
























































Archives of Academic Emergency Medicine. 2022; 10(1): e63

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

Lactate Dehydrogenase to Albumin ratio as a Predictive
Factor of COVID-19 Patients’ Outcome; a Cross-sectional
Study
Nafiseh Alizadeh1, Fatemeh-sadat Tabatabaei2, Amirali Azimi3∗, Neda Faraji4 †, Samaneh Akbarpour5,
Mehrnoush Dianatkhah6, Azadeh Moghaddas7

1. Department of Pharmaceutical Care, Baharlou Hospital, Tehran University of Medical Sciences, Tehran, Iran.

2. School of Medicine, Tehran University of Medical Sciences, Tehran, Iran.

3. Men’s Health and Reproductive Health Research Center, Shahid Beheshti University of Medical Sciences, Tehran, Iran.

4. Department of Internal Medicine, Baharlou Hospital, Tehran University of Medical Sciences, Tehran, Iran.

5. Occupational Sleep Research Center, Baharlou Hospital, Tehran University of Medical Sciences, Tehran, Iran.

6. Department of Clinical Pharmacy, Isfahan University of Medical Sciences, Isfahan, Iran.

7. Department of Clinical Pharmacy and Pharmacy Practice, School of Pharmacy and Pharmaceutical Sciences, Cancer Prevention Research
Center, Seyyed Al-Shohada Hospital, Isfahan University of Medical Sciences, Isfahan, Iran.

Received: June 2022; Accepted: July 2022; Published online: 15 August 2022

Abstract: Introduction: Despite the increasing vaccination coverage, COVID-19 is still a concern. With the limited health
care capacity, early risk stratification is crucial to identify patients who should be prioritized for optimal man-
agement. The present study investigates whether on-admission lactate dehydrogenase to albumin ratio (LAR)
can be used to predict COVID-19 outcomes. Methods: This retrospective cross-sectional study evaluated hos-
pitalized COVID-19 patients in an academic referral center in Iran from May 2020 to October 2020. The area
under the receiver operating characteristic (ROC) curve (AUC) was used to evaluate the value of LAR in the pre-
diction of mortality. The Yuden index was used to find the optimal cut-off of LAR to distinguish severity. Patients
were classified into three groups (LAR tertiles), first: LAR<101.46, second: 101.46≤LAR< 148.78, and third group:
LAR≥148.78. Logistic regression analysis was used to identify the association between tertiles of LAR, as well
as the relationship between each one-unit increase in LAR with mortality and ICU admission in three models,
based on potential confounding variables. Results: A total of 477 patients were included. Among all patients,
100 patients (21%) died, and 121 patients (25.4%) were admitted to intensive care unit (ICU). In the third group,
the risk of mortality and ICU admission increased 7.78 times (OR=7.78, CI: 3.95-15.26; p <0.0001) and 4.49 times
(OR=4.49, CI: 2.01-9.04; p <0.0001), respectively, compared to the first group. The AUC of LAR for prediction of
mortality was 0.768 (95% CI 0.69- 0.81). LAR ≥ 136, with the sensitivity and specificity of 72% (95%CI: 62.1-80.5)
and 70% (95%CI: 64.9-74.4), respectively, was the optimal cut-off value for predicting mortality. Conclusion:
High LAR was associated with higher odds of COVID-19 mortality, ICU admission, and length of hospitalization.
On-admission LAR levels might help health care workers identify critical patients early on.

Keywords: Serum Albumin; L-Lactate Dehydrogenase; COVID-19; Prognosis; Emergency Service, Hospital

Cite this article as: Alizadeh N, Tabatabaei F-S, Azimi A, Faraji N, Akbarpour S, Dianatkhah M, Moghaddas A. Lactate Dehydrogenase to

Albumin ratio as a Predictive Factor of COVID-19 Patients’ Outcome; a Cross-sectional Study. Arch Acad Emerg Med. 2022; 10(1): e63.

https://doi.org/10.22037/aaem.v10i1.1646.

∗Corresponding Author: Amirali Azimi; Men’s Health and Reproductive
Health Research Center, Shohada Tajrish Hospital, Tehran, Iran. Email: az-
imi.amirali96@gmail.com aa-azimi@alumnus.tums.ac.ir, Tel: (+98) 910 140
7012, ORCID: https://orcid.org/0000-0001-7801-7855.

