Archives of Academic Emergency Medicine. 2021; 9(1): e24
https://doi.org/10.22037/aaem.v9i1.1096

REV I EW ART I C L E

The Value of Lactate Dehydrogenase in Predicting
Rhabdomyolysis-Induced Acute Renal Failure; a Narra-
tive Review
Hazhir Heidari Beigvand1, Kamran Heidari2, Behrooz Hashemi3, Amin Saberinia3,4∗

1. Preventive Medicine and Public Health Research Center, Psychosocial Health Research Institute, Community and Family Medicine
Department, School of Medicine, Iran University of Medical Sciences, Tehran, Iran.

2. Skull Base Research Center, Loghman Hakim Hospital, Shahid Beheshti University of Medical Sciences, Tehran, Iran.

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

4. Emergency Department, Bahonar Hospital, Faculty of Medicine, Kerman University of Medical Sciences, Kerman, Iran.

Received: January 2021; Accepted: February 2021; Published online: 9 March 2021

Abstract: Introduction: Determining the diagnostic value of available biomarkers in predicting rhabdomyolysis-induced
acute kidney injury (AKI) is a priority. This study aimed to review the current evidence about the value of lactate
dehydrogenase (LDH) in this regard. Methods: In this narrative review, the papers in PubMed, Embase, and web
of science were studied. The keywords prognosis, prognoses, prognostic, LDH, rhabdomyolysis, emergency pa-
tients, and acute kidney failure or AKI had been selected from MeSH medical dictionary. Related papers written
in English and published from November 2007 to December 2020 were selected. Results: Finally, 14 articles
were accepted for analysis. Among the selected articles, four were randomized clinical trials, seven were cross-
sectional, and three were case-control studies. The results of the present review showed that abuse of illegal
drugs is the most common cause of rhabdomyolysis. AKI is the most serious complication of rhabdomyolysis
reported in the studies. These studies have shown a three-fold increase in AKI following drug-induced rhab-
domyolysis. The review of the included articles shows that high LDH can predicts AKI, especially in critical and
emergency situations such as rhabdomyolysis where there is a risk of death if diagnosed late. These studies
show that LDH increases in the presence of renal failure and tissue damage. Conclusion: Serum LDH is an ap-
propriate and cost-effective prognostic indicator that can be used for risk classification of patients at risk for
rhabdomyolysis-induced AKI.

Keywords: L-Lactate Dehydrogenase; Acute Kidney Injury; Rhabdomyolysis; Role; Review; Clinical Enzyme Tests

Cite this article as: Heidari Beigvand H, Heidari K, Hashemi B, Saberinia A. The Value of Lactate Dehydrogenase in Predicting

Rhabdomyolysis-Induced Acute Renal Failure; a Narrative Review. Arch Acad Emerg Med. 2021; 9(1): e24.

1. Introduction

Rhabdomyolysis accounts for 5 to 25% of all acute kidney in-

juries (AKIs) (1). The overall mortality rate of patients with

rhabdomyolysis is about 10% but it is higher in men than

women (2). Rhabdomyolysis-induced AKI can occur follow-

ing poisoning, trauma, environmental factors, metabolic dis-

orders, infections, immune disorders, and hereditary disor-

∗Corresponding Author: Amin Saberinia; Emergency Department,
Bahonar Hospital, Kerman University of Medical Sciences, Kerman,
Iran. Email: amin.saberinia@gmail.com, Tel: +982122721155, ORCID:
http://orcid.org/0000-0001-8612-4319.

ders (3, 4). It is also a major medical complication of disas-

ters victims (5).

Considering the importance of early diagnosis of at-risk pa-

tients in emergency department, determining the diagnostic

value of available biomarkers in predicting rhabdomyolysis

induced AKI is a priority (2, 6).

Muscle damage leads to membrane disruption, extracellu-

lar fluid leakage, and increased serum level of creatine phos-

phokinase (CK) and lactate dehydrogenase (LDH) enzymes

(7-10). LDH levels are elevated in infarction, hepatocellu-

lar damage, carcinomas, and any conditions that cause cell

necrosis (11, 12).

