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2020, Volume 11, Issue 1, pages: 44-57 | https://doi.org/10.18662/brain/11.1/14  
 

Comparison of 
Inhaled Anesthesia 
with Sevoflurane 
and Intravenous 
Anesthetics with 
Propofol in Children 
under Flexible 
Bronchoscopy 

Anahid MALEKI1, Alireza 
TAKZARE2, Mehrdad 
GOUDARZI3, Alireza EBRAHIM 
SOLTANI4, Maryam NODEHI5 

1 Assistant Professor, children Medical Center, 
Tehran University of medical science 

2 Assistant Professor, children Medical Center, 
Tehran University of medical science, 
Drtakz@gmail.com  

3 Assistant Professor, children Medical Center, 
Tehran University of medical science   

4 Associated Professor, children Medical 
Center, Tehran University of medical science 

5 General physician, children Medical Center, 
Tehran University of medical science 

 

Abstract: Objective: Bronchoscopy is a diagnostic procedure. Due to 
lack of cooperation of children, pediatric bronchoscopy is necessarily 
accompanied by anesthesia. The most prevailing method of anesthesia in 
children is inhaled anesthesia, but since duration of anesthesia is long and 
there is involuntary respiration in this method, the amount of dispersed 
gas is high. The objective of this review is comparing inhaled anesthesia 
with sevoflurane and intravenous anesthetics with propofol in children 
under flexible bronchoscopy, in order to do a more appropriate and safe 
bronchoscopy and also to improve recovery after general anesthesia in 
children.  
Methodology: 80 children under the age of 10 who were going under 
flexible bronchoscopy, were randomly divided into two groups of 40 
individuals. For anesthesia of one group inhaled sevoflurane was given, 
and for the second group intravenous propofol was given; then in both 
groups changes in blood pressure, heart rate, O2 saturation t, and 
recovery time were recorded and compared. 
Findings: There is no significant difference in three times measurement of 
both anesthetics. In other words the average blood pressure shows no 
difference after anesthesia, start of bronchoscopy, and end of bronchoscopy 
in both anesthetics (P-value=0.771). Moreover, no significant difference 
was observed in three times measurement of both anesthetics. This means 
that the average heart rate shows no difference after anesthesia, start of 
bronchoscopy, and end of bronchoscopy in both anesthetics. Furthermore, 
the average o2sat is different after anesthesia, start of bronchoscopy, and 
end of bronchoscopy in both anesthetics (P-value>0.001). 
 

Keywords: bronchoscopy; sevoflurane; propofol. 
 
How to cite: Maleki, A., Takzare, A., Goudarzi, M., Soltani, 
A.E., & Nodehi, M. (2020). Comparison of Inhaled 
Anesthesia with Sevoflurane and Intravenous Anesthetics 
with Propofol in Children under Flexible Bronchoscopy. 
BRAIN. Broad Research in Artificial Intelligence and Neuroscience, 
11(1), 44-57. https://doi.org/10.18662/brain/11.1/14  

https://doi.org/10.18662/brain/11.1/14
mailto:Drtakz@gmail.com
https://doi.org/10.18662/brain/11.1/14


Comparison of Inhaled Anesthesia with Sevoflurane and Intravenous … 
Anahid MALEKI et al. 

 

45 

Introduction 

The term anesthesia was first proposed by Oliver Wendell Holmes 
(Haridas, 2016) on the basis of its Greek root meaning “no sense” to 
William Morton in 1846 (Morton, 1846). Even in deep anesthesia some basic 
senses continue to exist, so it is more appropriate to assume anesthesia as a 
stationary state without any kind of perception. As an easy definition, 
anesthesia is losing sense of pain or perception during a surgery. Anesthesia 
is classified into local, regional or general forms, and may vary depending on 
type of surgery and health conditions of the specific person (Bakan et al., 
2014) 

Types of anesthesia and their level of effect differ. Regional 
anesthesia creates analgesia effect, while anesthesia with Benzodiazepines 
creates sedative effects. General anesthesia may produce all effects of 
analgesia, sedation, and forgetfulness; its ultimate goal is to attain conditions 
in which surgical procedure is done in the best possible way with minimum 
risk. This goal is achieved through various but connected functions of 
medicines on nervous system of patient. For instance, the drowsiness impact 
of medication is created by affecting the central nervous system cells and 
activating state of sleep for the patient (Chen et al., 2016; Damian et al., 
2019). 

