Archives of Academic Emergency Medicine. 2023; 11(1): e41

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

Using Sodium Bicarbonate During Prolonged Cardiopul-
monary Resuscitation in Prehospital Setting; a Retrospec-
tive Cross-sectional Study
Thongpitak Huabbangyang1, Chunlanee Sangketchon1∗, Gotchagorn Noimo2, Korawee Pinthong2, Ketvipa
Saungun2, Kaiwit Bunta2, Chomkamol Saumok3

1. Department of Disaster and Emergency Medical Operation, Faculty of Science and Health Technology, Navamindradhiraj University,
Bangkok, Thailand.

2. Faculty of Medicine Vajira Hospital, Navamindradhiraj University, Bangkok, Thailand.

3. Division of Emergency Medical Service and Disaster, Faculty of Medicine Vajira Hospital, Navamindradhiraj University, Bangkok, Thailand.

Received: March 2023; Accepted: April 2023; Published online: 25 May 2023

Abstract: Introduction: Although the 2020 American Heart Association (AHA) guidelines recommend that sodium bicarbonate
(SB) be avoided during routine cardiopulmonary resuscitation (CPR) a limited number of studies have examined the
effects of SB injection during prolonged CPR (>15 min) in prehospital setting. The present study aimed to examine
the effects of prehospital SB use during prolonged CPR on patients’ outcome. Methods: In this retrospective cross-
sectional study adult patients aged >18 years who experienced a non-traumatic, out-of-hospital cardiac arrest (OHCA)
were compared regarding three outcomes, namely return of spontaneous circulation (ROSC), ROSC > 20 minute, and
survival to discharge, based on receiving or not-receiving SB during CPR. Results: 330 patients were divided into two
equal groups of 165. The two groups had similar conditions regarding gender distribution (p = 0.729); mean age (p =
0.741); underlying diseases (p = 0.027); etiology of arrest (p = 0.135); the initial rhythm (p = 0.324); receiving normal
saline solution (p = 1.000), epinephrine (p = 0.848), and atropine during CPR (p = 0.054); and using defibrillation (p =
0.324). Those who received SB had 0.80 times greater likelihood for sustained ROSC (adjusted odds ratio (OR) = 0.80,
95% CI: 0.47–1.37, p = 0.415), 0.93 times greater likelihood for ROSC at the scene (adjusted OR = 0.93, 95% CI: 0.55–1.59,
p = 0.798), and 0.34 times greater likelihood for survival to discharge (adjusted OR = 0.34, 95% CI: 0.10–1.17, p = 0.087).
Conclusion: The present study demonstrated that prehospital SB use by EMS during prolonged CPR did not improve
ROSC rate at the scene, sustained ROSC, and survival to discharge.

Keywords: Cardiopulmonary resuscitation; emergency medical services; treatment outcome; out-of-hospital cardiac arrest;
sodium bicarbonate

Cite this article as: Huabbangyang T, Sangketchon C, Noimo G, Pinthong K, Saungun K, Bunta K, Saumok C. Using Sodium Bicarbonate

During Prolonged Cardiopulmonary Resuscitation in Prehospital Setting; a Retrospective Cross-sectional Study. Arch Acad Emerg Med. 2023;

11(1): e41. https://doi.org/10.22037/aaem.v11i1.2002.

1. Introduction

Sodium bicarbonate (SB) is the primary medication used as

buffer therapy during cardiac arrest. Previous researchers hy-

pothesized that SB therapy corrected metabolic acidosis and

could improve outcomes in cardiac arrest (1). During car-

diac arrest, an imbalance in oxygen exchange occurs in the

∗Corresponding Author: Chunlanee Sangketchon; Department of Disas-
ter and Emergency Medical Operation, Faculty of Science and Health Tech-
nology, Navamindradhiraj University, Bangkok 10400, Thailand. Tel: +66
2-244-3000, Email: chunlanee@nmu.ac.th, ORCID: https://orcid.org/0000-
0003-4509-1527.

