line delineates a concentration ratio Closs/Cpat of 0.097 (isoflurane) and 0.096 (sevoflurane) respectively.

RC describes the slopes of the first linear parts of all curves. For these parts, until RC increases by more than 20% of the previous value (bold values Table 1), all values of RC were averaged to yield 0.097 (0.014) for isoflurane and 0.096 (0.012) for sevoflurane. The small difference between the two is neither statistically nor clinically significant. Therefore the total average was calculated as 0.096 (0.012), or as a reciprocal value: one to 10.4.

Discussion

It is the main finding of our study that the ratio of the anaesthetic concentrations on both sides of the anaesthetic reflector is constant with a value of 0.096 (0.012):

$${R_C} = {{{C_{loss}}} \over {{C_{pat}}}} = 0.096 ({\rm{dimensionless}})$$

This technical performance is verifiable with different ventilatory settings, both for isoflurane and sevoflurane, and over the clinically used concentration range. In detail, constant concentrations measured for Cpat were 10.4 times higher than Closs.

If we imagine that the anaesthetic reflector would not work at all, Cpat would equal Closs and the data points in Figure 2a and b would lie on the bisecting line. In a similar bench experiment, Berton et al. [7] removed the reflector from the device and the concentrations measured on the patient side (0.1–0.4 vol%) were very close to our calculation for Closs (Equation 1).

Another important finding of our study is that, when the volume of anaesthetic vapour expired in one breath exceeds 10 ml (Cpat × VT; e.g. 1 vol% × 1.0 l, 2 vol% × 0.5 l or 3.33 vol% × 0.3 l), Closs increases disproportionately. This may be interpreted as a “spill over”: If during expiration the maximal capacity of the reflector is reached, no more anaesthetic molecules can be bound and they will be carried through the reflector and be lost for the patient. This “spill over effect” depends on the number of molecules contained in the expired VT.

When using the ACD in clinical practice, one of the first questions arising is how to dose the anaesthetic to yield the desired “patient concentration” (Cpat). By combining Equations 1 and 2, Cpat can easily be calculated as:

$${C_{pat}} = {{{C_{loss}}} \over {{R_C}}} = {{IR} \over {RR \times {V_T}}} \times {F \over {{R_C}}} \times 100 ({\rm{vol}}\% )$$

For ICU sedation, usually 0.3–0.6 vol% isoflurane or 0.5–1.0 vol% sevoflurane are targeted. In this concentration range, RC will be constant. Therefore, in our bench model, Cpat will be proportional to the infusion rate and inversely proportional to the minute volume. RR and VT have an equal influence.

In their bench study, Berton et al. [7] examined iso-flurane (F = 219.1 ml vapour per ml liquid anaesthetic) at an IR of 5 ml h−1, a rate commonly used in clinical practice. But because of the lack of patient uptake, this resulted in unusually high “patient concentrations” provoking spill over. According to Equation 3, an IR of 5 ml h−1 (83.3 × 10−6 l min−1), a RR of 12 breaths min−1, and a VT of 0.3 l yields 5.2 vol%. This means that one expired breath would contain 15.7 ml anaesthetic vapour, which exceeds the capacity of the reflector. But the authors measured a concentration of only 3.4 vol% which corresponds to 10.2 ml isoflurane vapour contained in one breath. When measuring in the range where spill over occurs, the reflector seems to behave irregularly and the authors were not able to construct a simple model for calculation of Cpat such as the one presented here.

How can the ACD be compared to the classical circle system (CS)? During anaesthesia, anaesthetic vapour has to be delivered continuously to compensate firstly for patient uptake, secondly for leaks of breathing gas, e.g. during tracheal suctioning or disconnections from the ventilator, and thirdly for losses that occur during the normal operating of the system. Let us assume there are no patient uptake and no leaks as in our bench test and look only at anaesthetic losses inherent to the respective systems (V′loss):

