Archives of Academic Emergency Medicine. 2022; 10(1): e57

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

Effect of Interposed Abdominal Compression on Car-
diopulmonary Resuscitation Outcomes; a Randomized
Clinical Trial
Atefeh Ghanbari Khanghah1, Mohammad Taghi Moghadamnia2, Latif Panahi3∗, Somaye Pouy4, Marjan
Aghajani Nargesi5, Ehsan Kazemnezhad Leyli6

1. Professor, Social Determinants of Health Research Center (SDHRC), Department of Nursing and Midwifery (Medical- Surgical), Guilan
University of Medical Sciences, Rasht, Iran.

2. Department of Medical Surgical Nursing, School of Nursing and Midwifery, Guilan University of medical Sciences, Rasht, Iran.

3. Master Student of Emergency Nursing, School of Nursing and Midwifery, Guilan University of Medical Sciences, Rasht, Iran.

4. PhD Candidate in Nursing, School of Nursing and Midwifery, Guilan University of Medical Sciences, Rasht, Iran.

5. Clinical Research Development Unit of Razi Hospital, Department of Emergency Medicine, School of Medicine, Guilan University of
Medical Sciences, Rasht, Iran.

6. Associate professor, Department of Biostatistics, School of Nursing and Midwifery, Guilan University of Medical Sciences, Rasht, Iran.

Received: April 2022; Accepted: May 2022; Published online: 16 July 2022

Abstract: Introduction: Standard cardiopulmonary resuscitation (STD-CPR) is successful in only 10-15% of cases in emer-
gency department (ED). This study aimed to determine the effect of interposed abdominal compression (IAC)
during resuscitation on outcomes of ED cardiac arrests. Methods: In this randomized clinical trial study, non-
trauma patients aged 18-85 years, patients with in-hospital cardiac arrest hospitalized in the ED were randomly
assigned into two either STD-CPR or IAC-CPR group on a 1:1 basis and using computer-generated random num-
bers. Participants in the intervention group, received abdominal compression during the diastole phase of STD-
CPR. The rate of return of spontaneous circulation (ROSC), heart rate (HR), respiratory rate (RR), arterial blood
gas (ABG) indicators, and survival rate were compared between the two groups. Results: Ninety patients were
enrolled (45 in each group). There were no differences between the two groups regarding age (p = 0.76), sex (p
= 0.39), employment status (p = 0.62) and Charlson comorbidity scale (p = 0.46). Abdominal compression had
a positive effect on heart rate (p < 0.001), mean arterial pressure (p = 0.003), arterial blood oxygen pressure (p =
0.001), and arterial blood carbon dioxide pressure (p = 0.001) as well as a negative effect on arterial blood oxy-
gen saturation (p = 0.029) 30 minutes after resuscitation. Out of the 90 CPR cases, 8 (17.7%) cases in intervention
group and 8 (17.7%) cases in control group were successful, among which all of the 8 patients in the intervention
group and 5 of the patients in the control group had been discharged from hospital without any complications.
Conclusion: The results showed that abdominal compression during CPR can improve resuscitation outcomes
in patients with cardiac arrest. Therefore, in order to use this technique, further research is recommended.

Keywords: Heart Arrest; Cardiopulmonary Resuscitation; Treatment Outcome; Clinical trial

Cite this article as: Ghanbari Khanghah A, Moghadamnia MT, Panahi L, Pouy S, Aghajani Nargesi M, Kazemnezhad Leyli E. Effect of Inter-

posed Abdominal Compression on Cardiopulmonary Resuscitation Outcomes; a Randomized Clinical Trial . Arch Acad Emerg Med. 2022;

10(1): e57. https://doi.org/10.22037/aaem.v10i1.1678.

∗Corresponding Author: Latif Panahi; Master Student of Emergency Nurs-
ing, School of Nursing and Midwifery, Guilan University of Medical Sciences,
Rasht, Iran. Email: Latif_p2020@yahoo.com; Tel: +98 (922) 4833167, ORCID:
http://orcid.org/0000-0001-5157-2613.