body, resulting in acidosis (2). Observational studies on in-

tensive care units reported that over 95% of cardiac arrest

patients exhibited acidosis after return of spontaneous cir-

culation (ROSC), especially those receiving prolonged car-

diopulmonary resuscitation (CPR) (3). Moreover, available

evidence suggests that low blood pH or acidosis after ROSC

significantly increased mortality rates in hospitals. Similarly,

one study showed that every 0.1-unit increase in pH from pH

<7.2 promoted an increase in the likelihood of survival to dis-

charge (4). SB has been widely used not only in context of in-

hospital medical services but also in prehospital emergency

medical services (EMS).

A study found that SB use during CPR by EMS significantly

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T. Huabbangyang et al. 2

improved the outcomes of ROSC (5). But, one study found

that SB use was not associated with improved outcomes

of ROSC or increased rates of survival to discharge in car-

diac arrest patients. In fact, mortality increased significantly,

with several side effects of SB use having been noted dur-

ing CPR, which included hypernatremia, alkalosis, and ex-

cess carbon dioxide production (6). A prospective random-

ized controlled trial (RCT) comparing out-of-hospital cardiac

arrest (OHCA) patients treated with and without SB found

that SB administration was not associated with the likelihood

of favorable functional 30-day outcomes (7). Therefore, the

2010, 2015, and 2020 American Heart Association guidelines

for advanced cardiac life support do not recommend rou-

tine use of SB during CPR in cardiac arrest patients except

in the presence of certain indications, namely pre-existing

metabolic acidosis, hyperkalemia, and tricyclic antidepres-

sant intoxication (8-10). Previously studies had vigorously

attempted to prove the efficacy of SB. One RCT demonstrat-

ing the benefit of SB use in cardiac arrest patients requiring

prolonged CPR (>15 min) found that SB use was significantly

associated with increased ROSC rates (11). Present knowl-

edge has suggested that prolonged CPR results in just a <1%

or no chance for ROSC, survival to discharge, and favorable

outcomes (12). As such, prolonged resuscitation can trigger

anxiety among health care personnel, including prehospital

emergency medical staff, and has been associated with many

factors. One previous study found that bystander CPR and

initial shockable rhythm might be important factors causing

prolonged CPR in cardiac arrest patients, particularly pre-

hospitally (13).

Prevailing knowledge suggests that buffer therapy with SB

by EMS can be an option for treating OHCA patients requir-

ing prolonged CPR. However, such circumstances have some

limitations, that is, blood gas testing cannot be performed

and there is a current paucity in human studies examining

the effects of SB in cases requiring prolonged CPR. No clear

and concrete guidelines on rational SB use in OHCA patients

have been established, and empirical evidence supporting

the prehospital use of SB has been lacking and there are lim-

ited resources and emergency medical staff.

Hence, the present study aimed to examine the effects of pre-

hospital SB use during prolonged CPR (for >15 min) on sus-

tained ROSC (>20 min), ROSC at the scene, and survival to

discharge.

2. Methods

2.1. Study design and setting

This retrospective cross-sectional study was conducted at

Vajira Emergency Medical Service (V-EMS), Vajira Hospital,

Navamindradhiraj University, Bangkok, Thailand. Patients

with OHCA, who underwent CPR were compared regarding

ROSC, ROSC > 20 minute, and survival to discharge, based

on receiving or not-receiving SB during CPR.

V-EMS is primarily responsible for providing EMS to zone

area one among a total of nine zone areas within Bangkok

and is dispatched by Erawan Center, Bangkok, which main-

tains a network of six public and private hospitals within the

50 km2 area of responsibility with a population of 500,000

(14, 15). When responding to OHCA patients in need of EMS,

V-EMS dispatches one team at a time, which includes at least

three staff comprising paramedics or emergency nurse prac-

titioners (ENPs) as the operation team leader and emergency

medical technicians. During each operation, paramedics or

ENPs would follow off-line and on-line medical protocols un-

der the emergency physicians’ orders. In cases involving car-

diac arrest patients within the area, the 2020 American Heart

Association (AHA) guidelines were applied by paramedics or

ENPs. Everyone passed advanced cardiovascular life support

training (10).

