A randomized prospective study of BIS guided low-flow sevoflurane anesthesia; is air safer than nitrous oxide?


Gozde Inan, MD1, Hulya Celebi, MD2
1Consultant; 2Professor of Anesthesiology & Reanimation

Department of Anesthesiology and Reanimation, Faculty of Medicine, Gazi University, 06500-Besevler, Ankara, (Turkey)

Correspondence:  Gozde Inan, MD, Gazi University Faculty of Medicine, Department of Anesthesiology and Reanimation, 06500-Besevler, Ankara, (Turkey); Phone: +90 312 202 53 10 \ +90 535 810 56 20; Fax: (+90 312) 202 41 66; E-mail: inangozde@yahoo.com

ABSTRACT
Objective: This prospective randomized BIS controlled study was conducted to compare low-flow anesthesia (LFA) techniques with or without nitrous oxide (N2O) using remifentanil and sevoflurane, with respect to ventilation parameters and sevoflurane consumption.

Methodology: Forty-five, ASA I/II women younger than 65-year-old, scheduled for gynecological surgery lasting nearly two hour under general anesthesia were enrolled. Electrocardiogram (ECG), pulse oximetry, non-invasive arterial pressure, train-of-four (TOF) and bispectral index (BIS) were monitored. Anesthesia was induced by inj propofol 2 mg/kg with increments of 10 mg until BIS was under 60 and rocuronium 0.6 mg/kg. Patients were randomized to one of three groups, 15 patients in each, to receive either N2O (Group N) or N2O-free anesthesia (Groups R I and R II). All groups received bolus remifentanil 0.5 µg/kg and then infusions @ 0.2 µg/kg/min (Group R I), or 0.05 µg/kg/min (Group R II) as maintenance. Anesthesia was maintained with sevoflurane in O2 + N2O or air. Signs indicating adequate depth of anesthesia during maintenance phase of anesthesia were HR, arterial blood pressure and BIS. The goal was to obtain a BIS value between 40 and 60 and hemodynamic parameters within 20% of baseline values. Opioid infusions were constant as sevoflurane vaporizer dial setting was adjusted in ± 0.5% volumes to maintain this goal. Systolic, diastolic and mean arterial pressures, HR, SpO2, the inspired and expired gas partial pressure measurements of O2, sevoflurane, N2O, and CO2, BIS values sevoflurane vaporizer dial settings, and recovery times were recorded. Measuring points were at every 5 min during surgery. A minimum inspired oxygen concentration (FiO2) of 0.3 was maintained. Consumption and costs for sevoflurane were calculated.

Results: Demographic data, duration of surgery and anesthesia were similar between the groups. A significant decrease was observed in FiO2 by time in all groups. For all recording times FiO2 was statistically greater in Group N. The difference between delivered O2 and FiO2 was the lowest in Group N. The difference between inspired and expired fractions of sevoflurane (Fisevo and Fetsevo) reduced by time during the low flow period. It was lower in Group N than in remifentanil groups. Total sevoflurane consumption was significantly greater in Group R II than Group N but there was no significant difference in sevoflurane consumption and costs per patient per minute between groups. Recovery times were comparable between the groups.

Conclusions: We concluded that risk of hypoxia and volatile anesthetic consumption did not differ with or without N2O in remifentanil-sevoflurane, low flow anesthesia. Monitoring FiO2 is essential in both air/O2 and N2O/O2 mixtures. Both are safe to administer unless FiO2 is lower than 30%. BIS-guided sevoflurane with its low solubility feature successfully adapts quickly to variable anesthetic depth levels during low-flow anesthesia.

Key words: Anesthesia; Closed Circuit, Anesthesia; Rebreathing; Nitrous oxide; Consciousness Monitors; Bispectral Index Monitor

Citation: Inan G, Celebi H. A randomized prospective study of BIS guided low-flow sevoflurane anesthesia; is air safer than nitrous oxide? Anaesth Pain & Intensive Care 2016;20(3):266-272

Received: 31 January 2016; Reviewed: 27 March 2016; Corrected: August 2016; Accepted; 9 September 2016

