Emergency. 2018; 6(1): e53

OR I G I N A L RE S E A RC H

Intravenous versus Subcutaneous Midazolam Using Jet-
injector in Pediatric Sedation; a Randomized Clinical Trial
Majid Hajimaghsoudi1, Mehdi Bagherabadi2, Ehsan Zarepur3, Vahid Ahmadi Hanzaei4∗

1. Emergency Department, Trauma Research Center, Shahid Sadoughi University of Medical Sciences, Yazd, Iran.

2. Emergency Department, School of Medicine, Shahid Sadoughi University of Medical Sciences, Yazd, Iran.

3. Isfahan Cardiovascular Research Center, Cardiovascular Research Institute, Isfahan University of Medical Sciences, Isfahan, Iran.

4. Emergency Department, School of Medicine, Shahid Sadoughi University of Medical Sciences, Yazd, Iran.

Received: May 2018; Accepted: August 2018; Published online: 31 August 2018

Abstract: Introduction: The quality of interventions in children is largely dependent on their control. Hence, this study
compared the sedative effects of subcutaneous (SC) and intravenous (IV ) Midazolam in pediatric sedation in-
duction. Methods: This randomized clinical trial was conducted on children aged 1-6 years presenting to emer-
gency departments of Shahid Sadoughi and Shahid Rahnemoon Hospitals, Yazd, Iran. Participants were ran-
domly assigned to IV or SC midazolam using a jet injector and success rate, degree of sedation, and satisfaction
of parents and physician were compared between groups. Results: 60 cases with the mean age of 3.15±1.43
(1-6) years were randomly assigned to the SC (30 cases) or IV (30 cases) groups (56.7% female). SC and IV groups
were similar regarding the mean age (p = 0.165) and sex (p = 0.121). Depth of sedation (p=0.900), control of child
(p=0.711), in-charge physician’s satisfaction (p=0.467), successful sedation and need for rescue dose (p=0.519)
were not different between groups. IV midazolam group had a significantly shorter recovery time (about 10 min-
utes; p=0.040) and SC midazolam group had a significantly higher level of parent satisfaction (p=0.001). Conclu-
sion: The findings indicate no significant difference in depth of sedation, control of child, in-charge physician’s
satisfaction, successful sedation (reaching stage 1 of sedation or higher), and need for rescue dose of SC and IV
midazolam. Parents’ satisfaction was significantly greater with SC administration and IV injection had shorter
recovery time.

Keywords: Midazolam; sedation; jet injector; Injections, Subcutaneous; Personal satisfaction; children.

© Copyright (2018) Shahid Beheshti University of Medical Sciences

Cite this article as: Hajimaghsoudi M, Bagherabadi M, Zarepur E, Ahmadi Hanzaei V. Intravenous versus Subcutaneous Midazolam Using

Jet-injector in Pediatric Sedation; a Randomized Clinical Trial. Emergency. 2018; 6(1): e53.

1. Introduction

M
any patients present to the emergency department

(ED). Children are vulnerable to many diseases

and constitute a considerable number of traumatic

patients presenting to ED. The correct implementation of di-

agnostic procedures requires control and tranquility of chil-

dren as lack of children’s cooperation due to anxiety and dis-

comfort leads to lengthening of diagnostic procedures and

reduces their quality. So, the use of sedatives is mandatory

∗Corresponding Author: Vahid Ahmadi Hanzaei; Emergency Medicine
department, Shahid Sadoughi Hospital, Ibn Sina St., Riazi Sq., PO Box
8915887857, Yazd, Iran. E-mail: d.vahidahmadi@yahoo.com Tel: +98
3538224000 Fax: +98 3538224001

in younger children to increase the quality of the provided

interventions and shorten the duration of these procedures.