This study was conducted in accordance with the tenets

of the Declaration of Helsinki 1975 and its later revisions.

Our study protocol was approved by the Institutional Review

Board of the Faculty of Medicine, Vajira Hospital, Navamin-

dradhiraj University (COA no. 216/2565). The requirement

for informed consent was waived due to the retrospective na-

ture of our study and anonymity of all patient data.

2.2. Participants

Data of adult OHCA patients aged >18 years were collected

from EMS patient care reports coded as symptom group 6

(cardiac arrest) based on the Thailand Emergency Medical

Triage Protocol and Criteria-Based Dispatch (CBD) from 1

January 2019 to 31 December 2020 (2 years). OHCA patients

to whom the V-EMS unit was dispatched were selected using

simple random sampling. These reports were completed by

the V-EMS unit.

Patients who had ROSC within 15 min, had incomplete or

missing data, were evaluated as dead by a team leader and re-

quired no resuscitation, had a do-not-resuscitate order, had a

cardiac arrest outdoors, had suffered an OHCA during trans-

fer, in which CPR was started at the scene and continued dur-

ing transfer to the hospital, and had termination of resuscita-

tion at the scene were excluded from the study.

2.3. Data gathering

Data of OHCA patients were collected from EMS patient

reports, a standard form recording advanced EMS proce-

dures performed by Bangkok EMS (Erawan Center), with

the Bangkok Advanced Emergency Operation Unit utilizing a

similar form. In particular, this form contained data on EMS

operation units, patients, and all treatments performed by

EMS teams, including dispatchers and paramedics or ENPs

operating at the scene. These data were required to deter-

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3 Archives of Academic Emergency Medicine. 2023; 11(1): e41

mine the remuneration of EMS operation units. Data on sur-

vival to discharge were extracted from the electronic medi-

cal records (EMR) at Vajira Hospital. All data were collected

and entered into a Microsoft Excel spreadsheet. Data ob-

tained from the electronic medical records comprised: 1) the

general characteristics of OHCA patients including gender,

age, underlying disease, location type, cause of cardiac arrest,

witnessed collapse, bystander CPR, initial rhythm, defibril-

lation, advanced airway, prehospital intravenous (IV ) fluids,

medication during CPR, total CPR time (min), time from CPR

to SB (min), and SB amount (mEq/mL), and 2) study out-

comes including sustained ROSC (>20 min), ROSC, and sur-

vival to discharge. Patients were followed up every 30 days

by a principal investigator (TH) to determine the survival to

discharge outcomes. In-hospital outcomes were determined

from the EMR of Vajira Hospital.

2.4. Definitions

- ROSC indicates a return of circulation wherein the heart is

able to sufficiently pump blood throughout the body, which

can be characterized by a palpable pulse and measurable

blood pressure at the scene (1, 15).

- Sustained ROSC (>20 min) indicates a return of circulation

wherein the heart is able to sufficiently pump blood through-

out the body, which can be characterized by a palpable pulse

and measurable blood pressure at the scene that continued

for 20 min (1).

- Survival to discharge indicates the patient’s status after 30

days starting from the first day the patient suffered an OHCA

(1).

- Symptom group 6 indicates OHCA according to the emer-

gency level screening system, which can be classified as CBD

6, severity level–critical (Red) 6 critical 1 or 6 Red 1, indicating

cardiac arrest including unconsciousness, apnea, or pulse-

lessness (15).

- Total CPR time (min) indicates the duration from the first

medical contact (FMC) to the end of CPR determined from

the EMS patient care report.

- Time from CPR to SB (min) indicates the duration from the

FMC to SB injection among OHCA patients determined from

the EMS patient care report.

- Witnessed collapse or witnessed arrest means cardiac arrest

with witness, which probably is layperson or medical person-

nel witnessing the event during a patient having sudden car-

diac collapse (10).