INTRODUCTION
There is a debate on N2O usage whether it is a unique or an outdated drug;1,2 and compelling arguments have been presented to question its continued use as a carrier gas in anesthesia.3-6 When N2O is not present in anesthesia, an air/O2 mixture is frequently used as the prolonged use of 100% O2 has its own disadvantages.7
Other than general concerns about N2O in standard anesthesiology practice, when it comes to the low flow anesthesia (LFA) technique, questioning its ongoing usage gains importance.8 Low-flow techniques using O2/N2O mixtures have been well studied9 than the use of air/O2 mixtures. Should we then assume air is safer in LFA? Nitrous oxide has favorable features and possible advantages as an amnesic in the prevention of intraoperative awareness.3 European Society of Anaesthesiology task force recently concluded that when not specifically contraindicated N2O could be used.10 Hendrickx et al revised pharmacokinetic and pharmacodynamic concepts of inhaled anesthetics including nitrous oxide and suggested that the second gas affect of N2O may be more pronounced than assumed.11
This study hypothesized that omitting N2O from carrier gas compositions would help to utilize LFA technique and would be useful as an academic demonstration of inhalational anesthetic pharmacokinetics and pharmacodynamics, yet its impact on cost-effectiveness was unknown. Primary outcomes were the changes of delivered, inspired and expired gas partial pressure measurements of O2, sevoflurane, N2O, and CO2 during LFA with and without N2O. Additional outcomes included the comparison of the effects of different remifentanil doses with nitrous oxide on recovery times as well as volatile anesthetic consumption and cost under BIS monitoring.

METHODOLOGY
This prospective, randomized study was conducted on 45, ASA I/II women under 65 years old, who were scheduled for gynecological surgery of approximately two hours duration under general anesthesia. Institutional Ethics Committee approval and written informed consent from each subject were obtained. The exclusion criteria were a previous unusual response to anesthetics, emergency surgery, a history of hepatic, renal or significant cardiovascular disease, history of alcohol or drug abuse, and procedures with an expected duration of less than 30 min.

No premedication was given. Anesthesia was administered and anesthetic gases monitored with Julian™ (Dräger Medizintechnik, Lübeck, Germany) anesthesia machine. Before each anesthetic administration, fresh soda lime with new respiratory tubing and connections were used.

Routine monitoring included electrocardiogram (ECG), pulse oximetry (SpO2), non-invasive mean arterial pressure (MAP). Additionally, bispectral index (BIS) monitoring (BIS XP Platform, Aspect Medical Systems Inc., Newton, USA) was used. The bispectral values were monitored continuously from before the induction until the patient fully recovered after surgery. Neuromuscular transmission was monitored by train-of-four nerve stimulation (TOF, Innervator NS 252, Fisher & Paykel Electronics Ltd., Auckland, New Zealand).

In all patients, following 5 min of preoxygenation with 100% oxygen, anesthesia was induced by propofol 2.0 mg/kg IV with increments of 10 mg until the BIS was under 60. A neuromuscular block was administered with inj rocuronium 0.6 mg/kg. Patients were randomly placed into one of three groups containing 15 patients each, by means of a computer-generated table of random numbers designating a N2O group (Group N), or two N2O-free groups (Groups R I and R II). All of the groups received remifentanil 0.5 µg/kg as a loading dose.  Continuous infusions were maintained @ 0.2 µg/kg/min (Group R I) or @ 0.05 µg/kg/min (Group R II) in remifentanil groups. Anesthesia was maintained with sevoflurane/oxygen/N2O in Group N and with sevoflurane/oxygen/air in Groups R I and R II. Fresh gas flows were supplied with 6.0 L/min during the first five minutes, than adjusted to 1.0 L/min with a sevoflurane vaporizer setting of 2% and 2.5% respectively. Opioid infusions were constant as the sevoflurane vaporizer dial setting was adjusted in ± 0.5% volumes to maintain BIS 50 ± 10. Incremental doses of 0.01 mg/kg rocuronium were given at two twitches achieved with a train-of-four stimulus. End-tidal carbon dioxide, tidal volume and respiratory rate were adjusted to 30-35 mmHg, 8 ml/kg and 8-12/min respectively.