Injectable anesthetics are medicines injected to body through 
intravenous. Propofol is one of the most important of these medications. 
Propofol has no analgesic effect, it reduces blood flow of the brain, brain 
pressure and pressure of the eye. It also lowers blood pressure by dilating 
the arteries. Quick infusion of propofol causes apnea in patients (Dewhirst 
et al., 2013). It spreads in body rapidly and enters the Central Nervous 
System (CNS) as well. Its quick exit from CNS is a reason of its short-time 
effect. It is also metabolized in liver speedily (Hofmeister & Pille, 1977). 

Inhaled anesthetics are chemical compounds having anesthesia 
properties and patient becomes unconscious by inhaling them. Sevoflurane is 
one of the important medications of this group. This medication quickly 
enters blood through lungs and leaves blood with the same speed, therefore 
has a rapid anesthesia and anesthesia return. Minimum alveolar concentration 
(MAC) is 4.1% in elderly and 3.3% in children (Larsen et al., 2012).  

Various studies are conducted in this field. For example, Chen et al. 
(2016) performed a research to determine effects of propofol and 
sevoflurane on cytokine levels in children with acquired pneumonia from a 
population under flexible fibrotic bronchoscopy. Results showed that in 



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46 

children with acquired pneumonia from that population, the use of 
sevoflurane was dependent on low levels of interleukin 6 and 15 versus 
propofol. The intensity of pneumonia was reflected with higher levels of 
blood cytokine (Chen et al., 2016). Also, Rivenes et al. (2001) found out that 
halothane causes a significant reduction in the average pressure of ejection 
fraction and the heart index. Moreover, in a study done by Larsen et al. 
(2012) it became evident that Sevoflurane reduces regional area of infarction 
and improves hemodynamics in patients. Findings of a research conducted 
by Hasani et al. (2011) (Hasani et al., 2013) indicated that compared with 
propofol, sevoflurane could have similar and safe effects in non-relaxant 
intubation in children undergoing surgery (Moshiri et al., 2013).  

Bronchoscopy is a diagnostic procedure and general anesthesia is 
required for doing it. Currently, flexible bronchoscopy is used for diagnosis 
of many lung diseases, in children due to the lack of child cooperation, 
bronchoscopy is inevitably done with anesthesia. Various anesthesia 
methods are used for this group of patients, the most prevalent of which is 
inhaled anesthesia. But since duration of anesthesia is longer in this method 
and there is involuntary respiration, the amount of dispersed gas is high. 
Intravenous methods are used as well. Propofol due to its short-acting effect 
can be helpful in such cases. Controlling duration of anesthesia as well as 
short-time effect of medication is amongst necessities of this method. To 
achieve this, the present study was performed with the objective of 
comparing inhaled anesthesia with sevoflurane and intravenous anesthesia 
with propofol in terms of hemodynamic and induction and preservative 
effects, and improvement features in children under flexible bronchoscopy 
in a pediatric medical hospital. 

Materials and Methods 

This study is a clinical trial and interventional, which was conducted 
on children with flexible bronchoscopy in a pediatric medical hospital. 
Research participants included 80 children with the age range of below 10 
years old, and with physical condition of ASAI, II who participated in the 
research by having informed consent and observing all ethical issues, then 
based on random numbers table they were divided into two groups. During 
this study, these children were undergoing bronchoscopy to remove external 
objects from their tracheobronchial tree. They were randomly divided into 
two groups of A and B. Group A with n=40 included children who received 
8% of sevoflurane for anesthesia and anesthesia continued the same. Group 
B with n=40 included children who received 2 mg/kg propofol for 



Comparison of Inhaled Anesthesia with Sevoflurane and Intravenous … 
Anahid MALEKI et al. 