Various studies have evaluated the level of this enzyme at the

time of kidney damage and have shown that in most cases,

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



H. Heidari Beigvand et al. 2

very high concentrations of LDH have been observed in the

serum of patients with rhabdomyolysis, which indicates that

it can be useful in predicting renal failure (13, 14). Based on

the above-mentioned reasons, this study aimed to review the

current evidence regarding the value of LDH in predicting the

rhabdomyolysis induction AKI.

2. Methods

2.1. Study design

In this narrative review, the keywords prognosis, prognose,

prognostic, lactate dehydrogenase (LDH), rhabdomyolysis,

emergency patients, and acute kidney injury or acute renal

failure had been selected from MeSH medical dictionary. Re-

lated papers written in English and published from Novem-

ber 2007 to December 2020 were searched in PubMed, Em-

base, and web of science. Original researches with available

full text, which had evaluated the value of LDH in detection

of at-risk patients for rhabdomyolysis-induced AKI were se-

lected. Case reports, letters to the editors, and review papers

were omitted.

2.2. Search process and assessment of papers

There was no restriction on duration of intervention, type of

participants, and place of study. The steps for selecting the

papers were as follows: First the initial search was performed

by two researchers separately and the duplicate papers were

removed, then with the aim of eliminating unrelated articles,

the abstract and the title of each article were reviewed, po-

tentially related papers meeting the inclusion criteria were

identified. The full texts of the papers were reviewed by two

authors and discussed until consensus was reached regard-

ing their suitability.

After compiling a list of study titles and abstracts in the

databases, the Strobe standard checklist was used to deter-

mine the quality of the studies. The Strobe checklist consists

of 22 different sections that assess various aspects of method-

ology including sampling methods, statistical analysis, con-

founding factor adjustment, measurement of variables, va-

lidity and reliability of the tools used, and the objectives of

the study.

2.3. Data extraction

The specific characteristics of each study were extracted by

the researchers using a standard form. Two researchers ex-

amined the data independently, based on the inclusion cri-

teria. In case of disagreement between the researchers, help

was sought from a third researcher.

The differences in findings were resolved using the method

of benchmarking the overall conclusions of the articles and

in this study, it was organized. Findings on rhabdomyolysis,

AKI, and their association with lactate dehydrogenase were

derived.

3. Results

231 titles were extracted. In the initial screening stage, the ti-

tle and type of articles were reviewed and finally 140 articles

were excluded. Then, the full text of the articles was studied

and 50 articles were excluded due to differences in purpose.

Of the remaining 41 articles, 27 articles were excluded due to

duplication of content and exclusion criteria, and finally, 14

articles were accepted for analysis (figure 1). The specifica-

tions and findings of the included articles are shown in Table

1.

Among the selected articles, four were randomized clini-

cal trials, seven were cross-sectional, and three were case-

control studies. The studies, either specifically or gener-

ally, examined serum level condition and prognostic ability

of LDH in predicting rhabdomyolysis-induced AKI. Amongst

the fourteen articles, eight (three randomized clinical trials,

two case-control, and three cross-sectional studies) reported

a high serum level and prognostic value of LDH in kidney dis-

ease. The target groups were often 30-60 year-old individuals

and a case-control study was conducted on rats.

The results of the present review showed that abuse of ille-

gal drugs is the most common cause of rhabdomyolysis. AKI

is the most serious complication of rhabdomyolysis reported

in the studies (15-18). These studies have shown a three-fold

increase in AKI following drug-induced rhabdomyolysis (16).

The review of the included articles shows that high LDH can

predicts AKI, especially in critical and emergency situations

such as rhabdomyolysis where there is a risk of death if diag-

nosed late (15, 17-23).

4. Discussion

The studies showed that the serum level of LDH was high in

patients with renal impairment and the concentration of this

enzyme significantly increased in patients with rhabdomyol-

ysis. Studies have also shown that LDH can be useful in early

diagnosis of acute renal failure in children.

The exact process or processes of the development of

rhabdomyolysis-induced AKI are not yet clear. A number

of proposed processes include mechanical damage to renal

tubules caused by myoglobin deposition, and direct effect of

the toxic property of free iron on renal tubules and volume

depletion (15-18, 20, 21).