Systolic, diastolic and MAPs, heart rate (HR), SpO2, the inspired and expired gas partial pressure measurements of oxygen, sevoflurane, N2O, and CO2, BIS values were recorded before induction, and at 5-minute intervals thereafter throughout the study. Delivered gas concentrations (oxygen, sevoflurane) were defined as the gas concentrations set at the anesthesia machine and vaporizer and inspired fractions (Fi) and expired fractions (Fe) of oxygen, sevoflurane, N2O, and CO2 were measured from the breathing system.

In case of a decrease in inspired O2 concentration (FiO2 < 0.3) or in peripheral oxygen saturation (SpO2 < 94), it was planned that an increase in O2 flow by 10% of the total flow and a decrease of N2O/air by the same rate would be carried out. Hemodynamic stability was maintained by adjusting the inspired anesthetic concentration. If the MAP increased by > 20% of the baseline value, the anesthetic gas vaporizer volume was increased by 0.5%. When HR and MAP were < 20% of the baseline, the anesthetic gas concentration was decreased by 0.5%. If this did not prove effective to treat hypotension, 5-10 mg ephedrine was given IV.

Before completion of the last skin sutures, the vaporizer was turned off, fresh gas flow was increased to 4 L/min, and ventilation was performed manually with 100% O2. Residual muscle paralysis was reversed with neostigmine administration. The durations of anesthesia and surgery were noted. The response times by ‘eyes opening’ on command, and being well-oriented in time and place, were recorded. Extubation was done when they successfully responded to the command to open their eyes. The time between cessation of the inhalation anesthesia and extubation was noted. A postanesthetic recovery score was evaluated at 10th and 30th minutes after extubation according to the Aldrete Recovery Scoring System in the postanesthesia care unit. Patients who had a score over nine were transported to the ward. Consumption and costs for sevoflurane were calculated by use of the Dion Formula.12
The statistical analysis was performed with SPSS 15.0 software for Windows (IBM, USA). All data are expressed as mean ± standard deviation (Mean ± SD). P values <0.05 were considered statistically significant. One-way analysis of variance or the Kruskal-Wallis tests were used for between-group comparisons. Analysis of variance was used for repeated measures of intergroup comparisons.

RESULTS
The study included 45 women of ASA I-II physical status, between the ages of 41-65 years. Demographic variables were similar between the groups (Table 1). The mean anesthesia duration was 95.27 min for Group N, 100.27 min for Group R I, and 104.07 min for Group R II (p > 0.05).

Table 1: Patient demographics, duration of anesthesia and operation, and recovery features (n, mean ± SD)
Variables Group N Group R I Group R II
ASA (I/II) 11/4 7/8 7/8
Age (yrs) 50.07 ± 6.58 48.53 ± 4.82 49.53 ± 6.52
Height (cm) 160 ± 6 160 ± 4 160 ± 6
Weight (kg) 69.87 ± 13.01 74.60 ± 14.16 78.60 ± 14.06
Duration of surgery (min) 85.73 ± 17.27 90.53 ± 22.57 97.27 ± 22.66
Duration of anesthesia (min) 95.27 ± 17.79 100.27 ± 23.84 104.07 ± 22.25
Eye opening time (min) 3.8 ± 1.47 5.2 ± 2.48 4.07 ± 2.09
Extubation time (min) 5.33 ± 1.92 6.07 ± 2.52 5.93 ± 2.12
There was a significant decrease in HR and MAP after induction in all groups. Remifentanil groups revealed no hemodynamic response to intubation, whereas in Group N, there was a significant increase in MAP. During the low flow period, HRs were significantly lower than baseline values in all groups and MAPs also decreased in remifentanil groups without statistical differences between groups.

The difference between delivered O2 and FiO2 was the lowest in Group N compared with the remifentanil groups (Table 2). A significant decrease was observed in FiO2 by time in all groups. For all recording times, FiO2 was statistically greater in Group N (p < 0.05). The lowest FiO2 % monitored in each group was 38% for Group N, 32.73% for Group R I, and 34.47% for Group R II (Table 3).