 

47 

anesthesia, and it continued with 200-300 mic/kg/min. The age, sex, weight 
and patients profiles as well as the details of their physical inspection along 
with findings of chest X-ray, were recorded in information collection forum.  

Method of Research 

After having access to the peripheral vein, all patients received 0.01 
mg / kg atropine and 0.1 mg / kg dexamethasone and fentanyl 1 mic/kig. In 
group A. Drager Fabius Plus anesthesia machine equipped with sevoflurane 
was used for patients. Anesthesia induction was done by MAPELSON F 
system and face mask with inhalation of 100% oxygen and sevoflurane 
during involuntary breathing, and concentration of anesthetics was increased 
gradually in every 3 to 5 inhalation for sevoflurane at 2-4-6-8% 
concentration, respectively. In group B, anesthesia induction was done by 
propofol infusion at a dose of 2.5 mg/kg, and anesthesia continued with 
propofol infusion 25-100 mic/kg/min. To reduce pain in the injection area, 
propofol was diluted with lidocaine 2% with ration of 1: 1. 

Before bronchoscopy, in all patients, lidocaine 2% with a maximum 
dose of 5 mg / kg was sprayed on the epiglottis and larynx and between the 
vocal cords and the upper part of trachea. The depths of anesthesia and 
bronchoscopy conditions were evaluated by clinical hemodynamic 
parameters including blood pressure, heart rate, cough, pushing and 
movement. When the procedure ended, inhaled medicines were stopped and 
bronchoscope was removed through airway. During involuntary breathing, 
children received %100 oxygen through Mask. The time interval between 
cutting the anesthetics medicines and opening the eyes or responding to 
non-painful stimuli was recorded. Any unfavorable effects such as Cough, 
laryngeal or bronchial spasm, shortness of breath or apnea were recorded. 
Postoperative croup and oedema of the upper respiratory system, if 
observed, were treated by inhalation of epinephrine and wet oxygen. 

Criteria to participate in research include: being fast, patients must be 
connected to ECG and blood pressure measurement devices before 
anesthesia induction, aximetry pulse, recording heart, BP and arterial oxygen 
level in every 5 minutes, consent of patient to take part in the research, 
having no specific disease, and being conscience before surgery. Criteria to 
leave research include: lack of patient‟s consent, abnormal response to 
anesthetic medicines of study, patients with serious cardiovascular, liver, 
kidney and muscular diseases, children with a history of increased respiratory 
sensitivity and irritable airways and history of airway disease, and patients 
having cold and children with history of respiratory response to anesthetics.  



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Data Analysis Method 

The collected data were recorded in SPSS data bank, and then 
analyzed on the basis of research objectives. Quantitative data were 
explained as mean, standard deviation, and qualitative variables as frequency 
or relative frequency. In order to analyze variables in groups in regard of 
quantitative data, repeated measures and independent sample t-test were 
used. P-value under 0.05 was considered as significant.  

Ethical Observations 

According to the principles of the Declaration of Helsinki, data were 
recorded confidentially and required explanations were given to the parents 
of patients. Besides that, all information of patients is secret and will not be 
available to any legal or natural person. Research conditions are explained to 
research participants and their parents and informed consent is taken from 
them. Moreover, before implementation of the study, coordination with the 
authorities of the surgery department and surgery room was done. No extra 
charge will be imposed on patients.  

Research Findings 

In table 1 a comparison of blood pressure mean in three times of 
measurement in the two kinds of anesthetics is represented. There is no 
significant difference between three times of measurement in the two kinds 
of anesthetics. In other words, blood pressure mean shows no difference 
after anesthesia, in the beginning of bronchoscopy and in the end of 
bronchoscopy (P-value=0.771) (figure 1). 