The use of diagnostic procedures and minor surgical oper-

ations outside the operating room has increased over the

last decade. Yet, the administration of sedatives to children

is associated with risks like hypoventilation, apnea, airway

obstruction, laryngospasm, and impaired cardiopulmonary

functioning. Hence, the selection of appropriate drugs for

diagnostic and therapeutic interventions is as important as

the diplomacy and tactfulness of the in-charge physician in

reacting to drug complications (1-5). Midazolam is a short-

acting benzodiazepine with sedative, narcotic, anxiolytic, an-

ticonvulsive, and relaxing effects (1, 6, 7). Its acute complica-

tions include respiratory suppression and apnea which occur

rarely in cases of rapid injection of high doses of the drug. Ad-

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M. Hajimaghsoudi et al. 2

ditionally, Midazolam is a rapid-acting sedative with minimal

effect on blood oxygenation level and cerebral blood flow,

which renders it a suitable drug for cerebral imaging stud-

ies like MRI (6). Midazolam can be administered via intra-

venous (IV ), subcutaneous (SC), muscular, intranasal, buc-

cal, and rectal routes. One modality of Midazolam adminis-

tration is the subcutaneous injection in which the drug effect

is initiated in 7 minutes reaching a peak during 23-49 min-

utes. The onset of IV Midazolam effect is 3-5 min, which is

finally eliminated by the liver (7, 8). Given that the subcu-

taneous injection with a jet injector is almost painless, and

also based on what has been said so far and considering the

lack of sufficient related studies in this field, especially on the

use of jet injector in ED (9-11), we embarked on comparing

the SC midazolam using jet injector with IV midazolam in

performing sedation for doing non-invasive diagnostic pro-

cedures in children aged 1-6 years.

2. Methods

2.1. Study design and setting

This parallel randomized clinical trial was carried out on

traumatized children aged 1-6 years presenting to EDs of

Shahid Sadoughi Hospital and Shahid Rahnemoon Hospitals

in Yazd, central Iran, from April to June 2015, who needed

control and sedation for undergoing a diagnostic procedure.

The research goals and procedures were explained clearly to

the parents and the possible complications of drug admin-

istration (hypoxia, respiratory depression, apnea, coma, hy-

potension, agitation, confusion, and cough) were elucidated

in a crystal-clear fashion. Informed written consent was ob-

tained from the children’s parents. The research proposal

was approved by Committee of Ethics in Research at Shahid

Sadoughi University of Medical Sciences, Yazd, Iran, with

code of ethics no.: IR.SSU.Medicine.REC.1393.30 and regis-

tered in Iranian Registry of Clinical Trials with no.: IRCT no.:

IRCT201510018640N2.

2.2. Participants

Traumatized children aged 1-6 years presenting to EDs of the

mentioned hospitals and in need of sedation for doing non-

invasive diagnostic procedures were enrolled. Un-stable vi-

tal signs, reduced level of consciousness, a positive history

of taking anticonvulsive drugs, allergy to midazolam, lack

of consent for participating in the study, and children with

moderate to severe pain (pains with scores greater than 4 out

of 10 form the researcher’s perspective) were among the ex-

clusion criteria.

2.3. Procedure and data gathering

After history taking and complete medical examination, chil-

dren diagnosed by the medical emergency specialist to be in

need of sedation for performing diagnostic intervention who

met the inclusion criteria were randomly and blindly (with-

out awareness of the researcher and the assessor) assigned

to SC or IV midazolam groups using convenience sampling

method. In doing so, random numbers were selected by a

computer and placed in opaque envelopes, which were num-

bered sequentially. The number in the envelope was placed

in the SC with jet injector group if it was an even number and

in the IV group if it was an odd number. Injection was done

in the brachial area for jet injector patients while IV injec-

tion was performed in the cubital zone after phlebotomy in

the IV group. Phlebotomy was performed by nurses with a

5-year work experience. If phlebotomy failed in the cubital

area of one hand, the other hand was then used for injection.