1. Introduction

Sudden cardiac arrest is one of the main causes of death

around the world (1, 2). According to global statistics, in the

United States, about 350,700 adults over the age of 18 expe-

rience in-hospital cardiac arrest each year (3). Standard car-

diopulmonary resuscitation (STD-CPR) is one of the meth-

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A. Ghanbari Khanghah et al. 2

ods used to save the lives of these people. STD-CPR involves

applying pressure to the chest of a patient with cardiac arrest

and ventilation with an Ambu bag, which causes an increase

in the patient’s probability of survival before performing ad-

vanced life-saving procedures (4, 5). According to the latest

revision of the American Heart Association (AHA) Guidelines,

rapid and effective chest massage is a key component of STD-

CPR (6, 7). But chest massage is less successful in some pa-

tients and in certain conditions, such as patients with pneu-

mothorax or chest trauma, and other alternative methods

should be used (8, 9). According to conducted studies, it

has been found that although STD-CPR is widely used, the

survival rate of patients undergoing this method is not com-

pletely desirable (3). Also, based on a study in Iran, it has

been found that following STD-CPR, the mortality rate is over

90% and the discharge rate from hospital is less than 7% (10).

For reasons such as presence of an underlying disease, pa-

tient’s age, or delay in starting CPR, the final result of STD-

CPR may not be desirable. Therefore, it may be necessary

to use more effective and alternative methods for resuscita-

tion in some patients (10). Interposed abdominal compres-

sion CPR (IAC-CPR) is one of the methods that may be able to

make up for existing STD-CPR defects (11-13). Some clinical

studies have reported that using IAC-CPR for patients with

cardiopulmonary arrest is more effective than STD-CPR (8,

9, 14). On the other hand, a number of studies have shown

that there is no difference between these two techniques re-

garding patient consequences and conducting more research

is required (10, 15).

According to the AHA Guidelines for CPR and Emergency

Cardiovascular Care, IAC-CPR can be an effective method of

CPR when staff are adequately trained. The level of evidence

for IAC-CPR is divided as Class IIb13, which means that al-

though using this technique is not certainly recommended,

further research is suggested due to many benefits of IAC-

CPR (15). The current study has been conducted with the

purpose of determining the effect of interposed abdominal

compression on outcome of CPR for patients with cardiac ar-

rest in emergency department (ED).

2. Methods

2.1. Study design and setting

This is a two-group randomized clinical trial, which was con-

ducted from June 2021 to May 2022 on patients with cardiac

arrest, referring to Razi Hospital in Rasht, Iran. Before select-

ing patients to enter the study and due to the emergency na-

ture of CPR, the necessary explanations were given to the pa-

tient’s family members and informed consent was obtained.

All patients with cardiopulmonary arrest were transferred

to the resuscitation room of ED and all medical procedures

were performed for them in this room. Our data collection

was done in this room, too.

This research has been approved by the ethics commit-

tee of Guilan University of Medical Sciences (ethics code:

IR.GUMS.REC.1399.665) and it complies with the statements

of the Declaration of Helsinki. Also, the trial has been

registered in the Iranian Registry of Clinical Trials (code:

IRCT20080901001174N14).

2.2. Participants

All adult patients aged 18-85 years with in-hospital cardiac

arrest in ED were enrolled in this study. Inclusion criteria

were non-trauma patients hospitalized in the ED who had

in-hospital cardiac arrest in the presence of a nurse and their

cardiopulmonary arrest was confirmed by a doctor and the

presence of a resuscitation team including nurses, anesthe-

siologists, emergency medicine specialists, and the main re-

searcher after announcing CPR code. Exclusion criteria were

liver cirrhosis, abdominal surgery in the past two weeks,

active gastrointestinal bleeding based on nurse and physi-

cian’s explanations or report of patient’s family, history of

pulmonary embolism, abdominal aortic aneurysm, signifi-

cant abdominal ascites, abdominal cirrhosis, and a history

of coagulation disorders. Our eligibility criteria were defined

according to previous studies. It should be noted that our

methods did not change after initiation of trial. The patient

enrollment process is shown in figure 1. According to studies

by Reynolds and Zhou (16, 17) and considering the α = 0.05,

and power = 80% the sample size was calculated as 45 people

in each group.