The researchers reported that LDH levels significantly in-

creased in acute renal failure, especially in conditions caused

by rhabdomyolysis (15-18). Understanding the cause of this

increase can help in providing scientific solutions. Tissue

concentration of LDH is 500 times its serum concentration.

In general, high concentrations of this enzyme are present

in the liver, heart, red blood cells, skeletal muscles, and kid-

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



3 Archives of Academic Emergency Medicine. 2021; 9(1): e24

neys (14). In cases of damage to the mentioned organs, such

as in kidney and heart infarction and hemolysis, its serum

levels rise. Unlike enzymes such as aspartate transaminase

(AST), alanine transaminase (ALT), and Creatine phosphok-

inase (CPK), which show significant variations in enzymatic

activity between tissues, for LDH, the difference between the

highest value tissues (such as the liver) and the lowest value

tissues (such as the kidney) is only about 1.5 times (24).

In the analysis of the reviewed studies, it can be concluded

that serum LDH is an appropriate and cost-effective prog-

nostic indicator that can be used for risk classification of pa-

tients with acute renal failure due to rhabdomyolysis. Given

the importance of rhabdomyolysis-induced acute renal fail-

ure, it is recommended that serum LDH level be measured

at the time of admission to the emergency department and

in the event of symptoms such as coma, convulsions, and el-

evated body temperature during the hours after hospitaliza-

tion in order to promptly start treatment if rhabdomyolysis is

proven.

Further understanding of the value of LDH in predicting

rhabdomyolysis-induced AKI could be the subject of more

extensive research, as present studies in this area are lim-

ited to a small number of randomized controlled trials, case

studies, and retrospective studies. We need to conduct more

multi-centered studies to confirm the findings of the present

review and deeply explore the mechanism.

5. Conclusion

The results showed that the level of LDH was high in pa-

tients with renal impairment and this enzyme significantly

increased in patients with rhabdomyolysis. Studies have also

shown that LDH can be useful in early diagnosis of acute re-

nal failure in children.

6. Declarations

6.1. Acknowledgement

The authors would like to thank the Shahid Beheshti Univer-

sity of Medical Sciences for its technical and editorial assist.

6.2. Funding

None.

6.3. Author contributions

All authors met the criteria for authorship contribution based

on the international committee of medical journal editors’

recommendations.

6.4. Conflict of interest

The authors declare that there is not any conflict of interest

regarding this study.

References

1. Zutt R, Van Der Kooi A, Linthorst G, Wanders R, De Visser

M. Rhabdomyolysis: review of the literature. Neuromus-

cular Disorders. 2014;24(8):651-9.

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

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

tine kinase in predicting the risk of rhabdomyolysis-

induced acute kidney injury: a systematic review and

meta-analysis. Clinical and experimental nephrology.

2016;20(2):153-61.

3. Packard K, Price P, Hanson A. Antipsychotic use and the

risk of rhabdomyolysis. Journal of pharmacy practice.

2014;27(5):501-12.

4. Omrani H, Najafi I, Bahrami K, Najafi F, Safari S. Acute

kidney injury following traumatic rhabdomyolysis in

Kermanshah earthquake victims; a cross-sectional study.

The American journal of emergency medicine. 2020.

5. Hosseini M, Safari S, Sharifi A, Amini M, Farokhi FR,

Sanadgol H, et al. Wide spectrum of traumatic rhab-

domyolysis in earthquake victims. Acta Medica Iranica.

2009:459-64.

6. Alavi-Moghaddam M, Safari S, Najafi I, Hosseini M. Ac-

curacy of urine dipstick in the detection of patients at

risk for crush-induced rhabdomyolysis and acute kid-

ney injury. European Journal of Emergency Medicine.

2012;19(5):329-32.

7. Duncan SJ, Howden CW. Proton pump inhibitors and risk

of rhabdomyolysis. Drug safety. 2017;40(1):61-4.

8. Mendes P, Robles PG, Mathur S. Statin-induced rhab-

domyolysis: a comprehensive review of case reports.

Physiotherapy Canada. 2014;66(2):124-32.

9. Nelson KL, Stenehjem D, Driscoll M, Gilcrease GW. Fa-

tal statin-induced rhabdomyolysis by possible interac-

tion with palbociclib. Frontiers in Oncology. 2017;7:150.