Midazolam with the initial dose of 0.2 mg/kg was adminis-

tered subcutaneously using jet injector (INJEXT M 30, Carpol

0.3 cc, Needle Free, Made in Germany) in the case group and

given to the IV group with the dose of 0.1 mg/kg by a periph-

eral vein catheter. The assessor was also blind to the site of

injection in both groups not to be aware of the type of injec-

tion. The children underwent cardiac monitoring and pulse

oximetry before the onset of sedation and their level of con-

sciousness was measured by the assessor once per min be-

fore and after sedation (Stage 0: conscious; stage 1: silence;

stage 2: drowsy; stage 3: napping; stage 4: deep sleep). When

the child reached stage 1 of sedation, the intended procedure

was commenced. Successful sedation (achieving stage 1 of

sedation), degree of sedation before and after injection (by

the assessor once per min), and parents’ and the physician’s

satisfaction with the whole process of sedation and diagnos-

tic technique (completely dissatisfied, dissatisfied, indiffer-

ent, satisfied, and completely satisfied) were measured as

primary variables. In addition, the time of regaining full con-

sciousness (level A of AVPU), child control, and the need for

reinjection of drug in the case of failure were assessed as sec-

ondary variables. Child control was defined as the degree of

difficulty in positioning and controlling the child during per-

formance of the procedure for which the physician was asked

by the assessor using a 5-point Likert scale item (very diffi-

cult, difficult, moderate, easy, and very easy). In cases that

the child did not enter stage 1, reinjection was performed

20 minute after the first injection in the case group and 3

minute after the first injection in the control group. If after

one reinjection the required sedation was not achieved, the

procedure was considered as failure and the resident medical

emergency specialist decided on the continuation or discon-

tinuation of the procedure. The child was monitored during

and after completion of the procedure till full consciousness

was reached and the time of full consciousness recovery was

measured.

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3 Emergency. 2018; 6(1): e53

Flowchart 1: Enrollment and allocation of patients to the studied groups.

2.4. Statistical Analysis

The sample volume in each group was set at 42 on the ba-

sis of the study by Bennett et al. (12) considering type I error

of 0.05 and type II error of%20, which was increased to 60 to

enhance the validity of the study results. The data were ana-

lyzed by an experienced statistician blind to the groups using

SPSS Ver. 17 (SPSS, Chicago, IL, USA). Descriptive statistics of

mean ± standard deviation and frequency (percentage) were
used to report the results. Also, Chi-square test was used to

analyze nominal data, and independent sample t-test or their

nonparametric equivalents were used to analyze the quanti-

tative data. The level of significance was considered 0.05.

3. Results

3.1. Baseline characteristics of participants

75 children were evaluated, 10 of which were excluded due to

not meeting the inclusion criteria or declining to participate

(flowchart 1). Finally, 60 cases with the mean age of 3.15±1.43
years were randomly assigned into the SC (30 cases) or IV (30

cases) groups (56.7% female). Owing to lack of cooperation,

1 child from the jet injector group and 2 children from the IV

group were excluded from the study. Also, 1 child was omit-

ted from each group due to the parents of the two children

deciding to withdraw from the study (flowchart 1). SC and IV

groups were similar regarding the mean age (2.8 ± 1.2 vs 3.4
± 1.6, respectively; p = 0.165) and sex (56.7% vs 36.7% female,
respectively; p = 0.121).

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M. Hajimaghsoudi et al. 4

Table 1: Comparing the procedural sedation and analgesia (PSA) characteristics of subcutaneous and intravenous midazolam in 1- 6 year old