2.5. Outcomes measurement

The primary outcome was effects of prehospital SB use dur-

ing prolonged CPR on sustained return of spontaneous cir-

culation (ROSC) (>20 min) at the scene, and the secondary

outcome was survival to discharge.

2.6. Statistical analysis

We estimated the sample size needed to test two indepen-

dent proportions (16). Sample size calculation was based on

statistical data presented in a previous study by Weng et al.

(1), who reported sustained ROSC (>20 min) rates of 6.7% (p1

= 0.067) and 19.4% (p2 = 0.194) for those with and without

prehospital SB administration during CPR, respectively. As-

suming a 1:1 ratio in the sample size of the compared groups,

our sample size calculation determined that at least 147 pa-

tients per group were needed. After adding 10% of the sample

size using the formula nnew = 147/(1–0.1), we determined

that at least 163 patients per group were required. Therefore,

the final sample size consisted of 165 patients per group or a

total of 330 patients.

Descriptive analysis was performed to determine the distri-

bution of variables. Continuous variables are presented as

mean ± standard deviation (SD), whereas categorical vari-

ables are presented as frequencies and proportions. Differ-

ences between the two studied groups were evaluated using

the independent t-test or Mann–Whitney U test for numeric

variables and the chi-square test or Fisher’s exact test for cat-

egorical variables.

To compare the groups with and without prehospital SB ad-

ministration during CPR, the chi-squared test or Fisher’s ex-

act test were used depending on the appropriateness of data.

Multivariate analysis using multiple logistic regression was

used to determine the effects of prehospital SB use during

prolonged CPR on sustained ROSC, ROSC at the scene, and

survival to discharge, reporting the odds ratios (OR) and 95%

confidence intervals for the same.

IBM SPSS Statistics for Windows version 28.0 (Armonk, NY,

USA: IBM Corp.) was used for all statistical analyses, with a P

value of ≤.05 indicating statistical significance.

3. Results

3.1. Baseline characteristics of studied cases

330 patients with OHCA were divided into two groups based

on prehospital SB use (165 patients each). The mean time

from CPR to SB was 18.92 ± 7.51 minutes and the mean

amount of SB was 54.48 ± 18.72 meq/ml.

Table 1 compares the baseline characteristics of studied

cases between the two groups. The two groups had similar

conditions regarding gender distribution (p = 0.729); mean

age (p = 0.741); underlying diseases (p = 0.027); etiology of

arrest (p = 0.135); the initial rhythm (p = 0.324); receiving nor-

mal saline solution (p = 1.000), epinephrine (p = 0.848), and

atropine during CPR (p = 0.054); and using defibrillation (p =

0.324).

53.3% and 41.8% had witnesses arrest (p = 0.036), and 55.2%

and 35.2% obtained bystander CPR, in the SB and non-SB

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T. Huabbangyang et al. 4

Table 1: Comparing the baseline characteristics of patients with out of hospital cardia arrest (OHCA) based on receiving or not receiving

sodium bicarbonate (SB)

Characteristic Total (n = 330) P value
SB (n = 165) Non-SB(n=165)