Table 2: Disparity between the oxygen concentrations set at the anesthesia machine (delivered oxygen) and in the breathing system (inspired oxygen concentration - FiO2) (mean ± SD)
Time Group N Group R I Group R II
4 L 3 ± 2.04*† 8.2 ± 3.1 6.8 ± 3.71
1 L 5min 4 ± 1.96*† 11.93 ± 2.05 10.93 ± 2.49
1 L 15min 7 ± 1.31#*† 15 ± 2.48# 14.93 ± 2.37#
1 L 30min 10 ± 1.13#*† 16.4 ± 2.61# 15.53 ± 3.14#
1 L 45min 11.47 ± 1.13#*† 16.87 ± 2.67# 15.27 ± 3.37#
1 L 60min 12 ± 1.77#*† 17.27 ± 3.77# 15.2 ± 3.28#
*p<0.05 (compared with Group R I),

†p<0.05 (compared with Group R II),

#p<0.05 (compared with 1 L 5 min)

Table 3: Changes in FiO2 by time (mean ± SD)
>

Time Group N Group R I Group R II
4 L 47 ± 2.04*† 41.8 ± 3.1 43.2 ± 3.71
1 L 5min 46 ± 1.96*† 38.07 ± 2.05 39.07 ± 2.49
1 L 15min 43 ± 1.31#*† 35 ± 2.48# 35.07 ± 2.37#
1 L 30min 40 ± 1.13#*† 33.6 ± 2.61# 34.47 ± 3.14#
1 L 45min 38.53 ± 1.13#*† 33.13 ± 2.67# 34.73 ± 3.37#
1 L 60min 38 ± 1.77#*† 32.73 ± 3.77# 34.8 ± 3.28#
*p<0.05 (compared with Group R I),

†p<0.05 (compared with Group R II),

#p<0.05 (compared with 1 L 5 min)

For maintaining constant BIS values (40-60), delivered sevoflurane volume was similar between the groups. The difference between inspired and expired fractions of sevoflurane (Fisevo and Fetsevo) reduced by time during the low flow period. It was mostly lower in Group N than in remifentanil groups (Table 4).

Total consumption of sevoflurane was significantly greater in Group R II than in Group N [36.71 ± 7.46 vs. 28.93 ± 6.28 ml] but there was no significant difference in sevoflurane consumption and cost per patient per minute between groups.

Recovery times were comparable between the groups (Table 1). The Aldrete recovery scores were also similar in PACU. Patients were recorded with an Aldrete score over 9 after 7.9 ± 5.9 min in Group N, 8.1 ± 6.3 min in Group R I and 8.3 ± 6.7 min in Group R II (p > 0.05).

Table 4: The difference between inspired (Fisevo) and expired (Fetsevo) fractions of sevoflurane (mean ± SD)
Time Group N Group R I Group R II
4 L 0.23 ± 0.06*† 0.35 ± 0.07 0.37 ± 0.08
1 L 5min 0.19 ± 0.06*† 0.26 ± 0.05 0.27 ± 0.07
1 L 15min 0.18 ± 0.06*† 0.25 ± 0.06 0.26 ± 0.07
1 L 30min 0.12 ± 0.09#*† 0.21 ± 0.06# 0.23 ± 0.1#
1 L 45min 0.11 ± 0.07† 0.13 ± 0.11# 0.19 ± 0.05#
1 L 60min 0.09 ± 0.08# 0.1 ± 0.18# 0.13 ± 0.14#
1 L end 0.05 ± 0.21# 0.05 ± 0.12# 0.08 ± 0.09#
*p<0.05 (compared with Group R I)

†p<0.05 (compared with Group R II)

#p<0.05 (compared with 1 L 5 min)

DISCUSSION
Omitting N2O was suggested to have a number of advantages in LFA practice. In the present study, a significant decrease was observed in FiO2 by time for all groups. At all recording times, the difference between delivered O2 and FiO2 was the lowest in N2O group compared with remifentanil groups. None of the study groups led to hypoxic gas mixtures with FiO2 over 30%.

LFA techniques optimize the performance of re-breathing systems since high fresh gas flows minimize rebreathing fractions of exhaled gases.9 With technological advances in modern anesthesia, machines equipped with inhaled and exhaled gas monitoring permits safe and efficient usage of low flow techniques, especially when new inhalational anesthetics with low tissue solubility are administered.12,13
With low-flow techniques at reduced fresh gas flows, the fraction of expired gases in inspired gas concentrations increases and a disparity between the gas concentrations set at the anesthesia machine and in the breathing system develops. Rebreathing increases and O2 concentrations accordingly reduce in the exhaled gases, inspired O2 becomes lower than the delivered O2 concentration, and thus a risk of hypoxia occurs.