10. Jin Y, Ye X, Shao L, Lin B, He C, Zhang B, et al.

Serum lactic dehydrogenase strongly predicts survival

in metastatic nasopharyngeal carcinoma treated with

palliative chemotherapy. European journal of cancer.

2013;49(7):1619-26.

11. Li B, Li C, Guo M, Shang S, Li X, Xie P, et al. Predictive

value of LDH kinetics in bevacizumab treatment and sur-

vival of patients with advanced NSCLC. OncoTargets and

therapy. 2018;11:6287.

12. Chen Z, Guo Q, Lu T, Lin S, Zong J, Zhan S, et al. Pretreat-

ment serum lactate dehydrogenase level as an indepen-

dent prognostic factor of nasopharyngeal carcinoma in

the intensity-modulated radiation therapy era. Medical

Science Monitor: International Medical Journal of Exper-

imental and Clinical Research. 2017;23:437.

13. Wang Y, Li G, Wan F, Dai B, Ye D. Prognostic value of

D-lactate dehydrogenase in patients with clear cell renal

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



H. Heidari Beigvand et al. 4

cell carcinoma. Oncology letters. 2018;16(1):866-74.

14. Karamanos Y. Purification and characterisation of lactate

dehydrogenase: an undergraduate biochemistry labora-

tory experiment. Adv Biochem. 2014;2(1):14-23.

15. Åkerström B, Rosenlöf L, Hägerwall A, Rutardot-

tir S, Ahlstedt J, Johansson ME, et al. rA1M-035,

a Physicochemically improved human recombi-

nant α1-microglobulin, has therapeutic effects in

rhabdomyolysis-induced acute kidney injury. Antioxi-

dants & redox signaling. 2019;30(4):489-504.

16. Qingying F, Liu R, Fagui H, Shan F, Lu M. Clinical analysis

in patients with rhabdomyolysis and acute kidney injury

caused by intense exercise. Chinese Journal of Postgrad-

uates of Medicine. 2018;41(10):904-8.

17. Green H, Tobar A, Gafter-Gvili A, Leibovici L, Klein T, Ra-

hamimov R, et al. Serum lactate dehydrogenase is ele-

vated in ischemic acute tubular necrosis but not in acute

rejection in kidney transplant patients. Progress in trans-

plantation. 2017;27(1):53-7.

18. Nara A, Yajima D, Nagasawa S, Abe H, Hoshioka Y, Iwase

H. Evaluations of lipid peroxidation and inflammation in

short-term glycerol-induced acute kidney injury in rats.

Clinical and Experimental Pharmacology and Physiol-

ogy. 2016;43(11):1080-6.

19. Vikrant S, Jaryal A, Gupta D, Parashar A. Epidemiology

and outcome of acute kidney injury due to venomous an-

imals from a subtropical region of India. Clinical toxicol-

ogy. 2019;57(4):240-5.

20. Nishimura H, Enokida H, Kawahira S, Kagara I, Hayami

H, Nakagawa M. Acute kidney injury and rhabdomyolysis

after Protobothrops flavoviridis bite: a retrospective sur-

vey of 86 patients in a tertiary care center. The American

journal of tropical medicine and hygiene. 2016;94(2):474-

9.

21. Alzahri MS, Mousa SA, Almomen AM, Hasanato RM, Poli-

meni JM, Racz MJ. Lactate dehydrogenase as a biomarker

for early renal damage in patients with sickle cell disease.

Saudi Journal of Kidney Diseases and Transplantation.

2015;26(6):1161.

22. Bennett MR, Nehus E, Haffner C, Ma Q, Devarajan P. Pe-

diatric reference ranges for acute kidney injury biomark-

ers. Pediatric nephrology. 2015;30(4):677-85.

23. Zager RA, Johnson AC, Becker K. Renal cortical lactate de-

hydrogenase: a useful, accurate, quantitative marker of

in vivo tubular injury and acute renal failure. PloS one.

2013;8(6):e66776.

24. Ma L, Qiu J, Zhang Y, Qiu T, Wang B, Chen W, et al. Prog-

nostic factors for operable biliary tract cancer: serum lev-

els of lactate dehydrogenase, a strong association with

survival. OncoTargets and therapy. 2018;11:2533.