Gender
Male 106 (64.2) 109 (66.1) 0.729
Female 59 (35.8) 56 (33.9)
Age (year)
Mean ± SD 64.44 ± 17.88 65.08 ± 17.68 0.741
Underlying disease
No 65 (39.4) 85 (51.5) 0.027
Yes 100 (60.6) 80 (48.5)
Location of cardiac arrest
Non-public 131 (79.4) 133 (80.6) 0.783
Public 34 (20.6) 32 (19.4)
Cause of cardiac arrest
Presumed cardiac etiology 128 (77.6) 134 (81.2)
Respiratory 33 (20.0) 21 (12.7)
AOC 1 (0.6) 5 (3.0)
Hypoglycemia 3 (1.8) 2 (1.2) 0.135
Seizure 0 (0.0) 1 (0.6)
UGIB 0 (0.0) 1 (0.6)
Unknown 0 (0.0) 1 (0.6)
Witnessed arrest
No 77 (46.7) 96 (58.2) 0.036
Yes 88 (53.3) 69 (41.8)
Bystander CPR
No 74 (44.8) 107 (64.8) <0.001
Yes 91 (55.2) 58 (35.2)
Initial rhythm
Asystole 111 (67.3) 122 (73.9)
Ventricular fibrillation 27 (16.4) 25 (15.2) 0.324
PEA 25 (15.2) 18 (10.9)
Pulseless VT 2 (1.2) 0 (0.0)
Defibrillation
No 121 (73.3) 139 (84.2) 0.015
Yes 44 (26.7) 26 (15.8)
Advanced airway management
ETT 144 (87.3) 107 (64.8) <0.001
BVM 11 (6.7) 54 (32.7)
LMA 10 (6.1) 4 (2.4)
Prehospital IV fluid
NSS 161 (97.6) 161 (97.6) 1.000
RLS 3 (1.8) 3 (1.8)
Acetar 1 (0.6) 1 (0.6)
Medication during CPR
Epinephrine 165 (100) 165 (100.0) NA
Amiodarone 16 (9.7) 14 (8.5) 0.848
Atropine 8 (4.8) 2 (1.2) 0.054
Calcium gluconate 63 (38.2) 9 (5.5) <0.001
Glucose 23 (13.9) 8 (4.8) 0.005
Total CPR time (minute)
Mean ±SD 33.81 ± 13.25 25.08 ± 12.40 <0.001
Data are presented as mean ± standard deviation (SD) or frequency (%). NA: data not applicable; PEA: pulseless electrical
activity; VT: ventricular tachycardia; ETT: endotracheal tube; BVM: bag valve mask; LMA: laryngeal mask airway;
AOC: alteration of consciousness; CPR: cardiopulmonary resuscitation; UGIB: upper gastrointestinal bleeding;
IV: intravenous; NSS: normal saline solution; RLS: Ringer’s lactated solution.

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5 Archives of Academic Emergency Medicine. 2023; 11(1): e41

Table 2: Comparing the studied outcomes between patients receiving and not receiving sodium bicarbonate (SB)

Outcomes SB (n = 165) Non-SB (n = 165) Odds (95% CI) p value
ROSC at the scene
No 115 (69.7) 110 (66.7) 0.8 7 (0.55–1.38) 0.555
Yes 50 (30.3) 55 (33.3)
Sustained ROSC (>20 min)
No 122 (73.9) 124 (75.2) 1.07 (0.65–1.75) 0.800
Yes 43 (26.1) 41 (24.8)
Survival to discharge
No 140 (84.8) 132 (80.0)
Yes 4 (2.4) 9 (5.5) 0.42(0.13–1.39) 0.145
Unknown 21 (12.7) 24 (14.5)
Data are presented as frequency (%). CI: confidence interval; ROSC: return of spontaneous circulation.

groups, respectively (p < 0.001). Most patients in the SB and

non-SB groups were managed using endotracheal tube (ETT)

(87.3% and 64.8%, respectively; p < 0.001) and among the

same groups, 38.2% and 5.5% received calcium gluconate (p

< 0.001), and 13.9% and 4.8% received glucose during CPR,

respectively (p = 0.005). The mean total CPR time was 33.81 ±

13.25 and 25.08 ± 12.40 minutes in the SB and non-SB groups,

respectively (p < 0.001).

3.2. Comparing the studied outcomes between
groups

Table 2 compares the studied outcomes between patients re-

ceiving and not receiving SB. Among the patients in the SB

and non-SB groups, 30.3% and 33.3% exhibited ROSC at the

scene, respectively (p = 0.555). The rate of sustained ROSC

was 26.1% and 24.8% (p = 0.800), whereas the rate of survival

was 2.4% and 5.5% (p = 0.145) in SB and non-SB cases, re-

spectively).