In an earlier randomized clinical study, Hendrickx et al examined the effect of different air-O2 mixtures and fresh gas flows on the relationship between the delivered and inspired O2 in a circle system.15 In accordance with our findings, they found a significant difference especially in the utilization of air-O2 mixtures with fresh gas flows under 2 L/min. They reported that the oxygen concentration in the exhaled gases decreases and the nitrogen concentration increases due to nitrogen accumulation. The authors concluded that more oxygen should be added when air-oxygen mixtures are administered in flow rates of less than 2 L/min to maintain the desired FiO2. In Bozkurt’s study of N2O-free LFA in children, despite the statistically significant decrease in inspired oxygen concentration, the high-delivered oxygen concentration (60%) prevented the occurrence of hypoxic gas mixtures.16 We also preferred 50% O2 to prevent the possibility of hypoxemia. For all these reasons, analysis of the FiO2 is mandatory when using air or N2O with LFA.

Similar to changes in oxygen concentration, the use of a fresh gas flow of 1 L/min decreases the inspired and expired values of inhaled anesthetic gases compared with the vaporizer settings. Johansson et al investigated the effect of two different fresh gas flows on inspired and end-tidal sevoflurane concentrations with a fixed vaporizer setting and noted a significant difference between 1 and 2 L/min for inspired and end-tidal concentrations.17 Using a 1 L/min fresh gas flow and a 2% vaporizer setting of sevoflurane, these authors found that the inspired and end-tidal sevoflurane concentrations in adult patients after 30 min of LFA were 1.4% and 1.2% respectively, while after 120 min of anesthesia they were approximately 1.5% and 1.3%. With the same fresh gas flow and vaporizer setting, Bozkurt et al demonstrated a similar significant decrease in the inspired and end-tidal value of sevoflurane compared with the vaporizer setting.16 Park et al also showed the same effect of low fresh gas flow on isoflurane concentrations at constant vaporizer settings.18 In the current study, delivered sevoflurane was not fixed to a constant concentration; alterations in vaporizer settings were adjusted to maintain a BIS value of 40-60. But in line with the literature findings, inspired and expired sevoflurane concentrations differed from the vaporizer settings. With constant BIS values (40-60), sevoflurane vaporizer settings were similar between the groups. The differences between the delivered sevoflurane volume and the end-tidal sevoflurane as well as inspired and expired fractions of sevoflurane (Fisevo and Fetsevo) were also evaluated and both decreased in time during low flow period. These differences were mostly lower in the N2O group than the remifentanil groups.

Remifentanil as a selective mu-opioid receptor-agonist provides optimal analgesia without producing a delay in recovery. The metabolism of remifentanil is independent of liver and kidney functions and it is distinguished by non-specific esterase in blood and tissue. Its short half-life is independent of the administered dose and duration of administration.19 The absence of analgesic effect in nitrous oxide-free groups in the present study was prevented by remifentanil infusions. We evaluated more stable and controllable hemodynamic parameters in remifentanil groups clinically but they were not statistically significant.

