Emergency. 2017; 5 (1): e5

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

20-Day Trend of Serum Potassium Changes in Bam Earth-
quake Victims with Crush Syndrome; a Cross-sectional
Study
Saeed Safari1, Iraj Najafi2∗, Mostafa Hosseini3, Alireza Baratloo 1, Mahmoud Yousefifard4, Hamidreza
Mohammadi1

1. Emergency Department, Shohadaye Tajrish Hospital, Shahid Beheshti University of Medical Sciences, Tehran, Iran.

2. Department of Nephrology, Dr. Shariati Hospital, Tehran University of Medical Sciences, Tehran, Iran.

3. Department of Epidemiology and Biostatistics, School of Public Health, Tehran University of Medical Sciences, Tehran, Iran.

4. Department of Physiology, School of Medicine, Tehran University of Medical Sciences, Tehran, Iran.

Received: February 2016; Accepted: April 2016; Published online: 8 January 2017

Abstract: Introduction: Many of those who survive following an earthquake die in the next phase due to preventable and
treatable medical conditions such as hyperkalemia. The present study aimed to evaluate the trend of potassium
changes in crush syndrome patients of Bam earthquake. Methods: In this retrospective cross-sectional study,
using the database of Bam earthquake victims, which were developed by Iranian Society of Nephrology following
Bam earthquake, Iran, 2003, the 20-day trend of potassium changes in > 15 years old crush syndrome patients
was evaluated. Results:135 crush syndrome patients with the mean age of 29.9 ± 9.91 years were evaluated
(56.3% male). Mean potassium concentration during the first 3 days of admission was 5.6 ± 1.3 mEq/L. On the
day of admission, 43.1% (95% CI: 34.0 - 52.2) had normal potassium concentration, 3.4% (95% CI: 0.1 - 6.8) had
hypokalemia, and 53.4% (44.3 - 62.6) had hyperkalemia. During 20-day follow-up, 62.3% (95% CI: 66.7-71.9) of
the patients had normal potassium. While, 11.5% (95% CI: 9.7-13.3) had hypokalemia and 19.2% (95% CI: 17.0-
21.5) had hyperkalemia. As the days of hospitalization increased, prevalence of hyperkalemia decreased while
hypokalemia increased. On the 17th day 21.2% (95% CI: 2.2-39.9) had hypokalemia and 10.5% (95% CI: 0.1 -
24.7) had hyperkalemia. Conclusion: Findings of the present study showed that following urine alkalinization
and fluid resuscitation, the prevalence of hyperkalemia reduced, but hypokalemia developed. It seems that the
correction of serum potassium level should be accompanied by precise monitoring of intake and output of the
patient and prescription of reasonable amount of intravenous fluid.

Keywords: Rhabdomyolysis; crush syndrome; potassium; water-electrolyte imbalance; disaster victims

© Copyright (2017) Shahid Beheshti University of Medical Sciences

Cite this article as: Safari S, Najafi I, Hosseini M, Baratloo A, Yousefifard M, Mohammadi H. 20-Day Trend of Serum Potassium Changes in

Bam Earthquake Victims with Crush Syndrome; a Cross-sectional Study. Emergency. 2017; 5 (1): e5.

1. Introduction

Crush syndrome following traumatic rhabdomyolysis is a

life-threatening condition that is accompanied by severe

shock, cardiovascular disorders and acute kidney injury.

Traumatic rhabdomyolysis is a result of direct pressure

∗Corresponding Author: Iraj Najafi; Department of Internal Medicine,
Dr. Shariati Hospital, Tehran University of Medical Sciences, North Kare-
gar Avenue, Tehran 14114 Iran. Tel/Fax: +98 21 22721155; Email: na-
jafi63800@yahoo.com.

on skeletal muscles and is frequently seen in accidents,

sports and most importantly in natural disasters such as

earthquakes (1-3). Electrolyte abnormalities are among

very common problems of these patients. When pressure

is removed and perfusion of ischemic body part is restored,

intracellular ions are released in the systemic circulation

through the damaged cell membrane (4, 5). Hyperkalemia is

the most important and fatal electrolyte imbalance in these

patients (6). Severe hyperkalemia may lead to dysrhythmia,

cardiac arrest and finally sudden death. This electrolyte

imbalance can occur on the site of accident, during trans-

portation to the hospital and even during hospitalization (7).