In the CS, a specified fresh gas flow (FGF) enters the system on one side (Figure 3, left). In the absence of patient uptake and leaks, the outflow from the CS equals the FGF and the anaesthetic concentrations in fresh gas, inspired and expired air will all be the same after wash in (CCS). Losses of anaesthetic vapour can be described as (CCS should be inserted as a dimensionless fraction):

$$ V_{loss,CS}^\prime = FGF \times C_{CS} (1 min^{ - 1} ) $$
(4)
Fig. 3
figure 3

Comparison of the circle system (CS) with the Anaesthetic Conserving Device (ACD). A classical anaesthesia machine consists of the fresh gas supply with the interposed vaporizer, the CS with soda lime, and a ventilator usually in form of a bag in bottle system. In the absence of patient uptake and leaks, the outflow from the CS equals the FGF and the anaesthetic concentrations in fresh gas, inspired and expired air will all be the same after wash in (CCS). Losses of anaesthetic vapour can be described as the product FGF times CCS. With the ACD, the anaesthetic is delivered as a liquid via a syringe pump. Closs, the mean concentration on the ventilator side of the device, is 10.4 times lower than Cpat. Vapour losses can be calculated as the product minute ventilation (MV) times Closs. Vapour losses can also be imagined to be carried away by a clearance flow flushing the patient side of the ACD (semicircular arrow). The clearance is a fraction (Closs/Cpat = 0.097) of the minute volume. Vapour losses can be calculated as the product clearance times Cpat.

With the ACD anaesthetic losses can be described by the product MV times Closs (Figure 3, right). In the lower concentration range we can replace Closs by inserting Equation 2 (Cpat should be inserted as a dimensionless fraction):

EquationSource% MathType!MTEF!2!1!+- % feaafiart1ev1aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn % hiov2DGi1BTfMBaeXatLxBI9gBaerbd9wDYLwzYbItLDharqqr1ngB % PrgifHhDYfgasaacH8srps0lbbf9q8WrFfeuY-Hhbbf9v8qqaqFr0x % c9pk0xbba9q8WqFfea0-yr0RYxir-Jbba9q8aq0-yq-He9q8qqQ8fr % Fve9Fve9Ff0dmeaabaqaciGacaGaaeqabaWaaeaaeaaakeaacaWGwb % Waa0baaSqaaiaadYgacaWGVbGaam4CaiaadohacaGGSaGaamyqaiaa % doeacaWGebaabaWexLMBbXgBd9gzLbvyNv2CaeHbbjxAHXgiv5wAJ9 % gzLbsttbacfaGaa8NmGaaaieaakiaa+bcacaGF9aGaa4hiaGqaciaa % 91eacaqFwbGaa0hiaiaa-DnacaWFGaGaa0NuamaaBaaaleaacaqFdb % aabeaakiaa+bcacaWFxdGaa4hiaiaa9neadaWgaaWcbaGaa0hCaiaa % 9fgacaqF0baabeaakiaa+bcadaqadaqaaiaa+fdacaGFTbGaa4xAai % aa+5gadaahaaWcbeqaaiaa+1cacaGFXaaaaaGccaGLOaGaayzkaaaa % aa!6174! <Equation ID="E1"><EquationNumber>1</EquationNumber><EquationSource Format="MATHTYPE"><![CDATA[ V_{loss,ACD}^\prime = MV \times R_C \times C_{pat} \left( {1min^{ - 1} } \right) $$
(5)

The product MV times RC corresponds to the FGF of a CS and both may be called clearance (Cl):

$$C{l_{ACD}} = {R_C} \times MV = {{{C_{loss}}} \over {{C_{pat}}}} \times MV (1{\min ^{ - 1}})$$

This clearance of anaesthetic vapour through the reflector is in many respects analogous to the clearance of creatinine by the kidneys, which can be calculated as the ratio of the creatinine concentration in urine and plasma times the flow of urine. In the case of creatinine, the clearance corresponds to the glomerular filtration rate or the flow of primary urine. For most solutes, the clearance by the kidney does not correspond to any real flow, but can be imagined as the flow of an imaginary medium carrying the solute out of the body.

Whereas a good renal function is witnessed by a high clearance of solutes, a well performing ACD will be characterized by a low clearance of the anaesthetic vapour. Also in the case of the ACD the clearance may be imagined as a flow: If the ACD is performing well, Closs will be much lower than Cpat and the clearance will be a fraction (RC) of the minute ventilation. This fraction of the minute ventilation can be imagined to flush the system and carry the anaesthetic vapour away, comparable to the FGF flushing the CS.

There still remains one important difference between CS and ACD: Increasing the FGF will increase V′loss. But at the same time the vaporizer will deliver a larger volume of vapour per unit of time, leaving the concentrations unchanged. With the ACD, when the MV, and thus the clearance flow, is increased, the syringe pump will not deliver any more anaesthetic automatically and therefore the IR has to be adjusted manually.