2.3. Study protocol

Eligible patients were randomly assigned to either STD-CPR

or IAC-CPR group on a 1:1 basis. Randomization of patients

into two groups was done using a computer-generated ran-

dom allocation sequence. The co-researcher (S.P) enrolled

patients in the study and allocated patients to either group

according to the random allocation sequence. When a car-

diac arrest happened, a code (99) was announced and the re-

suscitation team was notified by pocket beeper. The resus-

citation team included two nurses, an anesthesiology nurse,

and an emergency medicine physician. All of patients un-

derwent resuscitation based on AHA2020 advanced cardiac

life support protocol. Chest compression was performed at a

rate of 100 times per minute at a depth of 5 cm and ventila-

tion rate was 8-10 times per minute. Cardiac arrest was con-

firmed by physician and endotracheal intubation was per-

formed as soon as possible. The intervention group received

STD-CPR plus IAC-CPR and the control group received STD-

CPR only. In patients who received IAC-CPR, abdominal

compression was performed with open hands, fused to-

gether in center of abdomen between the xiphoid and the

umbilicus during the relaxation phase of chest compression.

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3 Archives of Academic Emergency Medicine. 2022; 10(1): e57

Depth, rhythm, and rate of abdominal compressions were

similar to chest compressions and force on the abdomen

was maintained until the beginning of next chest compres-

sion. We used a bag-valve-mask apparatus attached to the

endotracheal tube and performed ventilation at a rate of 8-10

breaths/minute. Oxygen was delivered at 100% FiO2 in both

groups. During resuscitation, 1 mg of epinephrine was in-

jected intravenously every 3-5 minutes and other drugs were

injected as needed based on the AHA2020 guideline (such as

amiodarone or lidocaine, atropine, epinephrine) (6).

In compliance with AHA guidelines, termination of CPR

was considered with the appearance of an autonomous

Carotid pulse, moist facial complexion, the appearance of

autonomous respiration, and shrinking pupils and reappear-

ance of a light reflex, or the appearance of eyeball motion and

limb spasms (7). If after continued CPR for at least 30 min-

utes no Carotid pulse or autonomous breathing was noted,

CPR was terminated after obtaining informed consent from

family members.

All patients with successful CPR were followed for their 24-

hour survival. For evaluation of complications of IAC-CPR,

patients were followed for 24 hours and the presence of any

abdominal pain, tenderness in abdomen, and need for ab-

dominal surgery after CPR, which could be sings and symp-

tom of internal bleeding, were assessed in these patients.

Also, all patients in both groups were monitored and assessed

in terms of any complication such as rib fracture, arrythmia,

or post-resuscitation syndrome.

2.4. Data collection

Demographic (age, sex, body mass index (BMI), height, and

weight) and clinical (Charlson comorbidity Index, underly-

ing diseases) information of patients at the time of cardiac

arrest were recorded. The Charlson comorbidity Index (CCI)

was used to examine the presence of comorbidities in pa-

tients. The CCI assesses 19 diseases and conditions, and rates

the probability of the patient’s mortality based on them. The

scores obtained from CCI can be adjusted with age, so that

each decade of age (starting from the age of 50) is considered

as an additional score. Scores range from zero to 37 in case of

age mismatch and from zero to 43 in case of age match.

Finally, the scores are ranked as four degrees of illness: zero,

1-2, 3-4 and 5, where a higher score indicates the presence of

more comorbidities (18).

Primary outcome measured in this study was return of spon-

taneous circulation (ROSC). ROSC was defined as the pres-

ence of a palpable carotid arterial pulse and a systolic blood

pressure above 80 mmHg for longer than 3 minutes.

Secondary outcomes were heart rate (HR), respiratory rate

(RR), mean arterial pressure (MAP), peripheral capillary oxy-

gen saturation (SPO2), partial pressure of carbon dioxide

(PaCO2) and potential of hydrogen (pH) of arterial blood gas

(ABG). All of the outcomes were measured in the interven-

tion and control groups immediately and half an hour after

the start of CPR.

The presence of ROSC was assessed based on the Carotid

pulse. The PaCO2, pH, and SPO2 were measured via ABG

test. For ABG test, one of co-researcher (S.P) took an arterial

blood sample and sent it to laboratory department of hospi-

tal as soon as possible and they used MEDICA Easy Blood Gas

analyzer for ABG analysis.

For calculating MAP of patients, we measured systolic and

diastolic blood pressures of patients with a cuff that was at-

tached to a monitor. Then it was estimated using a formula

in which the diastolic blood pressure is doubled and added

to the systolic blood pressure and that composite sum is then

divided by 3 (19).

The heart rate and respiratory rate were measured by the

monitoring device. It should be mentioned that all of the pa-

tients who received CPR, in either group, were monitored us-

ing OMNICARE monitoring device. Before starting the study,

monitoring and MEDICA Easy Blood Gas analyzer devices

had been calibrated and approved by the medical engineer-

ing team of hospital.