25. Weide B, Elsässer M, Büttner P, Pflugfelder A, Leiter U,

Eigentler T, et al. Serum markers lactate dehydrogenase

and S100B predict independently disease outcome in

melanoma patients with distant metastasis. British jour-

nal of cancer. 2012;107(3):422-8.

26. Gurkan S, Scarponi KJ, Hotchkiss H, Savage B, Dracht-

man R. Lactate dehydrogenase as a predictor of kidney

involvement in patients with sickle cell anemia. Pediatric

nephrology. 2010;25(10):2123-7.

27. Mohammadi-Karakani A, Asgharzadeh-Haghighi S,

Ghazi-Khansari M, Hosseini R. Determination of uri-

nary enzymes as a marker of early renal damage in

diabetic patients. Journal of clinical laboratory analysis.

2007;21(6):413-7.

28. Huang C-C, Lo H-C, Huang H-H, Kao W-F, Yen DH-T,

Wang L-M, et al. ED presentations of acute renal in-

farction. The American journal of emergency medicine.

2007;25(2):164-9.

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



5 Archives of Academic Emergency Medicine. 2021; 9(1): e24

Table 1: Characteristics and findings of included studies

Characters* Title Findings
Sanjay et al, 2019 (19). India,

N = 181,Clinical trial
Epidemiology and outcome of

acute kidney injury due to
venomous animals from a
subtropical region of India

Compared to the survival group, serum white blood cells, serum
bilirubin, aspartate aminotransferase, alanine aminotransferase,

creatine kinase, lactate dehydrogenase, and serum albumin levels were
significantly higher in patients who died. The proportion of patients with

leukocytosis, hyperkalemia, metabolic acidosis, pneumonia / ARDS,
seizures / encephalopathy, need for ICU support, and dialysis was

significantly higher in patients who died.
Akerstrom, et al, 2019 (15).

Sweden, N = 87, Clinical Trial
rA1M-035, a Physicochemically
improved human recombinant

α1-microglobulin, has
therapeutic effects in

rhabdomyolysis-induced acute
kidney injury

In this study, the researchers noted that lactate dehydrogenase levels
show significant changes in acute renal failure due to rhabdomyolysis.

Qingying et al, 2018 (16).
China, N = 22, Cross sectional

Clinical analysis in patients with
rhabdomyolysis and acute kidney
injury caused by intense exercise

There was a significant relationship between elevated serum LDH levels
and acute renal failure. Intense exercise in summer is likely to cause

rhabdomyolysis and AKI. Early diagnosis and comprehensive treatment
including appropriate blood purification are crucial for a successful

treatment. The findings also emphasize the importance of age in muscle
injury and the monitoring of electrolytes, markers of muscle damage and

renal function for prevention of rhabdomyolysis and its related
complications.

Hefziba et al, 2017 (17). Israel,
N = 150, Cross sectional

Serum lactate dehydrogenase is
elevated in ischemic acute tubular
necrosis but not in acute rejection

in kidney transplant patients

A strong and statistically significant association between elevated serum
LDH 1 to 3 days before renal biopsy and ischemic ATN diagnosis after

kidney transplantation was confirmed.

Akina et al, 2017 (18). Japan,
N = 59, Case control

Evaluations of lipid peroxidation
and inflammation in short-term
glycerol-induced acute kidney

injury in rats

In this study, the researchers stated that there was a statistically
significant relationship between time and serum LDH levels and acute

renal failure.

Hiroak etal, 2016 (20). Japan,
N = 86, Cross sectional

Acute Kidney Injury and
Rhabdomyolysis After

Protobothrops flavoviridis Bite: A
Retrospective Survey of 86

Patients in a Tertiary Care Center

Systolic blood pressure, serum creatinine, serum creatine kinase, that
serum lactate dehydrogenase white blood cell count, and platelet count

differed significantly between the AKI and non-AKI groups (P = 0.01)

Alzahri et al, 2015 (21), Saudi
Arabia, N = 55, Clinical Trial

Lactate Dehydrogenase as a
Biomarker for Early Renal

Damage in Patients with Sickle
Cell Disease

This study shows that in sickle cell patients LDH correlates with
creatinine clearance and, therefore, LDH could serve as a biomarker to

predict renal insufficiency in these patients.