 
Table 1. A comparison of Blood Pressure Mean in Three Times of Measurement 

in the Two Kinds of Anesthetics  
 

 Anesthetics  Mean Std. Deviation N 

Blood pressure mean 
after anesthesia  

sevoflurane 75.7750 7.67405 40 

propofol 77.3000 6.20164 40 

Total 76.5375 6.97484 80 

Blood pressure mean in 
the beginning of 
bronchoscopy  

sevoflurane 77.1000 6.85553 40 

propofol 76.5333 6.39480 40 

Total 76.8167 6.59325 80 

Blood pressure mean in 
the end of  
bronchoscopy 

sevoflurane 76.0333 7.56013 40 

propofol 77.6667 5.79222 40 

Total 76.8500 6.74196 80 



Comparison of Inhaled Anesthesia with Sevoflurane and Intravenous … 
Anahid MALEKI et al. 

 

49 

 

Figure 1. Rate of Changes in Sevoflurane and Propofol 

Comparison of PR in three times of measurement in the two kinds 
of anesthetics in presented in table 2. According to the results of figure 2, 
there is no significant difference between three times of measurement in the 
two kinds of anesthetics. In other words, heart rate mean shows no 
difference after anesthesia, in the beginning of bronchoscopy and in the end 
of bronchoscopy (P-value=0.214). 

 
Table 2. A Comparison of PR in Three Times of Measurement in the Two Kinds 

of Anesthetics  
 

 Anesthetics  Mean Std. Deviation N 

PR after anesthesia  sevoflurane 126.1750 24.29085 40 

propofol 121.3000 21.67854 40 

Total 123.7375 23.00674 80 

PR in the 
beginning of 

bronchoscopy  

sevoflurane 127.8750 26.02187 40 

propofol 123.0000 20.78461 40 

Total 125.4375 23.52798 80 

PR in the end of 
bronchoscopy 

sevoflurane 127.3750 24.75489 40 

propofol 123.3000 20.33590 40 

Total 125.3375 22.60276 80 

 



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Figure 2. PR Changes of Sevoflurane and Propofol  

Comparison of O2SAT in the two kinds of anesthetics in presented 
in table 3. According to the results of figure 3, there is a significant 
difference between three times of measurement in the two kinds of 
anesthetics. In other words, O2SAT mean is different after anesthesia, in the 
beginning of bronchoscopy and in the end of bronchoscopy in the two 
kinds of anesthetics (P-value<0.001). 

 
Table 3. A Comparison of O2 SAT in the Two Kinds of Anesthetics 

 Anesthetics  Mean Std. Deviation N 

O2 SAT after 
anesthesia 

sevoflurane 97.5000 4.64648 40 

propofol 97.3000 3.79068 40 

Total 97.4000 4.21450 80 

O2 SAT in the 
beginning of 

bronchoscopy 

sevoflurane 91.2000 7.25435 40 

propofol 97.2000 5.21929 40 

Total 94.2000 6.96719 80 

O2 SAT in the end 
of bronchoscopy 

sevoflurane 87.7250 9.68739 40 

propofol 96.8000 5.72534 40 

Total 92.2625 9.13020 80 

 



Comparison of Inhaled Anesthesia with Sevoflurane and Intravenous … 
Anahid MALEKI et al. 

 

51 

Figure 3. Changes of O2 SAT of Sevoflurane and Propofol  

Comparison of age, weight, and recovery time in both groups with 
independent sample t-test showed that there is no significant difference in 
the age mean (P-value=0.732) of patients in the two kinds of anesthetics 
which is indicative of proper homogenization in two groups. There is no 
significant difference in the weight mean (P-value=0.423) of patients in the 
two kinds of anesthetics which is indicative of proper homogenization in 
two groups (table 4). Furthermore, results of table 5 show a significant 
difference (P-value<0.001) between recovery time in two groups. In other 
words, recovery time mean is different in two groups. The mean is higher in 
sevoflurane anesthetics.  