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S. Safari et al. 2

To control this condition, early and vigorous fluid resuscita-

tion can be helpful and sometime lifesaving (8). However,

there are studies that show vigorous fluid resuscitation can

leads to a drop in serum potassium level and sometime

hypokalemia (9). Some existing studies have evaluated the

changes in the ion concentration of crushed patients in the

initial 3 days after earthquake (7, 10, 11). However, there is

not enough knowledge regarding long-term changes in the

concentration of this ion. Therefore, the present study aimed

to evaluate the 20-day trend of potassium concentration

changes in crush syndrome patients of Bam earthquake.

2. Methods

2.1. Study design and setting

The present study is a retrospective cross-sectional one de-

signed to evaluate the trend of changes in potassium ion dur-

ing the 20 initial days of hospitalization in crush syndrome

patients of Bam earthquake. This study was approved by the

Ethics Committee of Shahid Beheshti University of Medical

Sciences, Tehran, Iran. The researchers adhered to the prin-

ciples of Helisinki Declaration and confidentiality of patient

information throughout this study.

2.2. Participants

To achieve the aims of this study, the data of Bam earth-

quake victims were used. Following Bam earthquake, Iran,

2003, Iranian Society of Nephrology with the association of

International Society of Nephrology, designed a question-

naire and sent it to all the hospitals that were expected to

admit the earthquake victims. These hospitals included 15

centers in 7 cities of Bandarabbas, Bushehr, Isfahan, Kerman,

Shiraz, Tehran, and Zahedan. Data from Shiraz were not en-

tered to the database since the centers did not cooperate.

Data were entered to a database in the same year. The details

of data gathering and management have been introduced

in previously published studies (1, 12-15). In the present

study, crush syndrome patients whose serum potassium level

was recorded for at least the initial 3 days of admission were

included. Patients under 15 years old, those with chronic

kidney diseases and patients whose creatine phosphokinase

(CPK) was never measured were excluded. Crush syndrome

was defined as traumatic rhabdomyolysis leading to serum

creatinine over 1.66 mg/dl and CPK higher than 1000 IU/L

in 2 measurements during hospitalization (16). Hypokalemia

was defined as serum potassium level lower than 3.5 mEq/L

and hyperkalemia as serum potassium level higher than 5

mEq/L (17). Serum potassium levels were evaluated daily

and the data was recorded in the database.

2.3. Statistical analysis

Considering 15.9% prevalence of hyperkalemia (10), 95%

confidence interval (CI), and 0.06 accuracy, the sample size

was calculated to be 134 cases. Data from the database were

entered to STATA 11.0 and analyzed. Serum potassium level

was reported as mean ± standard deviation (SD). Patients
were classified as normal, hypokalemia and hyperkalemia

based on their serum potassium level and the prevalence was

reported with 95% CI.

3. Results:

135 crush syndrome patients with the mean age of 29.9

± 9.91 years were evaluated (56.3% male). Demographic,
clinical, and laboratory findings of the patients are presented

in table 1. Mean and SD of potassium concentration during

the first 3 days of admission was 5.6 ± 1.3 mEq/L. Trend of
changes of mean potassium level with 95% CI showed little

variation during the first 20 days of admission (figure 1).

On the day of admission, 43.1% (95% CI: 34.0 - 52.2) had

normal potassium concentration, 3.4% (95% CI: 0.1 - 6.8)

had hypokalemia, and 53.4% (44.3 - 62.6) had hyperkalemia.

During 20-day follow-up, 62.3% (95% CI: 66.7-71.9) of the

patients had normal potassium. While, 11.5% (95% CI:

9.7-13.3) had hypokalemia and 19.2% (95% CI: 17.0-21.5)

had hyperkalemia. As the days of hospitalization increased,

prevalence of hyperkalemia decreased while hypokalemia

increased. On the 17th day 21.2% (95% CI: 2.2-39.9) had hy-

pokalemia and 10.5% (95% CI: 0.1 - 24.7) had hyperkalemia.

Table 1: Baseline characteristics of included patients

Variable Values
Age (years)

15-34 105 (79.2)
35-54 17 (12.6)
≥55 11 (8.2)

Gender
Male 76 (56.3)
Female 59 (43.7)

Time under the rubble (hours) 6.2 ± 3.4
Systolic blood pressure (mmHg) 126.8 ± 2.6
Diastolic blood pressure (mmHg) 77.9 ± 1.0
Fluid intake (ml) 2872.0 ± 1829.0
Urine output (ml) 897.0 ± 923.0
Blood urea nitrogen (mg/dL) 104.0 ± 59.0
Creatinine (mg/dL) 4.73 ± 2.3
Creatine phosphokinase (IU/L) 17.4 ± 24.7
Lactate dehydrogenase (U/L) 3.1 ± 2.5
Uric acid (mg/dL) 8.5 ± 2.8
Data were presented as mean ± standard
deviation or number (%).