† Corresponding Author: Neda Faraji; Department of Internal Medicine,
Baharlou Hospital, Tehran University of Medical Sciences, Tehran, Iran.
Email: Nedafaraji1368@gmail.com, Tel: (+98) 919 268 6990, ORCID:

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N. Alizadeh et al. 2

1. Introduction

The most recent global pandemic, Coronavirus disease 2019

(COVID-19), is an infectious disease caused by the severe

acute respiratory syndrome coronavirus 2 (SARS-CoV-2).

Based on the recent worldwide analysis of COVID-19, more

than 5 million attributable deaths were reported till Novem-

ber 2021 (1).

The symptoms of COVID-19 vary in a wide range, from a mild

illness to a life-threatening condition. The disease can even

be asymptomatic, while the most common clinical symp-

toms are cough, fever, myalgia, and gastrointestinal symp-

toms (2, 3). COVID-19 can also cause severe organ failures

such as acute cardiac injury, acute kidney injury, acute liver

injury, and the most known among all, acute respiratory dis-

tress syndrome (ARDS). These conditions can lead the pa-

tients to a critical state, which requires intensive care unit

(ICU) admission and also, in some cases, can cause death

(4, 5). Outcomes of COVID-19 patients mainly depend on

the severity of the disease. Most individuals with a mild ill-

ness had good prognosis (6, 7), while the mortality among

critically ill patients was very high (8). According to pub-

lished data on COVID-19, the mortality rate among severely

infected individuals was up to 49% (9). Generally, in sep-

tic patients with acute respiratory failure and multiple organ

failure, the mortality may increase up to 35-46% and 60-98%,

respectively (10-12).

There have been numerous studies investigating factors al-

lowing the prediction of COVID-19 severity. Some demo-

graphic characteristics, a wide range of comorbidities, and

many laboratory biomarkers were related to the severity and

mortality of COVID-19 (13-16).

As a negative acute-phase protein, albumin promotes the

formation of anti-inflammatory substances, so it plays an es-

sential role in the prognosis of patients with inflammatory

events and inhibition of disease progression (17, 18). Some

previous studies have demonstrated that in non-surviving

patients with sepsis, albumin levels are lower (19).

Since blood lactate dehydrogenase (LDH) level can be de-

termined rapidly as a marker of tissue hypoperfusion, it is

widely used in the early risk classification of critical patients

admitted to the emergency department (20). Similarly, sev-

eral studies have shown that reduced serum albumin (Alb)

levels and increased lactate dehydrogenase are associated

with COVID-19 severity (21-23). Scientists have believed

that lactate dehydrogenase to albumin ratio integrates multi-

organ failure, chronic disease, inflammatory, and nutritional

https://orcid.org/0000-0002-9599-4575.

factors, which may provide more valuable information than

the predictive value of either lactate dehydrogenase or albu-

min alone (24); however, this has not been sufficiently inves-

tigated.

Despite the increasing vaccination coverage worldwide,

COVID-19 is still a concern, especially in developing coun-

tries. Therefore, early risk stratification is crucial for identi-

fying critical patients who should be prioritized for optimal

management and allocating the limited human and techni-

cal resources to the suitable patients (25). The present study

aims to investigate whether on-admission lactate dehydro-

genase to albumin ratio (LAR) levels can be used as a reliable

predictor for clinical outcomes in patients with COVID-19.

2. Methods

2.1. Study design and patients

This retrospective cross-sectional study, was conducted on

hospitalized patients with clinical manifestations of COVID-

19 and a positive COVID-19 polymerase chain reaction (PCR)

test or chest computed tomography scan (CT-scan) findings

consistent with COVID-19, from 1st May 2020 to 31st October

2020, in the Baharloo Hospital affiliated with Tehran Univer-

sity of Medical Sciences, Tehran, Iran. The current study was

performed under the tenets of the Declaration of Helsinki.

All patients were anonymized during the data collection pro-

cess, and due to the study’s retrospective nature, informed

consent was waived. Ethical feasibility was obtained from the

Ethics Committee of Tehran University of Medical Sciences,

number IR.TUMS.VCR.REC.1399.148.

2.2. Participants

Patients under 18 years old, with history of the previous

COVID-19, and missing data of LDH or Alb in the first 48

hours of hospital admission were excluded. Since the data

bank was used, the sample size was not calculated. None of

the patients had been vaccinated against COVID-19, as the

data gathered for this study belong to the period when vacci-

nation had not started in Iran.