In addition, during CPR in both groups, the emergency

medicine physician was present and in case of any problems

such as presence of any signs of internal bleeding, abdominal

pain or tenderness, organ injury or rib fracture, he immedi-

ately examined the patient and requested emergency surgi-

cal counseling. Also, we followed survived patients after CPR

and assessed the survival to hospital discharge in order to as-

sess the long-term survival of patients with successful CPR in

each group. All of the primary and secondary outcomes were

measured and recorded by one of the co-researchers (S.P).

2.5. Data analysis

After entering data in the Statistical Package for the Social

Sciences (SPSS) software (version 25.0, Armonk, NY: IBM-

Corp.), data analysis was performed using descriptive statis-

tics (mean, standard deviation, frequency) and inferential

tests (Independent t test, Chi-Square). The significance level

of the tests was considered less than 0.05.

3. Results

3.1. Baseline characteristics

Initially, 105 patients with cardiac arrest were assessed for eli-

gibility in the study. Finally, 90 cardiac arrest victims were en-

rolled (50 male and 40 female) and allocated into IAC-CPR or

STD-CPR (each group 45 patients) during the period of June

2021 to May 2022. Out of the 90 cases, 74 (82.22%) of CPR

attempts was unsuccessful and only 8 (17.77%) cases in each

group had successful resuscitation (a total of 16 patients).

The mean age of the patients in control and intervention

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A. Ghanbari Khanghah et al. 4

Figure 1: Patients’ enrollment and allocation.

groups were 40.60±16.80 and 60.04±14.97 years, respectively

(Range=19-72 years; p = 0.76). The most common cause of

cardiopulmonary arrest in both groups were cardiac, cere-

brovascular accident (CVA), and respiratory reasons. In-

hospital complications in both groups included: bruising

and abrasions in the face and neck, airway injuries, rib frac-

ture, sternal fracture, and pneumothoraxes. There were not

any significant differences between the two groups regard-

ing cause of cardiopulmonary arrest or in-hospital compli-

cations.

The most common underlying diseases in both groups were

hypertension (32.22%), diabetes (16.66%), and CVA (14.44%).

There were not significant differences between the groups re-

garding underlying disease. Sex distribution was not differ-

ent between the two groups (p = 0.396). BMI was not differ-

ent between the two groups (p = 0.432). CCI was not different

between the two groups (p = 0.463). Table 1 compares demo-

graphic and clinical characteristics between the two groups.

3.2. Outcomes

3.2.1. ROSC
The number of patients who had ROSC immediately after

the start of resuscitation was zero in both groups (p = 0.999).

Comparison of ROSC from immediately to half an hour after

the start of resuscitation had a significant increase in both

the intervention group (p < 0.001) and the control group (p <

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5 Archives of Academic Emergency Medicine. 2022; 10(1): e57

Table 1: Comparing the baseline characteristics of patients between the two studied groups

Variable STD-CPR (n=45) IAC-CPR (n=45) P-Value
Age (year) 40.60±16.80 60.04±14.97 0.916 *
BMI (Kg/m2) 25.2± 4.1 25.8± 3.6 0.432*
Height (cm) 167.01±5.1 166.12±6.2 0.674*
Weight (Kg) 71.1±9.2 72.03±8.9 0.712*
Charlson Comorbidity Scale 3.13±2.25 3.49±2.35 0.463*
Sex
Male 27 (60.0) 23 (51.11) 0.396**
Female 18 (40.0) 22 (48.88)
Cause of cardiopulmonary arrest
Cardiac 24 (53.33) 20 (53.33) 0.912*
Cerebrovascular accident 6 (13.33) 8 (17.77) 0.916*
Respiratory 5 (11.11) 6 (13.33) 0.891*
Renal 4 (8.88) 5 (11.11) 0.456*
Cancer 3 (6.66) 3 (6.66) 0.876*
Bleeding 2 (4.44) 3 (6.66) 0.897*
Infection 1 (2.22) 0 (0.00) 0.345*
In-hospital complications
Bruising and abrasions in face/neck 16 (35.55) 15 (33.33) 0.786*
Airway injuries 12 (26.66) 9 (22.22) 0.567*
Rib fracture 8 (17.77) 7 (15.55) 0.862*
Sternal fracture 3 (6.66) 2 (4.44) 0.457*
Pneumothoraxes 2 (4.44) 1 (2.22) 0.347*
Underlying disease
Hypertension 15 (33.33) 14 (31.11) 0.456**
Cancer 7 (15.55) 8 (17.77) 0.678**
Diabetes 7 (15.55) 6 (13.33) 0.377**
MI 4 (8.88) 4 (8.88) 0.321**
COPD 4 (8.88) 4 (8.88) 0.561**
Renal failure 3 (6.66) 4 (8.88) 0.423**
Hepatitis 2 (4.44) 2 (4.44) 0.345**
CVA 2 (4.44) 3 (6.66) 0.423**
Asthma 1 (2.22) 0 (0.00) 0.781**
Data are presented as mean ± standard deviation or frequency (%). CPR: cardiopulmonary resuscitation; STD-CPR= standard CPR;
IAC-CPR= interposed abdominal compression CPR; BMI= body mass index; COPD = chronic obstructive pulmonary disease;
CVA = cerebral vascular accident; MI = myocardial infarction. * Independent t test. ** Chi-Square