Due to the low solubility and high concentration delivered by the vaporizer, sevoflurane enables a safe and convenient control of the anesthetic level and is especially suitable for LFA in clinical practice. Moreover, the use of sevoflurane was suggested to be more economical and ecologically efficient only by LFA.17 At low fresh gas flows, the price difference for 1 MAC-hour expands for the volatile anesthetics with low solubility.20
In clinical practice, while carrying out nitrous oxide-free LFA, utilizing opioids can compensate the insufficient analgesic effect. Furthermore, when it comes to omitting N2O, awareness might be an issue of concern. The approach to light anesthesia in the LFA technique is to increase the volatile anesthetic concentration by 0.2-0.25×MAC or the FGF rate for a certain period.8 LFA is less costly but it provides less control of the depth of anesthesia. This means that the potential risks of light anesthesia or overdosing during LFA are greater than high flow techniques, so the monitoring of anesthetic agents and appropriate control of vaporizers are necessary during LFA.18,20,21 End tidal volatile anesthetic concentrations and minimum alveolar concentrations have been mostly used as a measure to maintain an adequate anesthetic level. In the present study, alterations in FGF were not permitted but the depth of anesthesia was controlled by changing vaporizer setting via BIS monitoring. The benefits of LFA when combined with the measurement of the depth of the anesthesia were considered in order to reduce volatile anesthetic consumption while avoiding risk of awareness. However, total consumption of sevoflurane was calculated to be significantly less in the N2O group than in the low remifentanil regimen group. There was no significant difference between the N2O group and the other remifentanil group. Presumably, in the lower remifentanil group, a single dose of remifentanil was insufficient for meeting analgesia. Similar with our findings, in another study that evaluated drug consumption related to variations in the fresh gas flow with the use of nitrous oxide at 1 MAC sevoflurane, sevoflurane utilization was found lowest at nitrous oxide in the oxygen group even compared with the lowest FGF oxygen in air group.22 Jakobsson et al also demonstrated that with fresh gas flow set at 3 L/min, the use of nitrous oxide decreased the sevoflurane cost by about 60% and the cost associated with the inhaled anesthetic by 40%.23
In an earlier study, Hendrickx concluded that during minimal flow anesthesia, the vaporizer setting required for maintaining a constant Fetsevo, was lower with an O2-N2O mixture than when 100% oxygen was used. This is probably due to the fact that when using O2-N2O as the carrier gas, less gas and vapors are wasted.24 In a later study, the same authors identified a second gas effect of N2O on sevoflurane.25
Bispectral index monitoring has been suggested not only to improve the financial burdens of anesthesia but also for the recovery profile when compared to the results of patients not monitored with BIS24. However, in the present study, recovery times as well as Aldrete Recovery Scores were comparable between the groups.

LIMITATIONS
One of the limitations of this study was small patient population and lack of sample size estimation. Also, a more extensive total cost analysis might provide additional information. Direct costs would increase if the equipment costs, such as the price of special electrodes, opioids, or infusion pumps were considered.

CONCLUSION
We conclude that, low-flow anesthesia technique demands expertise and attention from the anesthetist as risk of hypoxia and volatile anesthetic consumption do not differ regardless of the use of N2O; Hence monitoring FiO2 is essential. Both are safe to administer unless FiO2 is lower than 30%. Future randomized controlled studies with larger sample sizes are needed to encourage N2O free low-flow anesthesia. With appropriate remifentanil doses, air/O2 provide better hemodynamic stability without increasing sevoflurane consumption. BIS-guided sevoflurane with its low solubility feature is better in quickly adapting the desired anesthetic depth levels.

Conflict of Interest: The authors declare that they have no conflict of interest.

Authors’ contribution: Both authors took part in the concept, conduct of study, preparation of the manuscript and data analysis.