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3 Emergency. 2017; 5 (1): e5

Table 2: Prevalence of hypokalemia, normal, and hyperkalemia among Bam earthquake victims during 20 days of admission

Day Normal Hypokalemia Hyperkalemia

Prevalence 95% CI Prevalence 95% CI Prevalence 95% CI

1 43.1 34.0 - 52.2 3.4 0.1 - 6.8 53.4 44.3 - 62.6
2 56.8 47.8 - 65.8 2.5 0.0 - 5.4 40.7 31.8 - 49.6
3 67.9 59.0 - 76.9 11.3 5.3 - 17.4 20.8 13.0 - 28.5
4 66.1 57.1 - 75.0 15.6 8.7 - 22.4 18.3 11.0 - 25.7
5 71.0 62.1 - 79.9 14.0 7.2 - 20.8 15.0 8.0 - 22.0
6 75.9 66.8 - 84.9 12.6 5.6 - 19.7 11.5 4.7 - 18.2
7 76.4 66.5 - 86.3 15.3 6.9 - 23.7 8.3 1.9 - 14.8
8 77.6 67.5 - 87.7 13.4 5.2 - 21.7 9.0 2.1 - 15.9
9 63.5 50.2 - 76.7 21.2 9.9 - 32.4 15.4 5.5 - 25.3
10 86.0 76.3 - 95.7 6.0 0.0 - 12.7 8.0 0.1 - 15.6
11 83.3 72.7 - 94.0 14.6 4.5 - 24.7 2.1 0.1 - 6.2
12 76.7 64.0 - 89.5 14.0 3.5 - 24.4 9.3 0.5 - 18.1
13 81.1 68.3 - 93.9 8.1 0.1 - 17.0 10.8 0.7 - 21.0
14 77.8 61.8 - 93.8 11.1 0.1 - 23.2 11.1 0.1 - 23.2
15 69.2 51.1 - 87.3 23.1 6.5 - 39.6 7.7 0.1 - 18.1
16 80.0 64.0 - 96.0 12.0 0.1 - 25.0 8.0 0.1 - 18.9
17 68.4 46.9 - 89.9 21.1 2.2 - 39.9 10.5 0.1 - 24.7
18 80.0 70.0 - 90.0 6.7 0.1 - 19.7 13.3 0.1 - 25.1
19 91.0 88.0 - 96.0 0.0 0.1 - 0.0 9.0 0.6 - 16.0
20 100.0 90.0 - 100.0 0.0 0.0 - 0.0 0.0 0.0 - 0.0

Total 69.3 66.7 - 71.9 11.5 9.7-13.3 19.2 17.0-21.5
CI: Confidence interval.

At the end of the 20th day, all cases of hypo and hyperkalemia

were corrected (table 2 and figure 2).

4. Discussion:

Findings of the present study showed the 53.4% prevalence

of hyperkalemia and 3.4% hypokalemia in crush syndrome

patients of Bam earthquake victims on the day of admission.

Following therapeutic interventions, urine alkalinization

Figure 1: Mean and 95% confidence interval of potassium levels

during first 20 days after crush injury.

and fluid resuscitation, the prevalence of hyperkalemia

decreased but hypokalemia increased. Clinical and labo-

ratory variables monitoring in the earthquake victims can

be helpful in rapid diagnosis and efficient management of

these patients (18-22). The frequent cause of mortality at

the scene of disaster is direct trauma. However, many of

those who survive die in the next phase due to preventable

and treatable medical conditions such as hyperkalemia.

Hyperkalemia is the most important electrolyte that can lead

Figure 2: Trend of hyperkalemia and hypokalemia prevalence

among studied patients.

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S. Safari et al. 4

to a higher rate of mortality by causing fatal arrhythmias

(7, 10, 11, 23, 24). A study by Sever et al. on crush syn-

drome patients after Marmara earthquake in Turkey showed

that hyperkalemia is the most important life-threatening

problem in patients with traumatic crush syndrome (25).

Studying the causes of mortality in crush syndrome patients

in Marmara earthquake in Turkey showed that 42% of the

cases that died due to crush syndrome had hyperkalemia

(7). Oda et al. analyzed data of those who were injured

in Hanshin-Awaji earthquake in Japan and introduced hy-

perkalemia as one of the most important causes of death

among patients with crush syndrome (11). However, data

of Wenchuan earthquake in China show that hypokalemia

(18.2%) was more common than hyperkalemia (15.9%).