0.001) and in both groups, 8 patients (17.77%) had ROSC (Ta-

ble 2).

3.2.2. Vital signs
After CPR, almost all patients in both groups had heart rate

and MAP, but fewer patients in both groups had respiratory

rate. Patients in the IAC-CPR group had higher heart rate and

lower MAP compared to the STD-CPR group. The two groups

had the same mean respiratory rate immediately (P = 0.611)

and half an hour (P = 0.476) after CPR. Although the respira-

tory rate in the IAC-CPR group increased slightly more than

the STD-CPR group, and the rate of increase was 0.31 ± 1.06

in the STD-CPR group and 0.76± 33.40 in the IAC-CPR group,

the difference was not statistically significant (Table 2).

3.2.3. Change of Blood Gas Measurements
There was no significant difference in SPO2 between con-

trol and intervention groups immediately (p = 0.887) and also

half an hour (p = 0.292) after the start of CPR, but there was

a significant increase in SPO2 between these two times in

both control (p < 0.001) and intervention (p < 0.001) groups.

This increase was more in IAC-CPR in comparison to STD-

CPR group. The mean PaO2 was not significantly different

between the two groups immediately after the start of CPR,

but it was significantly different half an hour after the start of

CPR. The rate of change in the control group was not signif-

icant for this variable from immediately to half an hour af-

ter CPR, but there was a significant increase in the interven-

tion group (p <0.001). This increase was more in IAC-CPR in

comparison to STD-CPR group. Arterial blood pH was not

significantly different between the two groups immediately

after the start of CPR, but it was significantly different half

an hour after the start of CPR (P <0.001). Both groups had a

significant decrease in pH from immediately to half an hour

after the start of CPR (P <0.001), but the rate of decrease in

arterial blood pH in the intervention group was greater than

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Table 2: Comparing the vital signs and arterial blood gas parameters between the two groups at baseline and 30 minutes after CPR

Variable STD-CPR (n=45) IAC-CPR (n=45) P-Value Effect size
Heart Rate (beat/minute)
Baseline 65.31±19.40 98.42±14.86 < 0.001
30 minutes after CPR 60.69±20.82 99.58±18.93 < 0.001 0.094
Change from baseline -4.62±7.11 1.16±10.65 0.010
Respiratory Rate
Baseline 3.58±7.82 4.47±8.51 0.611
30 minutes after CPR 3.89±8.49 5.22±9.30 0.476 0.008
Change from baseline 0.31±1.06 0.76±3.40 0.959
MAP
Baseline 51.04±11.61 65.60±8.17 < 0.001
30 minutes after CPR 48.24±10.41 63.87±8.56 < 0.001 0.009
Change from baseline - 2.80±5.81 - 1.73± 5.49 0.641
pH
Baseline 7.27±0.09 7.24±0.08 0.102
30 minutes after CPR 7.16±0.10 7/00±0.47 <0.001 0.037
Change from baseline - 0.11±0.06 -0.24± 0.47 <0.001
SPO2
Baseline 68.34±16.71 66.45±19.18 0.878
30 minutes after CPR 71.69±15.93 76.89±17.79 0.292 0.361
Change from baseline 13.35±4.29 14.44±3.62 <0.001
PaO2
Baseline 55.76±38.91 55.43±25.65 0.373
30 minutes after CPR 59.21±38.92 68.71±26.16 0.002 0.361
Change from baseline 3.45±7.52 13.28±3.45 <0.001
PaCO2
Baseline 51.33±13.84 56.02± 10.99 0.106
30 minutes after CPR 51.33±13.21 51.80±10.96 0.932 0.383
Change from baseline - 0.01±2.85 - 4.22± 2.50 <0.001
Data are presented as mean ±standard deviation; CPR: cardiopulmonary resuscitation; STD-CPR= standard CPR;
IAC-CPR= interposed abdominal compression CPR; MAP=Mean arterial pressure; PH= potential of hydrogen;
SPO2= Peripheral capillary oxygen saturation; PaO2= partial pressure of oxygen; PaCO2= partial pressure of carbon dioxide.