children

PSA characteristics Subcutaneous n=30 Intravenous n=30 P
Depth of sedation
Fully conscious 5 (16.7) 3 (10.0)
Silent 1 (3.5) 1 (3.3)
Drowsy 0 0 0.900
Napping 1 (3.3) 1 (3.3)
Deep sleep 23 (76.7) 25 (83.3)
Child control
Very difficult 1 (3.3)
Difficult 4 (13.3) 5 (16.7)
Moderate 2 (6.7) 2 (6.7) 0 (0)
Easy 22 (73.3) 23 (76.6)
Very easy 1 (3.3) 0 (0)
Physicians’ satisfaction
Completely dissatisfied 4 (13.3) 4 (13.3)
Dissatisfied 3 (10) 1 (3.3)
Indifferent 1 (3.3) 0 (0) 0.467
Satisfied 8 (26.7) 22 (73.3)
Completely satisfied 14 (46.7) 3 (10.0)
Parents’ satisfaction
Completely dissatisfied 3 (10.0) 4 (13.3)
Dissatisfied 2 (6.7) 7 (23.3)
Indifferent 3 (10.0) 12 (40.0) 0.001
Satisfied 18 (60.0) 6 (20.0)
Completely satisfied 4 (13.3) 1 (3.3)
Successful sedation*
Yes 25 (83.3) 27 (90.0) 0.519
No 5 (16.7) 3 (10.0)
Recovery time (minute)
Mean ± standard deviation 35.8 ± 9.71 24.8 ± 7.60 0.040
Data are presented as number (%). *: Achieving sedation stage 1.

3.2. PSA characteristics of two groups

Table 1 compares the characteristics of PSA between SC and

IV midazolam groups. Two groups were similar regarding

the depth of sedation (p=0.900), control of child (p=0.711),

in-charge physician’s satisfaction (p=0.467), successful seda-

tion and need for rescue dose (p=0.519). IV midazolam group

had a significantly shorter recovery time (about 10 minutes;

p=0.040) and SC midazolam group had significant higher

level of parent satisfaction (p=0.001). None of the possible

midazolam side effects (hypoxia, respiratory depression, ap-

nea, coma, hypotension, agitation, confusion, and cough)

were manifested in any child in this study. Moreover, no der-

mal reaction like arythema, swelling, or inflammation was

observed at the site of injection.

4. Discussion

The findings indicate no significant difference in depth of

sedation, control of child, in-charge physician’s satisfaction,

successful sedation (reaching stage 1 of sedation or higher),

and need for rescue dose between SC and IV midazolam. Par-

ents’ satisfaction was significantly greater with SC adminis-

tration and IV injection had shorter recovery time. The trau-

matized children ought to be controlled and immobilized

during diagnostic procedures such as CT scanning, MRI, ra-

diography, and ultrasonography. There are various medica-

tions with different complications for induction of sedation.

The study by Pecking et al. (2002) conducted in France inves-

tigated the biological power of SC midazolam in volunteers

and the results showed that the biological potency of SC in-

jection of the drug was not significantly different from the IV

injection so that when the IV route was not accessible, the

SC route could be used safely, which is consistent with our

findings (13). Moreover, the study by Greenberg et al. (1995)

explored the effect of administration of different doses of mi-

dazolam with jet injector on 40 children and found that jet

injector administration quickly induced the effect of Mida-

zolam. This is again consistent with our findings (14). The

highly appropriate effect of the drug in the jet injector group

may be attributed to proper distribution of the drug in the

tissue leading to greatly acceptable absorption and the rapid

effect of the drug (12). Generally speaking, although in the

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5 Emergency. 2018; 6(1): e53

jet injector method it logically takes longer for the drug to

show its effect compared to the IV method, in the studies

conducted so far the effect of drug is seen faster when using

jet injector compared to the oral route since administration

of the drug using jet injector can induce the intended plasma

level of Midazolam with the same speed as the IM injection of

the drug. Also, when there is oral route resistance in the child

(15) or when there is the need for avoiding phlebotomy ten-

sion in the child, the use of jet injector is a suitable method.