Researchers believe that this has happened since most of

those with hyperkalemia have died on the way to hospital as

there was not enough fluid for early fluid resuscitation on the

scene in Wenchuan earthquake (10). However, hypokalemia

is a problem that has not been studied properly. Early and

vigorous fluid resuscitation can prevent acute kidney injury

in earthquake victims with crush syndrome. In addition,

it can reduce the severity of hyperkalemia and prevent it

from leading to fatal arrhythmias (9). For instance, Gunal

et al. studied 15 victims of Bingol earthquake and showed

that on admission, 9 had hypokalemia, while only one had

hyperkalemia. These researchers believe this to be due

to fluid resuscitation and bicarbonate prescription on the

scene (9). In Bam earthquake, lack of enough fluid for fluid

resuscitation on the scene led to lack of fluid resuscitation

during the initial hours of the incident for many of the

victims. Therefore, hyperkalemia was very common on the

first day. However, during the course of hospitalization fluid

resuscitation reduced the prevalence of hyperkalemia. Yet,

too much fluid resuscitation led to hypokalemia. Although

all cases of hypo and hyperkalemia were resolved on the

20th day, since hypokalemia may be accompanied by the

probability of cardiotoxicity, precise monitoring of intake

and output of the patient and prescription of reasonable

amounts of intravenous fluid can be important in correcting

this imbalance and preventing it. Excessive fluid resuscita-

tion during hospitalization can be prevented by adjusting

fluid resuscitation based on laboratory findings and serum

ion levels of the patients.

5. Limitation:

Missing data, outdated data, referring the victims to different

health centers, different therapeutic and resuscitative ap-

proaches, variations in management of the patient in these

centers, and not exactly knowing the type of trauma and its

severity are among the most important limitations of this

study. Despite all these limitations, since our information

regarding management and outcome of patients with crush

syndrome is limited, the authors decided to study and pub-

lish the minimum existing data.

6. Conclusion:

Findings of the present study showed that following urine al-

kalinization and fluid resuscitation, the prevalence of hyper-

kalemia reduced, but hypokalemia developed. It seems that

correction of serum potassium level should be accompanied

by precise monitoring of intake and output of the patient and

prescription of reasonable amount of intravenous fluid.

7. Appendix

7.1. Acknowledgements

This article has been extracted from Dr. Hamidreza Moham-

madi’s thesis for achieving his MD degree from the Faculty of

Medicine at Shahid Beheshti University of Medical Sciences.

7.2. Conflict of interest

None.

7.3. Funding support

None declared.

7.4. Author’s Contributions

All authors passed four criteria for authorship contribution

based on recommendations of the International Committee

of Medical Journal Editors.

References

1. Hosseini M, Safari S, Sharifi A, Amini M, Farokhi

FR, Sanadgol H, et al. Wide spectrum of traumatic

rhabdomyolysis in earthquake victims. Acta Med Iran.

2009;47(6):459-64.

2. Najafi I, Van Biesen W, Sharifi A, Hoseini M, Farokhi FR,

Sanadgol H, et al. Early detection of patients at high risk

for acute kidney injury during disasters: development of

a scoring system based on the Bam earthquake experi-

ence. J Nephrol. 2008;21(5):776-82.

3. Tolouian R, Wild D, Lashkari MH, Najafi I. Oral al-

kalinizing solution as a potential prophylaxis against

myoglobinuric acute renal failure: preliminary data

from healthy volunteers. Nephrol Dial Transplant.

2005;20(6):1228-31.

4. Gonzalez D. Crush syndrome. Crit Care Med.

2005;33(1):S34-41.

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: www.jemerg.com



5 Emergency. 2017; 5 (1): e5

5. Huerta-Alardin AL, Varon J, Marik PE. Bench-to-bedside

review: rhabdomyolysis–an overview for clinicians. Crit

care. 2005;9(2):158-69.

6. Smith J, Greaves I. Crush injury and crush syndrome: a

review. J Trauma. 2003;54(5 Suppl):S226-30.

7. Erek E, Sever MS, Serdengecti K, Vanholder R, Akoglu E,

Yavuz M, et al. An overview of morbidity and mortal-

ity in patients with acute renal failure due to crush syn-

drome: the Marmara earthquake experience. Nephrol

Dial Transplant. 2002;17(1):33-40.

8. Vanholder R, van der Tol A, De Smet M, Hoste E, Koc M,

Hussain A, et al. Earthquakes and crush syndrome casu-

alties: lessons learned from the Kashmir disaster. Kidney

Int. 2007;71(1):17-23.