 
Table 4. Difference between Age and Weight in Two Groups of Sevoflurane and 

Propofol  
 

 
Anesthetics N Mean Std. Deviation 

Std. Error 
Mean 

age sevoflurane 40 3.7500 2.80339 .44325 

propofol 40 3.9500 2.39069 .37800 

weight sevoflurane 38 17.9211 7.96744 1.29249 

propofol 40 19.2000 5.83183 .92209 

 



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Table 5. Difference in Recovery Time in Two Groups of Sevoflurane and 
Propofol  

 

 
Anesthetics  N Mean 

Std. 
Deviation 

Std. Error 
Mean 

Recovery time 
(minute) 

sevoflurane 40 32.1250 5.45935 .86320 

propofol 40 19.5000 4.77708 .75532 

Discussion  

Statistically there is no significant difference in demographic 
variables (age, weight) of two groups, so it seems that homogenization of 
groups has been appropriate and in this regard there are no confounding 
factors in this research. As can be seen, systolic and diastolic PR and BP 
variables were measured in both groups in the beginning, during and the end 
of surgery. After anesthesia induction, patients of both groups showed a 
slight increase in heart rate and decrease in blood pressure. But this rate of 
increase and decrease required no special clinical measurement. At the same 
time, statistically there is no significant difference in any one of the groups 
and between the two groups before, during, and after surgery. It seems that 
cardiovascular stability rate of both kinds of anesthetics is similar and in this 
regard both can be safe. 

There is a significant difference in propofol and sevoflurane groups 
between in full consciousness time and recovery time. In sevoflurane group, 
recovery time is nearly doubled. It seems that in terms of recovery time and 
full consciousness, propofol is preferred and can reduce recovery time of 
patients. Side effects (sough, apnea, spam) were more in propofol group 
than sevoflurane group, but they are not statistically significant. By 
increasing sample size, contradictory results may be obtained, therefore it 
seems that prescribing these medications does not escalate complications; in 
this regard if any complication is observed, it is due to the procedure itself 
and not because of type of anesthesia and anesthetics used. Apparently both 
medications are suitable for patients with foreign object endoscopy and 
scientifically both of them are safe.  

In a research conducted by Kaynar et al. (2011), diverse effects of 
propofol and sevoflurane on heart beat rate were observed. While propofol 
decreased blood pressure and heart beat depending on the depth of 
hypnosis, sevoflurane showed no prominent effect on hemodynamic indices. 
Despite the mentioned studies, in this research no significant difference was 
observed in heart beat rate of patients in two groups. Of course, it must be 
emphasized that hypnosis level is not measured and investigated in the 



Comparison of Inhaled Anesthesia with Sevoflurane and Intravenous … 
Anahid MALEKI et al. 

 

53 

present research. There is evidence that indicates some patients develop 
tachycardia after receiving propofol; but this study showed no difference in 
heart beat rate of patients. Potocnik et al. (2011), in a study, investigated and 
compared propofol and sevoflurane impacts on hemodynamic indices of 
patients under thoracotomy. It was also observed that hemodynamic indices 
are more stable in the group receiving propofol and patients of this group 
need less ephedrine (Cai et al., 2013). 

In a research Barthi and et al compared effects of sevoflurane and 
diets having propofol. Their findings indicated that sevoflurane is superior 
to propofol in maintaining cardiovascular stability; they also observed a 
shorter recovery time in the group receiving sevoflurane (Bharti et al., 2012). 
This finding is contrary to our research findings according to which patients 
receiving sevoflurane and ketamine had shorter recovery time than propofol 
and ketamine. Glaisyer and Sury (2005) observed in a study that recovery 
time in the group receiving propofol and remifentanil, was 19 minutes 
shorter than propofol, sevoflurane and nitrate oxide recipients. Their finding 
is consistent with results of this study.  