Of course, the time of full recovery in jet injector group was

35.8Âś9.71 minute, which was significantly higher compared

to the IV group. This can be viewed as a weak point of the

method. The study by Bennett et al. (1998) conducted in USA

investigated the effect of SC Midazolam with needle and sy-

ringe compared to the SC injection of this drug using jet in-

jector. The findings of the mentioned clinical trial conducted

on 14 children suggested that the discomfort caused by sub-

cutaneous Midazolam in the jet injector group was less com-

pared to the needle and syringe group though the difference

between the two was not significant. Finally, they concluded

that the peak plasma level was achieved more rapidly with jet

injector probably due to the distribution of the medicine in

the tissue by the jet injector (12). Our findings also suggested

that the parents were significantly more satisfied with jet in-

jector method. In the study by Bennett et al., the rate of dis-

comfort was smaller with jet injector, though the difference

was not significant due to small sample volume (14 samples)

or the study design (12). Overall, parents were more satisfied

with the jet injector method while physicians were less satis-

fied with this route. It appears that the child sustains less pain

and discomfort with the jet injector route causing more satis-

faction among the parents; nonetheless, physicians are more

satisfied with the IV method since the drug exerts its effect

more rapidly leading to faster sedation. However, our results

demonstrated that the physicians in the jet injector group as-

sessed child controlling and positioning of 23 (%76.6) chil-

dren as easy and very easy during the procedure. The same

was true with the IV group indicating another positive factor

in the jet injector method compared to the IV route. Consid-

ering the complications of Midazolam (hypoxia, respiratory

depression, apnea, coma, hypotension, agitation, confusion,

and cough), none of these undesirable side effects were man-

ifested in any child in this study. Moreover, no dermal reac-

tion like erythema, swelling, or inflammation was observed

in the site of injection, a finding which is consistent with the

results obtained by Bennett who reported no specific com-

plication in 14 adult patients who underwent SC Midazolam

injection with jet injector compared to subcutaneous needle

and syringe IV injection (12). Also, the results of the study by

Domino et al. (1998) showed that the SC injection of Midazo-

lam with jet injector was associated with appropriate effect

(16). It seems that SC injection using jet injector as a well-

known old method could be considered as an alternative root

for induction of sedation in pediatric non-invasive diagnos-

tic procedure. Considering the need that is felt for a pain-

less, safe, and rapid-acting method, jet injector as a needle-

less injection system can serve as an effective tool with little

complications to be used for inducing sedation, especially in

stressful situations like ED that demands more tranquility. It

is suggested that future studies investigate other aspects of

these two methods such as comparison of the resulted in-

fection or dermal complications in a longer time interval af-

ter injection. Different jet injectors may be applied for vari-

ous age groups or greater carpols may be used with jet injec-

tors. Additionally, jet injector may be explored for induction

of anesthesia or sedation in painful or invasive procedures.

A combination of the main drug with local anesthetics along

with their merits and demerits is also suggested.

5. Limitation

The children could not be made blind to the study due to the

nature of the use of jet injector. There was no placebo due to

ethical considerations to avoid pain in the children.

6. Conclusion

The findings indicate no significant difference in depth of se-

dation, control of child, in-charge physician satisfaction, suc-

cess rate of sedation (reaching stage 1 of sedation or higher),

and need for rescue dose between SC and IV midazolam. Par-

ents’ satisfaction was significantly greater with SC adminis-

tration and IV injection had shorter recovery time.

7. Appendix

7.1. Acknowledgements

The authors give their special thanks to all the staff in EDs of

Shahid Sadoughi and Shahid Rahnemoon Hospitals in Yazd

and also all the children and their parents. The manuscript

was extracted from a Medical Emergency Residency Thesis

by Vahid Ahmadi Hanzaei.

7.2. Authors’ contribution

All authors contributed to this project and article almost

equally. All authors read and approved the final manuscript.

7.3. Funding/Support

None.

7.4. Conflict of interest

All authors declare that they have no conflicts of interest.

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M. Hajimaghsoudi et al. 6

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	Introduction
	Methods
	Results
	Discussion
	Limitation
	Conclusion
	Appendix
	References