the control group. The mean PaCO2 immediately after the

start of CPR (P = 0.106) and half an hour after that (P = 0.932)

was not significantly different between the two groups, but

the changes in PaCO2 in the intervention group were greater

than the control group (P <0.001). (Table.2)

3.2.4. Long-term outcomes
After successful CPR, we followed survived patients (8 cases

in intervention and 8 cases in control group) and all of the

8 patients in IAC-CPR and 5 of the patients in STD-CPR had

long-term survival and were discharged from hospital with-

out any complications such as dysrhythmia or CPR-related

side effects, including fracture or internal bleeding.

4. Discussion

The quality of CPR, as assessed by appropriate cardiac out-

put, is often low and less than desirable level (20). The

amount of cardiac output after a desired STD-CPR is usually

more than 30% of the normal cardiac output, and coronary

blood flow during CPR is often less than 35% of the normal

coronary blood flow, because of different reasons (21). So, it

is recommended to use alternative methods for CPR such as

IAC-CPR.

The results of the current study showed that IAC-CPR can

improve CPR-related outcomes in patients with cardiopul-

monary arrest. Also, significant changes in arterial blood

gas levels were observed in both groups and these outcomes

were not affected by age, sex, and BMI.

According to the results of the current study, no difference

was found between the two groups regarding the number of

people who had ROSC, and in both groups, 8 people had

ROSC half an hour after the start of resuscitation. Based

on the study by Movahedi et al., which was conducted for

comparing the effect of STD-CPR and IAC-CPR on ROSC

and the amount of end-expiratory carbon dioxide in patients

with in-hospital cardiopulmonary arrest, the results showed

that ROSC levels were significantly different between the two

groups (10), which is not consistent with the present study.

Also, in the study by Mateer et al., there was no significant dif-

ference in terms of ROSC between the two groups (22), which

is consistent with the current study.

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7 Archives of Academic Emergency Medicine. 2022; 10(1): e57

In terms of respiratory rate, although its increase among pa-

tients in the intervention group was slightly greater than the

control group, but they were not statistically significant. In

the study by Zhang et al., no significant difference was re-

ported between the two groups (11), which is consistent with

the findings of the present study. Also, in the study by Wang

et al., it was found that IAC-CPR increased the number of RR

in patients with cardiopulmonary arrest (23), which is in line

with the findings of the present study. Considering that the

RR in the intervention group increased more than the control

group, it can be argued that in the IAC-CPR method, applying

intermittent pressure on the abdomen causes the diaphragm

to move up and down, and the pressure in the chest changes,

thus facilitating the entry and exit of air into the lungs. In

this method, intermittent abdominal massage causes the di-

aphragm to move downward, allowing the lungs to expand,

and the upward movement of the diaphragm also causes air

to drain from the lungs.

In terms of MAP, both groups had significant changes and

these changes in the control group had a more decreasing

course than the intervention group. However, this difference

in decrease between the two groups was not statistically sig-

nificant (P = 0.641). In the study by Zhang et al., all patients

and in both groups, MAP changes were negative, i.e., due

to performing CPR in both groups, the amount of MAP was

increased, but patients in the intervention group had lower

MAP compared to the control group (p = 0.003), which is con-

sistent with the findings of the current study. Also, accord-

ing to a study by Gu et al., all patients had MAP after CPR

in both intervention and control groups, but the amount of

MAP in the intervention group was not different from the

control group (23), which are inconsistent with the findings

of the present study. To justify this finding, it can be argued

that applying abdominal pressure in the intervention group

increased blood circulation and blood pressure, and as a re-

sult, the amount of MAP in the intervention group decreased

less than the control group.