3.3. Chance of ROSC

Univariate analysis using simple logistic regression analysis

showed that the SB group had 0.87 times greater chance for

ROSC at the scene (crude OR = 0.87, 95% CI: 0.55–1.38, p =

0.555). Multivariate analysis using multiple logistic regres-

sion was performed including confounders that were found

to be significantly (p < 0.05) associated with ROSC at the

scene in univariate analysis (which included: location of ar-

rest, witness arrest, initial rhythm, defibrillation, atropine,

and total CPR time). The analysis showed that the SB group

had 0.93 times greater likelihood of ROSC at the scene (ad-

justed OR = 0.93, 95% CI: 0.55–1.59, p = 0.798).

3.4. Likelihood of sustained ROSC

Similarly, univariate analysis using simple logistic regression

showed that the SB group had 1.07 times greater likelihood

of sustained ROSC (crude OR = 1.07, 95% CI: 0.65–1.75, p =

0.800). Multivariate analysis using multiple logistic regres-

sion, entering confounders that were significantly (p < 0.05)

associated with sustained ROSC (which included: witnesses

arrest, initial rhythm, and advanced airway) showed that the

SB group had 0.80 times greater likelihood of sustained ROSC

(adjusted OR = 0.80, 95% CI: 0.47–1.37, p = 0.415).

3.5. Likelihood of survival to discharge

Univariate analysis using simple logistic regression showed

that the SB group had 0.42 times greater likelihood of survival

to discharge (crude OR = 0.42, 95% CI: 0.13–1.39, p = 0.156).

Multivariate analysis using multiple logistic regression, en-

tering confounders that were significantly (p < 0.05) asso-

ciated with survival to discharge during univariate analysis

(which included: initial rhythm and defibrillation) showed

that the SB group had 0.34 times greater likelihood of sur-

vival to discharge (adjusted OR = 0.34, 95% CI: 0.10–1.17, p

= 0.087).

4. Discussion

Our main finding showed that SB use during prolonged CPR

did not improve sustained ROSC. Notably, 26.1% of OHCA

patients receiving SB had sustained ROSC, whereas 24.8% of

those who did not receive SB had the same. Although the

group who used SB use showed greater rates of sustained

ROSC, the difference was not statistically significant (p =

0.800), suggesting that SB administration by EMS did not in-

crease the rate at which patients achieved ROSC at the scene.

Surprisingly, our finding showed that the group with SB use

had lower rates of survival to discharge than did those with-

out SB administration (2.4% vs. 5.5%, respectively).

The results of the present study were consistent with those

reported in a previous study with a small sample size, which

showed that SB administration, as buffer therapy during pro-

longed CPR, did not improve sustained ROSC and survival to

discharge. Unexpectedly, the same study showed that among

those who received SB injection, none showed survival to dis-

charge (1). Moreover, a previous pilot study, which was an

RCT comparing the administration of SB and placebo in car-

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T. Huabbangyang et al. 6

diac arrest patients at the emergency department with se-

vere metabolic acidosis during prolonged cardiopulmonary

resuscitation, showed that SB use significantly affected pH

values and helped modify the acid–base balance of the blood.

However, the mentioned study did not find a significant dif-

ference in sustained ROSC (4.0% vs. 16.0%, p = 0.349) or good

neurologic survival at 1 month (0.0% vs. 4.0%, p = 1.000) be-

tween the SB and placebo groups (17).

Recently, two systematic review and meta-analysis stud-

ies evaluating the effects of SB on ROSC and survival-to-

discharge rates both concluded that SB use was not asso-

ciated with improvement in ROSC or survival-to-discharge

rate, consistent with our findings. Furthermore, the same

studies found that SB administration was associated with de-

creased rates of sustained ROSC and survival-to-discharge (6,

18). However, some previous studies have shown findings

contrary to those presented herein, such as the population-

based study using data of OHCA patients at an emergency

department in Taiwan that had been retrospectively col-

lected for 16 years. Accordingly, the mentioned study showed

that SB administration during resuscitation at the emergency

department was positively associated with survival to hospi-

tal admission (adjusted OR: 4.47; 95% CI: 3.82–5.22, p < 0.001)

(19).