We chose to calculate Closs instead of measure it, as we expected Closs to be ten times smaller than Cpat and therefore out of the measurement range of our gas monitor in half of the experiments performed. Unlike Cpat, Closs is not a stable concentration, but is fluctuating, and it would have been necessary to average Closs over the expiratory flow. Measuring the expiratory flow and combining the two measurements would have increased the total error. On the other hand our calculation is straight forward. Even if the assumption that all materials on the patient side of the reflector (catheter mount, chassis of the AnaConDa®) are gastight and that all anaesthetic delivered must be lost through the anaesthetic reflector, may not be absolutely right, these materials are used in clinical practice, and if anaesthetic agent is lost via these routes our calculations focussing on anaesthetic losses inherent to the ACD are valid.

We employed equipment commonly used in clinical practice. According to the manufacturer’s specifications the accuracy of the gas monitor is ±10%. Measuring constant concentrations without tidal fluctuations and in the absence of water vapour should improve the accuracy. Two gas monitors were used and frequent exchanges did never result in different readings. In the calculation of Closs, delivery of VT by the ventilator may be afflicted with a maximum error of ±10% as well, whereas RR and IR may be considered exact. For calculation of RC, with maximum errors of ±10% in enumerator and denominator, total error can be estimated to be ±20% at the most. But even if determination of RC may not be highly accurate, it is important to denote that RC is constant in the lower concentration range and dramatically increasing once the capacity of the reflector is exceeded.

It was the aim of our study to describe the functioning of the anaesthetic reflector as the more interesting and more innovative component of the new device. For several reasons we did not have a patient or experimental animal to take up the anaesthetic. For the calculation of Closs it was necessary to look at steady state conditions without anaesthetic uptake as pointed out above. Our bench model allowed us to measure Cpat as a stable concentration in the middle of the test lung. To avoid confusion we deliberately called that concentration ‘patient concentration’ and avoided the term ‘endtidal’. In a patient study or in an animal model one would have to consider alveolar, dead space, and mixed portions of the expired tidal volume each with differing anaesthetic concentrations. Last not least our bench model allowed us to reduce the number of possible influencing and disturbing factors and to concentrate on IR, RR and VT with constant flows. We were also able to apply extreme conditions to get to the limits of the device, which would not have been so easily possible in a patient or in an animal model. Other factors that might influence the performance of the reflector are temperature, humidity and carbon dioxide. It is up to further studies to rule out or quantify their respective influence.

A number of clinical studies compared anaesthetic consumption with the ACD in a high flow system to conventional anaesthesia systems with specified FGFs. Enlund, Wiklund and Lambert observed a 40% decrease in isoflurane consumption compared to a high flow coaxial Bain system [1]. The same group found the consumption of sevoflurane with the ACD to be similar to the one in a circle system with a FGF of 1.5 l min−1 [8]. Tempia and colleagues came to the same conclusion: they found consumption of sevoflurane with the ACD in a half open breathing circuit to be 6.2 ml h−1. In the comparison groups using circle systems with FGFs of 1.0, 1.5, 3.0, and 6.0 l min−1, the consumption was 5.2, 6.2, 13 and 24 ml h−1, respectively [9]. Assuming a MV of 5–10 l min−1, the above defined clearance would be 0.5–1.0 l min−1. Therefore in theory the ACD should perform slightly better than it turned out in practice. Possible explanations to this fact might be the inclusion of the priming volume contained in infusion line and evaporator, which amounts to 1.3 ml liquid anaesthetic, or possible spill over of volatile anaesthetic, when higher concentrations for anaesthesia are used.

Sackey et al. [10] reported an average consumption of only 2.1 ml h−1 isoflurane to maintain Cpat at 0.5 vol% during long term ICU sedation. According to the authors, this was 4 times less compared to conventional high flow vaporizer systems. Assuming a minute ventilation of 10 l min−1, the clearance would be 1 l min−1 and V′loss can be calculated as 1.4 ml liquid anaesthetic per hour (according to Equation 5 and after conversion to the appropriate units). The sample gas lost for gas monitoring accounts for another 0.2 ml h−1. So only 0.5 ml h−1 would be taken up by the patient, evaporate through the skin or escape through leaks, e.g. during tracheal suctioning.