Bennett et al, 2015 (22). USA,
N = 368, Clinical Trial

Pediatric reference ranges for
acute kidney injury biomarkers

In this study, the researchers suggested that lactate dehydrogenase
marker could be useful in early detection of acute renal failure in

children.
Richard et al, 2013 (23).

Brazil, N = 45, Case control
Renal Cortical Lactate

Dehydrogenase: A Useful,
Accurate, Quantitative Marker of
In Vivo Tubular Injury and Acute

Renal Failure

The results indicate that renal cortical LDH assay is a highly accurate
quantitative technique for gauging the extent of experimental acute

ischemic and toxic renal injury. The fact that it avoids the limitations of
more traditional AKI markers implies great potential utility in

experimental studies, which require precise quantitation of tubule cell
death.

Yue et al, 2013 (13). China, N
= 192, Cross sectional

Aims to evaluate the prognostic
value of D - lactate dehydrogenase

in patients with kidney disease

Findings suggest that decreased LDHD expression may be a predictor of
poor prognosis in patients with renal failure and even renal cancer.

Weide et al, 2013 (25).
Germany, N = 855, Cross

sectional

Serum markers lactate
dehydrogenase and S100B predict
independently disease outcome

in melanoma patients with
distant metastasis

The researchers noted that changes in serum lactate dehydrogenase
levels were useful as a marker in the prognosis of soft tissue disease,

including kidney disease. In addition, complete metastasectomy has an
independent prognosis specifically for the patient subgroup with normal

LDH and S100B values.
Gurkan et al, 2010 (26). USA,

N = 40, Cross sectional
Aims to investigate lactate

dehydrogenase as a predictor of
kidney involvement in patients

with sickle cell anemia

Multivariate analysis revealed a significant correlation between
microalbuminuria and LDH level (p = 0.04) when controlled for age, sex,
eGFR, hemoglobin level, Fetal hemoglobin%, type of SCA, BMI, history of

transfusions, and reticulocyte count. In this pediatric SCA population,
LDH was found to correlate with the presence of microalbuminuria and

proteinuria. Further studies are needed to confirm LDH as an early
marker for the risk of kidney involvement among SCA patients.

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



H. Heidari Beigvand et al. 6

Table 1: Characteristics and findings of included studies

Characters* Title Findings
Mohammadi-Karakani et al,
2007 (27). Iran, N = 57, Case

control

Aim of urinary enzymes including
LDH as an early marker of kidney

injury in diabetic patients

Researchers have shown that LDH urine excretion can be useful in
assessing renal failure Patients with diabetes and confirmation of using

LDH as a routine screening test.
Huang et al, 2007 (28).
Taiwan, N = 20, Cross

sectional

The objective of the study was to
investigate initial clinical

characteristics that can suggest an
early diagnosis of patients with

acute renal infarction presenting
with flank and/or abdominal pain

in the emergency department
(ED).

There was a significant relationship between serum LDH and patient
urine and renal infarction. This study, delineated specific clinical

features for emergency physicians to raise their suspicion index for an
early diagnosis of patients with renal infarction, a disease which is

uncommon and is usually delayed or missed at initial ED presentation.

*Characters: authors, year, country, sample size, and type of study, respectively.
ARDS: Acute respiratory distress syndrome; ICU: intensive care unit; LDH: Lactate Dehydrogenase;
AKI: Acute kidney injury; LDHD: lactate dehydrogenase D; SCA: sickle cell anemia;
BMI: body mass index; eGFR: Estimated Glomerular Filtration Rate; ED: emergency department.

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem



7 Archives of Academic Emergency Medicine. 2021; 9(1): e24

Figure 1: Flow diagram of the present meta-analysis; CVD: Cardiovascular disease.

This open-access article distributed under the terms of the Creative Commons Attribution NonCommercial 3.0 License (CC BY-NC 3.0).
Downloaded from: http://journals.sbmu.ac.ir/aaem


	Introduction
	Methods
	Results
	Discussion
	Conclusion
	Declarations
	References