Another study on cardiac arrest patients with non-shockable

rhythm, including asystole and pulseless electrical activity

(PEA), showed that SB use helped improve ROSC and signifi-

cantly increased rate of survival to discharge from a hospital

(20). In addition, one study on SB use during prolonged car-

diopulmonary resuscitation at the emergency department

found that determining the bicarbonate levels from blood

gas tests and administering the appropriate amount of SB

that accounted for body weight (1 mEq/kg) could increase

the rates of ROSC within 20 min (21).

Several explanations for the present results may be provided.

Firstly, the increased rates of sustained ROSC and survival

to discharge in the non-SB group might be explained by the

shorter total CPR time in the non-SB group than in the SB

group (22.66 ± 13.48 vs. 30.24 ± 12.79 min, respectively; p <

0.001). This could have been due to the failure of the EMS to

identify the cause of the arrest in patients who had no ROSC

and needed to receive prolonged CPR, which could have re-

sulted in more SB administration. However, in the present

study, SB administration during prolonged CPR did not im-

prove the rates of ROSC at the scene, sustained ROSC, and

survival to discharge. Therefore, we do not recommend SB

use during prolonged CPR in the prehospital setting. When

prolonged CPR is required, the EMS should focus on provid-

ing high-quality CPR and identifying the cause of the arrest,

which are more important than SB administration. Regard-

ing the context of EMS in the present study area, the deci-

sion for prolonged CPR depended on several factors, such

as the cause of the arrest, relatives’ decision regarding CPR

duration, cardiac rhythm, and unwitnessed or witnessed ar-

rest, among others. The 2010, 2015, and 2020 AHA guide-

lines do not recommend routine use of SB during CPR in car-

diac arrest patients, unless there is medical indication (8-10).

The 2020 AHA guidelines used in the present study recom-

mend using SB only in patients whose cause of arrest could

be determined, those with sodium channel blocker toxi-

city (e.g., tricyclic antidepressants and diphenhydramine),

and those receiving adjunctive therapy for suspected hyper-

kalemia (10).

Nonetheless, the 2021 European Resuscitation Council

Guidelines still recommended SB use in cases requiring pro-

longed unresponsive resuscitation, together with efficient

rescue breathing to decrease acidosis. Guideline recom-

mendations regarding SB use still need to be discussed and

prospectively studied, especially SB use in the prehospital

context by EMS (22). Secondly, the vicious cycle of metabolic

acidosis due to cardiac arrest and prolonged CPR, resulting

in delayed cardiac response and delayed ROSC, must be ad-

dressed. Limited approaches for prehospital management

are available, including buffer therapy with SB, ETT, or laryn-

geal mask airway (LMA) insertion and proper rescue breath-

ing. The present study found that the rate of ROSC was

greater in patients receiving SB with ETT and LMA insertion

than in those receiving rescue breathing by BVM. Thirdly,

one previous study reported that SB had multiple side ef-

fects, which probably increased the severity level of the car-

diac arrest. The reason why only a limited number of patients

achieved sustained ROSC, ROSC at the scene, and survival to

discharge could probably be explained by the side effects of

SB use, which include alkalosis, hypernatremia, excess pro-

duction of carbon dioxide, central venous acidosis with in-

activation of epinephrine administration, and compromised

coronary flow (23). Available evidence to date suggests that

SB needs to be used cautiously and rationally in OHCA pa-

tients to reduce disadvantages due to excessive SB use. How-

ever, the 2020 AHA guidelines specify the amount of SB to be

used based on body weight (mEq/kg) (10). Nonetheless, in

the context of actual EMS practice, determining the actual

body weight of OHCA patients is considerably challenging

and might lead to medication dosage errors.