2.3. Data collection

Demographic information (age, sex), comorbidities, initial

presentations, type of treatment, laboratory data in the first

48 hours of admission, and outcomes were collected from the

medical records. Only the first test value was included if there

were multiple laboratory test values.

The co-existing diseases were hypertension (HTN), dia-

betes mellitus (DM), coronary heart disease (CHD), previ-

ous stroke, chronic obstructive pulmonary disease (COPD),

chronic kidney disease (CKD), cancer, rheumatoid disease,

and hypo/hyperthyroidism. Patients were asked if they had

ever been informed of having a diagnosis of any mentioned

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3 Archives of Academic Emergency Medicine. 2022; 10(1): e63

comorbidities.

The patients were asked if they had experienced fever, chills,

myalgia, anorexia, nausea, vomiting, and diarrhea. Accu-

rate temperature measurement was also done within the first

24 hours of hospital admission to determine if fever was

present.

Laboratory results included White Blood Cell (WBC) count,

Neutrophil count, Lymphocyte count, Neutrophil to Lym-

phocyte ratio (NLR), Hemoglobin (Hb), Platelets count (PTL),

C-reactive-Protein (CRP), Erythrocyte Sedimentation Rate

(ESR), Blood Sugar (BS), Blood Urea Nitrogen (BUN), Al-

bumin (Alb), Creatinine (Cr), and Lactate Dehydrogenase

(LDH).

The clinical chemistry laboratories at the hospital evaluated

the blood samples with standard procedures. Venous blood

samples were collected in tubes, including ethylenediamine

tetra-acetic acid. Serum LDH level was measured using

the Hitachi 911 automatic chemistry analyzer (Roche). The

LDH concentration was presented as units per liter (U/L).

Blood samples were centrifuged at 3000 rpm for 10 min at

room temperature. Serum Alb level was measured using

Bromocresol green method and Latex coagulating nephelo-

metric assay. Given that the half-life of albumin is about

25 days, Alb level was included in the study if measured in

the first 48 hours of hospital admission. Other biochemical

markers were measured using standard methods.

All patients received nursing, nutritional, and respiratory

support. Some patients received non-invasive ventilation

(NIV ), such as nasal oxygen, while some ICU-admitted pa-

tients received invasive ventilation. Hydration, fever man-

agement, and pain control were considered. In addition,

conservative therapy was performed in patients with gas-

trointestinal symptoms such as nausea, vomiting, and diar-

rhea. Treatment of patients varied according to their clin-

ical conditions. Patients received medications, including

NSAIDs, IV Corticosteroids, oral antiviral drugs, and IV an-

tibiotics, according to the COVID-19 diagnosis and treatment

protocol designed by the Iran Ministry of Health.

A chest computed tomography (CT) scan was also done for

all patients. Bilateral and peripheral ground-glass opac-

ity (GGO), consolidation, reticular pattern, and air bron-

chogram on chest CT-scan were assumed to be COVID-19 in

patients with negative PCR test who had the typical clinical

manifestation of COVID-19 (26, 27).

The lactate dehydrogenase to albumin ratio was named LAR.

Patients were classified into three groups based on LAR levels

(LAR tertiles). The first group with LAR<101.46 (including 158

patients), the second group with 101.46 ≤ LAR < 148.78 (in-
cluding 159 patients), and the third group with LAR≥148.78
(including 160 patients).

All the information collection forms were checked for miss-

ing data by two researchers, independently. Less than 5% of

the total data was missing. Since this amount does not sig-

nificantly affect results, it was ignored.

2.4. Outcomes

Outcomes included the length of hospitalization, intensive

care unit (ICU) admission, and mortality.

2.5. Statistical Analysis

Quantitative variables were expressed as mean ± standard

deviation (SD) (quantitative variables with normal distri-

bution) or median and interquartile range (IQR) (quantita-

tive variables with non-normal distribution), and categor-

ical variables were presented as frequency and percentage

(number (%)). The chi-square (X2), one-way ANOVA, and the

Kruskal–Wallis test statistic were used to compare categori-

cal, quantitative, and skewed variables according to tertiles

of LAR.