In terms of SPO2 rate, there was no significant difference be-

tween the two groups immediately (P = 0.887) and also half

an hour after (P = 0.292) the start of resuscitation, but the

rate of change between these two times in the two groups was

statistically significant and the control group had a higher in-

crease in SPO2 than the intervention group. In Zhang et al.’s

study, it was found that the level of SPO2 after STD-CPR in-

creased more than IAC-CPR (11), which is in line with the re-

sults of the present study.

In terms of PaO2 levels, there was no significant difference

between the two groups immediately after the start of CPR,

but there was a significant difference at half an hour after the

start of CPR. The changes of PaO2 in the control group from

immediately to half an hour after CPR was not significant,

but in the intervention group it had significantly increased (P

<0.001). In the study by Zhang et al. it was found that PaO2

levels increased half an hour after IAC-CPR (from 45.15 to

60.68), but no change was reported in the STD-CPR method

and the change in the intervention group was significant (11),

which is consistent with the findings of the present study. In

justifying this finding, it can be argued that by applying ab-

dominal pressure in the intervention group, the rate of gen-

eral and pulmonary circulation increased and, therefore, it

caused a greater increase in arterial blood oxygen pressure in

the intervention group compared to the control group.

In terms of arterial blood pH immediately after CPR, there

was no significant difference between the two groups (P =

0.102), but the difference was significant half an hour after

the start of CPR (P <0.001) and both groups had a significant

decrease and the rate of decrease was greater in the inter-

vention group. According to the study by Zhang et al., the

pH level in both intervention and control groups had de-

creased after CPR and this decrease was more in the inter-

vention group (P = 0.037). Also, in this study, the intervention

group’s pH (7.06) was lower than the control group (11); the

findings of the current study are in line with their findings.

To justify this finding, it can be argued that applying abdom-

inal pressure in the resting phase of chest massage improves

perfusion and blood flow to the heart muscle and increases

cardiac output; therefore, by increasing cardiac output and

blood flow to tissues, the amount of arterial blood CO2 de-

creased, so the decrease in PaCO2 was compensated by the

decrease in serum bicarbonate, as a result, arterial blood pH

in the intervention group decreased more than the control

group.

In terms of PaCO2, it was found that there was no significant

difference between the two groups immediately (P = 0.106)

and half an hour (P = 0.932) after the start of CPR. In the con-

trol group, the change in PaCO2 from immediately to half an

hour after the start of CPR was not statistically significant (P

= 0.199), but in the intervention group it was significant and

more than the control group (P <0.001). According to the

study by Zhang et al., the rate of PaCO2 had significantly re-

duced in the intervention group after CPR, while this param-

eter had not changed in the control group (P = 0.009) (11),

which is in line with the findings of the current study.

Finally, all of the 8 patients who had survived after IAC-

CPR had been discharged from hospital, but in the STD-CPR

group, only 5 out of the 8 patients had been discharged from

hospital.

5. Strength and Limitations

So far, very few studies in this field have been done in Iran

and doing this study was one of our strengths. Also, our study

had some limitations. Firstly, since this study has been con-

ducted on a limited number of samples, in order to generalize

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A. Ghanbari Khanghah et al. 8

its results, it is necessary to conduct more studies in various

centers and on a larger number of patients with cardiopul-

monary arrest. Secondly, no neurological assessment of sur-

vived patients had been done.

6. Conclusion

The findings of the current study show that IAC-CPR has had

a positive effect on CPR-related outcomes. So in this regard,

it is recommended to conduct more extensive research and

on a larger sample size to increase the generalizability of the

present findings and include this technique in CPR guide-

lines in the future.

7. Declarations

7.1. Acknowledgments

This study is a part of a MSc dissertation in emergency nurs-

ing and all authors are very thankful to nurses, physicians,

patients, and all those who helped us in this research.

7.2. Authors’ contributions

A. Gh: Design of study, supervision of research process, data

analysis, preparing final manuscript.

M.M: Design of study, supervision of research process, data

analysis, preparing final manuscript.

L.P: Design of study, data collection, data analysis, preparing

final manuscript.

S.P: Design of study, data collection, data analysis, preparing

final manuscript.

M.AG: Design of study, data collection, preparing final

manuscript.

E.KL: Design of study, data analysis, preparing final

manuscript.

7.3. Funding and supports

None.

7.4. Conflict of interest

There are no conflicts of interest in this study.

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Downloaded from: http://journals.sbmu.ac.ir/aaem


	Introduction
	Methods
	Results
	Discussion
	Strength and Limitations 
	Conclusion 
	Declarations
	References