5. Limitations

Firstly, the present study was a retrospective single-center

study with two data sources: 1) from EMS patient care re-

ports and 2) from the electronic medical records. Despite

our attempts to maintain neutrality where possible, the risk

of selection bias cannot be completely eliminated. Secondly,

no blood gas test results were available in the present study

given that no equipment for blood gas point-of-care testing

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7 Archives of Academic Emergency Medicine. 2023; 11(1): e41

were available for the management of cardiac arrest patients

at the scene, unlike studies at the emergency department.

Thirdly, some confounding factors associated with the tar-

get outcomes might have been overlooked. Only data on

prehospital management were analyzed in the present study

without considering essential data from the emergency de-

partment or intensive care unit. Fourthly, data on survival

to discharge had several unknown aspects regarding the pa-

tients’ last status, such as neurological evaluation or Cerebral

Performance Category (CPC) score after hospital discharge.

Fifthly, For the study area, off-line protocol in management

of OHCA patients allowed paramedics or ENPs to be able to

administer SB in patients with prolonged CPR. If the study

results were applied in other areas, there would probably

be limitations regarding generalizability (external validity) of

the study results. This might include capacity of the oper-

ating team, indications and discretion of clinical decision of

CPR commander about decision using SB. Lastly, data for

OHCA patients in the area were not recorded and collected

using the Utstein OHCA template.

6. Conclusion

The present study demonstrated that prehospital SB use by

EMS during prolonged CPR did not improve the likelihood

of sustained ROSC, ROSC at the scene, and survival to dis-

charge. It seems that, in cases requiring prolonged CPR,

high-quality CPR and determination of the cause of arrest,

focusing on the 5 H’s and 5 T’s that may cause cardiac arrest,

should be emphasized over buffer therapy.

7. Declarations

7.1. Acknowledgments

The authors were grateful to Navamindradhiraj University

Research Fund, paramedics at V-EMS, Faculty of Medicine

Vajira Hospital, Navamindradhiraj University, for facilitat-

ing data collection and access in the present study, Gawin

Tiyawat, MD., chief of Department of Disaster and Emer-

gency Medical Operation, Faculty of Science and Health

Technology, Navamindradhiraj University, and Chunlanee

Sangketchon, MD., deputy dean of Faculty of Science and

Health Technology, Navamindradhiraj University, for sup-

port and suggestions in the research development and Ani-

wat Berpan, MD. for suggestions on English for the present

study.

7.2. Conflict of interest

The authors have no conflicting interests to declare.

7.3. Fundings

This research did not receive any specific grant from funding

agencies in the public, commercial, or not-for-profit sectors.

7.4. Authors’ contribution

Conceptualization: Thongpitak Huabbangyang, Chunla-

nee Sangketchon, Chomkamol Saumok, Gotchagorn Noimo,

Korawee pinthong, Ketvipa Saungun and Kaiwit Bunta;

Methodology: Thongpitak Huabbangyang, Gotchagorn

Noimo, Korawee pinthong, Ketvipa Saungun and Kai-

wit Bunta; Validation: Thongpitak Huabbangyang and

Chunlanee Sangketchon; Formal analysis: Thongpitak

Huabbangyang; Investigation: Thongpitak Huabbangyang,

Gotchagorn Noimo, Korawee pinthong, Ketvipa Saungun

and Kaiwit Bunta; Resources: Thongpitak Huabbangyang

and Chunlanee Sangketchon; Data Curation: Thongpi-

tak Huabbangyang; Writing – Original Draft: Thongpitak

Huabbangyang; Writing - Review & Editing: Thongpitak

Huabbangyang and Chunlanee Sangketchon; Visualization:

Thongpitak Huabbangyang; Supervision: Thongpitak Huab-

bangyang and Chunlanee Sangketchon; Project adminis-

tration: Thongpitak Huabbangyang; Funding acquisition:

Thongpitak Huabbangyang. All authors read and approved

final version.

7.5. Data availability

The datasets generated and analyzed during the current

study are available from the corresponding author on reason-

able request.

7.6. Using artificial intelligent chat bots

None.

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	Introduction
	Methods
	Results
	Discussion
	Limitations
	Conclusion
	Declarations
	References