REFERENCES
  1. Hopkins PM. Nitrous oxide: a unique drug of continuing importance for anaesthesia. Best Pract Res Clin Anaesthesiol. 2005;19:381-9. [PubMed]
  2. Jahn UR, Berendes E. Nitrous oxide: an outdated anaesthetic. Best Pract Res Clin Anaesthesiol. 2005;19:391-7. [PubMed]
  3. Smith I. Nitrous oxide in ambulatory anaesthesia: does it have a place in day surgical anaesthesia or is it just a threat for personnel and the global environment? Curr Opin Anaesthesiol. 2006;19:592-6. [PubMed]
  4. Baum VC, Willschke H, Marciniak B. Is nitrous oxide necessary in the future? Paediatr Anaesth. 2012;22:981-7. doi: 10.1111/pan.12006. [PubMed]
  5. Enlund M, Edmark L, Revenas B. Is nitrous oxide a real gentleman? Acta Anaesthesiol Scand. 2001;45:922. [PubMed]
  6. Knudsen KE, Secher NH. Nitrous oxide: an ageing gentleman. Acta Anaesthesiol Scand. 2001;45:923-4. [PubMed]
  7. Baum JA. The carrier gas in anaesthesia: nitrous oxide/oxygen, medical air/oxygen and pure oxygen. Curr Opin Anaesthesiol. 2004;17:513-6. [PubMed]
  8. Baum J, Sievert B, Stanke HG, Brauer K, Sachs G. Nitrous oxide free low-flow anesthesia. Anaesthesiol Reanim. 2000;25:60-7. [PubMed]
  9. Baum JA, Aitkenhead AR. Low-flow anaesthesia. Anaesthesia 1995;50:37-44.
  10. European Society of Anaesthesiology task force on use of nitrous oxide in clinical anaesthetic practice. The current place of nitrous oxide in clinical practice: an expert opinion-based task force consensus statement of the European Society of Anaesthesiology. Eur J Anaesthesiol. 2015;32:517-20. doi: 10.1097/EJA.0000000000000264. [PubMed]
  11. Hendrickx J, Peyton P, Carette R, De Wolf A. Inhaled anaesthetics and nitrous oxide: Complexities overlooked: things may not be what they seem. Eur J Anaesthesiol. 2016; 34:1-9. doi: 10.1097/EJA.0000000000000467. [PubMed]
  12. Dion P. The cost of anaesthetic vapours. Can J Anaesth. 1992;39:633-4. [PubMed]
  13. Baum JA. New and alternative delivery concepts and techniques. Best Pract Res Clin Anaesthesiol. 2005;19:415-28. [PubMed]
  14. Brattwall M, Warrén-Stomberg M, Hesselvik F, Jakobsson J. Brief review: theory and practice of minimal fresh gas flow Can J Anaesth. 2012;59:785-97. [PubMed]
  15. Hendrickx JF, De Cooman S, Vandeput DM, Van Alphen J, Coddens J, Deloof T, et al Air-oxygen mixtures in circle systems. J Clin Anesth. 2001;13:461-4. [PubMed]
  16. Bozkurt P, Emir NS, Tomatır E, Yeker Y. N2O-free low-flow anesthesia technique for children. Acta Anaesthesiol Scand. 2005;49:1330-3. [PubMed]
  17. Johansson A, Lundberg D, Luttropp HH. The quotient end-tidal/inspired concentration of sevoflurane in a low-flow system. J Clin Anesth. 2002;14:267-70. [PubMed]
  18. Park YJ, Kim JH, Kim WY, Chang MS, Kim JY, Shin HW. Effect of fresh gas flow on isoflurane concentrations during low-flow anaesthesia. J Int Med Res. 2005;33:513-9. [PubMed] [Free full text]
  19. Servin FS. Remifentanil: an update. Curr Opin Anaesthesiol 2003;16:367-72. [PubMed]
  20. Golembiewski J. Economic considerations in the use of inhaled anesthetic agents. Am J Health Syst Pharm. 2010;67:9-12. doi: 10.2146/ajhp100093. [PubMed]
  21. Meyer JU, Kullik G, Wruck N, Kück K, Manigel J. Advanced technologies and devices for inhalational anesthetic drug dosing. Handb Exp Pharmacol. 2008;182:451-70. doi: 10.1007/978-3-540-74806-9_21. [PubMed]
  22. Ekbom K, Assareh H, Anderson RE, Jakobsson JG. The effects of fresh gas flow on the amount of sevoflurane vaporized during 1 minimum alveolar concentration anaesthesia for day surgery: a clinical study. Acta Anaesthesiol Scand. 2007;51:290-3. [PubMed]
  23. Jakobsson I, Heidvall M, Davidson S. The sevoflurane-sparing effect of nitrous oxide: a clinical study. Acta Anaesthesiol Scand. 1999;43:411-4. [PubMed]
  24. Hendricks JF, Coddens J, Callebaut F, Artico H, Deloof T, Demeyer I, et al. Effect of N2O on sevoflurane vaporizer settings during minimal- and low-flow anesthesia. 2002;97:400-4. [PubMed] [Free full text]
  25. Hendrickx JF, Carette R, Lemmens HJ, De Wolf AM. Large volume N2O uptake alone does not explain the second gas effect of N2O on sevoflurane during constant inspired ventilation. Br J Anaesth. 2006;96:391-5. [PubMed] [Free full text]
  26. Yli-Hankala A, Vakkurı A,Annıla P, Korttıla K. EEG bispectral index monitoring in sevoflurane or propofol anaesthesia: analysis of direct costs and immediate recovery. Acta Anaesthesiol Scand. 1999;43:545-9. [PubMed]