Recently two studies evaluated the performance of pharmacokinetic models in patients in the operating theatre [11] and in the ICU [12]. This latter study evaluated the predictive performance of a simple pharmacokinetic model for the manually adjusted infusion of sevoflurane for use with the AnaConDa®. The model calculated patient uptake based on a nine compartment model as well as losses through the ACD based on an equation that gives very close results and shows a high correlation with Equation 5. The study showed an excellent predictive performance of the model in 50 patients for duration of up to 6 h.

We did not detect any differences between the two volatile anaesthetics examined, neither concerning RC (corresponding to the slopes of the first linear parts of the curves in Figure 2a, b), nor the range of high reflection performance (up to the points, when the curves start bending upwards). This is surprising considering the different physical characteristics of the two agents. As sevoflurane is less potent, higher concentrations are needed and thus spill over is more likely to occur. Our bench study is descriptive in nature and minor differences between the two volatile anaesthetics in the interaction with the ACD cannot be ruled out. To our knowledge, there is no published study examining differences in the two agents to be used with the AnaConDa®.

Drug dosing not only according to body weight or body surface area but according to the MV is unusual for clinicians. When increasing the FGF, vaporizers will automatically deliver a larger volume of anaesthetic vapour as pointed out before. Only with low FGFs, when patient uptake has a major influence on the resulting concentrations, changes in FGF have to be met by changing the dial of the vaporizer [13]. Using the ACD however, the IR has to be adjusted, when the MV changes. But intensive care physicians are not used to changing the infusion rate of a drug when changing the settings of a ventilator. In addition, the MV may not only be changed by the doctor, but also by the patient when breathing spontaneously. An increase in MV will lower the concentration of the drug, which in turn might increase respiratory drive. As a consequence, upper and lower alarm limits for the MV should be set and the IR adjusted accordingly.

With higher concentrations the reflection capacity may be reached, especially when large tidal volumes are used. The “spill over” of anaesthetic molecules may indeed offer some protection against an inadvertent overdose: In clinical practice, it may happen that the IR of sevoflurane (isoflurane) erroneously is set at 50 instead of 5 ml h−1. With ventilatory settings of 10 × 1.0 l min−1, and according to our bench model (Equation 3), Cpat instead of the intended 1.7 vol% (1.8 vol%) would increase to 17 vol% (18 vol%), if no spill over would occur and RC was constant over the whole concentration range. But in fact, Cpat will only approach 3.9 vol% (3.6 vol%, see Figure 2a, b; Table 1). If the same MV was applied with the settings 20 × 0.5 l min−1, again not 17 but 5.6 vol% (5.1 vol%) will be reached. But if small VT are used, the spill over effect offers no protection and Cpat will be above 11 vol% (upper limit of the measurement range of the gas monitor, see Table 1).

Therefore, a high performance of the reflector is not the only important thing. One could speculate about decreasing its capacity and by this narrow its range of high performance. If Cpat increased, the clearance would increase earlier and more anaesthetic vapour would escape the system. This would further decrease the risk of over dosage, also when small tidal volumes are used. By reducing dead space, which in AnaConDa® is 100 ml, this as well would make the ACD more suitable for children [14].

Conclusions

In this bench study, in the steady state, and at lower concentrations (≤1 vol%), the ratio of the concentrations on both sides of the anaesthetic reflector is constant at 0.096. This is true for isoflurane and sevoflurane and for different ventilatory settings. In other words, the anaesthetic concentration on the patient side is about ten times higher than the concentration on the ventilator side. Both concentrations are proportional to the infusion rate and inversely proportional to the respiratory rate and the tidal volume. Therefore in clinical practice, when the minute ventilation is increased (lowered), the infusion rate should also be increased (lowered) to keep the patient concentration constant.

If the volume of vapour expired within one breath exceeds 10 ml (Cpat × VT = 0.01 l; e.g. 1 vol% × 1.0 l, 2 vol% × 0.5 l, or 3.3 vol% × 0.3 l), the performance of the reflector decreases, as molecules exceeding the capacity of the reflector will be flushed away. This “spill over” effect may offer some protection against an inadvertent overdose.

In the lower concentration range, the clearance of anaesthetic vapour can be calculated as the ratio of the concentrations on both sides of the reflector (RC) times the minute volume. This clearance corresponds to a fresh gas flow in a circle system between 0.5 and 1.5 l min−1. This has already been shown in clinical studies.