9. Gunal AI, Celiker H, Dogukan A, Ozalp G, Kirciman E,

Simsekli H, et al. Early and vigorous fluid resuscitation

prevents acute renal failure in the crush victims of catas-

trophic earthquakes. J Am Soc Nephrol. 2004;15(7):1862-

7.

10. He Q, Wang F, Li G, Chen X, Liao C, Zou Y, et al. Crush Syn-

drome and Acute Kidney Injury in the Wenchuan Earth-

quake. J Trauma Acute Care Surg. 2011;70(5):1213-8.

11. Oda J, Tanaka H, Yoshioka T, Iwai A, Yamamura H,

Ishikawa K, et al. Analysis of 372 Patients with Crush

Syndrome Caused by the Hanshin-Awaji Earthquake. J

Trauma Acute Care Surg. 1997;42(3):470-6.

12. Alavi-Moghaddam M, Safari S, Najafi I, Hosseini M. Accu-

racy of urine dipstick in the detection of patients at risk

for crush-induced rhabdomyolysis and acute kidney in-

jury. Eur J Emerg Med. 2012;19(5):329-32.

13. Safari S, Najafi I, Hosseini M. Outcomes of fasciotomy

in patients with crush-induced acute kidney injury after

Bam earthquake. Iran J Kidney Dis. 2011;5(1):25-8.

14. Iraj N, Saeed S, Mostafa H, Houshang S, Ali S, Farin RF, et

al. Prophylactic fluid therapy in crushed victims of Bam

earthquake. Am J Emerg Med. 2011;29(7):738-42.

15. Najafi I, Safari S, Sharifi A, Sanadgol H, Hosseini M,

Rashid-Farokhi F, et al. Practical strategies to reduce mor-

bidity and mortality of natural catastrophes: a retrospec-

tive study based on Bam earthquake experience. Arch

Iran Med. 2009;12(4):347-52.

16. Rajagopalan S. Crush injuries and the crush syndrome.

Med J Armed Forces India. 2010;66(4):317-20.

17. Kasper D, Fauci A, Hauser S, Longo D, Jameson J,

Loscalzo J. Harrison’s Principles of Internal Medicine

19/E (Vol. 1 & Vol. 2): McGraw Hill Professional; 2015.

18. Safari S, Yousefifard M, Hashemi B, Baratloo A, Forouzan-

far MM, Rahmati F, et al. The value of serum creatine ki-

nase in predicting the risk of rhabdomyolysis-induced

acute kidney injury: a systematic review and meta-

analysis. Clin Exp Nephrol. 2016:1-9.

19. Safari S, Yousefifard M, Baikpour M, Rahimi-Movaghar

V, Abiri S, Falaki M, et al. Validation of thoracic injury

rule out criteria as a decision instrument for screening

of chest radiography in blunt thoracic trauma. J Clin Or-

thop Trauma. 2016;[In press].

20. Shojaee M, Faridaalaee G, Yousefifard M, Yaseri M,

Arhami Dolatabadi A, Sabzghabaei A, et al. New scoring

system for intra-abdominal injury diagnosis after blunt

trauma. Chin J Traumatol. 2014;17(1):19-24.

21. Hosseini M, Ghelichkhani P, Baikpour M, Tafakhori A,

Asady H, Haji Ghanbari MJ, et al. Diagnostic Accuracy

of Ultrasonography and Radiography in Detection of

Pulmonary Contusion; a Systematic Review and Meta-

Analysis. Emerg (Tehran). 2015;3(4):127-36.

22. Yousefifard M, Baikpour M, Ghelichkhani P, Asady H,

Shahsavari Nia K, Moghadas Jafari A, et al. Screening Per-

formance Characteristic of Ultrasonography and Radio-

graphy in Detection of Pleural Effusion; a Meta-Analysis.

Emerg (Tehran). 2016;4(1):1-10.

23. Allister C. Cardiac arrest after crush injury. BMJ.

1983;287(6391):531-2.

24. Better OS. The crush syndrome revisited (1940-1990).

Nephron. 1990;55(2):97-103.

25. Sever MS, Erek E, Vanholder R, Kantarci G, Yavuz M,

Turkmen A, et al. Serum potassium in the crush syn-

drome victims of the Marmara disaster. Clin Nephrol.

2003;59(5):326-33.

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	Introduction
	Methods
	Results:
	Discussion:
	Limitation:
	Conclusion:
	Appendix
	References