Different studies have been conducted to evaluate various anesthetic 
techniques and compare anesthetics about the difference between propofol 
as an injectable medication and sevoflurane as an inhaled medication, butthe 
implemented procedures have been different.For example, in Glaisyer's 
study, this comparison is made during painful oncology procedures. In the 
research of (Liao et al., 2010), during rigid bronchoscopy, in Boninn‟s study 
(D'Arienzo et al., 2011) in fibropetic intubation, and in the study of Kogan 
(Kogan et al., 2003) various surgeries were performed on air data including 
rigid bronchoscopy and micro-laryngeal bronchoscopy and laser treatments 
on air data. In our study type of surgery has been constant and flexible 
bronchoscopy is done for all patients, therefore this confounding factor of 
surgery type is decreased in achieving results of the study. In various studies 
different combinations of data are used. The study of Glaisyer and Sury 
(2005) compared effects of propofol, sevoflurane and nitrozoxide 
combination with total IV propofol and remifentanil combination. This is 
while in this research, similar to studies of Liao et al. (2010) and Boninn 
(D'Arienzo et al., 2011), two groups of sevoflurane and propofol 
medications are compared separately; in this way the impact of medications 
overlapping effects is eliminated and evaluation and comparison of the two 
medications is made easier and safer. In the study of Glaisyer and Sury 
(2005) the sample size was of 22 persons, it was of 64 individuals in the 
study of Liao et al. (2010), and of 52 persons in the research of Bonnin 
(D'Arienzo et al., 2011),. Each of the studies used premedication. In the 



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present study sample size was of 80 individuals, which is superior to other 
studies in this respect. 

In the study of Glaisyer and Sury (2005) variables of age, procedure 
duration, recovery time, and parents desire for kind of anesthetics are 
evaluated. However in the present study, homogenization, homogeneous age 
groups and children's weight, recovery time, HR, BP, SPO2, and 
postoperative complications were evaluated. Variables used by Liao in the 
study (Liao et al., 2010) included PR, HR, BP, induction time, and the need 
to intubation. Therefore, it seems that our research is superior to the studies 
of Glaisyer and Liao in respect of homogenization of demographic variables 
and evaluation of hemodynamic and arterial oxygen depletion and evaluation 
of anesthesia and recovery time. Research findings of Glaisyer study showed 
that recovery time in propofol group was much shorter than sevoflurane and 
propofol combination, and patients‟ parents were more willing to use 
propofol, but other variables was almost the same in each group. Therefore, 
in respect of recovery time, this study is consistent with findings of 
Glaisyer‟s study, and in regard of hemodynamic stability, similar to Glaisyer‟s 
study, both medications acted the same. However, in the research of Liao, 
induction and recovery time in group receiving sevoflurane was reported to 
be shorter which is contrary to our findings. No difference between the two 
medications, in respect of induction and recovery time as well as 
hemodynamic variables is reported in the study of Bonnin.  

Referring to time spent in recovery, as expected, this time was 
significantly lower in the sevoflurane group, the reason can be due to 
inhalation method of sevoflurane and the chemical and pharmacokinetic 
properties of thisanesthetic medication. Two cases of nausea and vomiting 
were observed and recorded in the sevoflurane group. However, no cases of 
nausea and vomiting were observed in the propofol group, which was 
expected as well and is related to antiemetic effect of propofol. Of course, 
this difference was a statistical one, and since patients with nausea and 
vomiting in sevoflurane group needed any special treatment, so there was no 
significant clinical difference in respect of nausea and vomiting in two 
groups.  

Conclusion  

It seems that both medications have been suitable for patients with 
foreign object endoscopy and scientifically both of them are safe. But the 
appealing finding of this study was that in the propofol group, both the 
speed of anesthesia and recovery were higher in patients. Accordingly, it 



Comparison of Inhaled Anesthesia with Sevoflurane and Intravenous … 
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55 

seems that, referring to time, prescription of propofol can make the duration 
of time safer for us, and is preferable in this regard. About hemodynamic 
variables both medications are safe and suitable in respect of anesthesia 
induction in bronchoscopy patients. The use of propofol causes less 
contamination of surgery room, better recovery, and in general reduction in 
costs for the patient.  

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