Logistic regression analysis was used to identify the associ-

ation between tertiles of LAR, as well as the relationship be-

tween each one-unit increase in LAR with mortality and ICU

admission in three models, based on potential confound-

ing variables, which were significantly different between ter-

tiles of LAR. Model one adjusted for age, based on model

one, model two added sex, and model three further adjusted

for CKD, hyper/hypothyroid, IV Corticosteroids, oral antivi-

ral therapy, IV antibiotics, WBC, NLR, CRP, ESR, BS, O2, BUN,

and Cr. The first tertile of LAR was considered a reference

point. Follow-up duration was defined as the period be-

tween hospital admission and mortality, ICU admission, or

discharge. Kaplan-Meyer survival analysis was used to cal-

culate the probability of survival in each class of LAR. Since

some data on the time of mortality and ICU admission was

missing (in about 80 patients), the logistic regression was

used instead of Cox proportional hazard regression analysis.

Cox regression analysis was then repeated in a small sam-

ple of the population with complete data, and no changes

in results were observed. The receiver operating character-

istic (ROC) curve, and the area under the curve (AUC) were

used to evaluate the value of LAR in prediction of mortal-

ity. The Yuden index was used to find the optimal cut-off of

LAR to distinguish severity. All data were analyzed using Stata

16 software. The significance threshold was considered less

than 0.05 (P-value < 0.05).

3. Results

3.1. Baseline characteristics of studied cases

A total of 477 patients with COVID-19 were eventually found

eligible to enter the analysis. Patients were classified into

three groups based on LAR levels (LAR tertiles). The first

group with LAR<101.46 (including 158 patients), the second

group with 101.46≤LAR< 148.78 (including 159 patients), and

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N. Alizadeh et al. 4

Table 1: Comparing the demographics, initial symptoms, comorbidities, types of treatment, lab data, and outcome between patients with

lactate dehydrogenase to albumin ratio (LAR) < 101.46 (group 1), 101.46 ≤ LAR < 148.78 (group 2), and LAR ≥ 148.78 (group 3)

Variables Total (n=477) Group1 (n=158) Group 2 (n=159) Group 3 (n=160) P
Demographics
Age (years) 58.56(17.52) 56.21(18.67) 57.45(16.8) 61.98(16.61) 0.008
Male sex 263 (55.1) 78 (49.4) 84 (52.8) 101 (63.1) 0.037
Initial symptoms
Cough 314 (65.8) 106 (67.1) 112 (70.4) 96 (60) 0.133
Fever 248 (52) 77 (48.7) 82 (51.6) 89 (55.6) 0.466
Myalgia 160 (33.5) 54 (34.2) 56 (35.2) 50 (31.3) 0.738
Chills 142 (29.8) 44 (27.8) 50 (31.4) 48 (30) 0.780
Nausea 80 (16.8) 35 (22.2) 22 (13.8) 23 (14.4) 0.086
Anorexia 66 (13.8) 16 (10.1) 22 (13.8) 28 (17.8) 0.163
Vomiting 36 (7.5) 12 (7.6) 10 (6.3) 14 (8.8) 0.707
Diarrhea 30 (6.3) 12 (7.6) 10 (6.3) 8 (5) 0.635
Comorbidity
Hypertension 166 (34.8) 50 (31.6) 50 (31.4) 66 (41.3) 0.110
Diabetes mellitus 146 (30.6) 43 (27.2) 45 (28.3) 58 (36.3) 0.161
Chronic heart disease 86 (18) 25 (15.8) 27 (17) 34 (21.3) 0.414
History of stroke 42 (8.8) 13 (8.2) 11 (6.9) 18 (11.3) 0.375
Hyper/Hypothyroidism 18 (3.8) 3 (1.9) 5 (3.1) 4 (2.5) 0.037
COPD 13 (2.7) 6 (3.8) 4 (2.5) 3 (1.9) 0.563
Chronic kidney disease 12 (2.5) 1 (0.6) 2 (1.3) 9 (5.6) 0.008
Rheumatoid disease 9 (1.9) 1 (0.6) 5 (3.1) 3 (1.9) 0.259
Cancer 3 (0.6) 0 0 3 (1.9) 0.050
Treatments
NSAIDs 302 (63.3) 102 (64.6) 105 (66) 95 (59.4) 0.431
IV Antibiotics 228 (47.8) 57 (36.1) 72 (45.3) 99 (61.9) <0.0001
Oral antiviral 171 (35.8) 32 (20.3) 57 (35.8) 82 (51.3) <0.0001
IV Corticosteroids 109 (22.9) 20 (12.7) 32 (20.1) 57 (35.6) <0.0001
Laboratory data
WBC (109 /L) 7.54 ±5.57 7.22±3.69 6.36 ± 3.41 9.04 ± 8.00 <0.0001
Neutrophil (percentage) 74.39± 11.36 70.01 ± 10.25 73.77± 10.74 79.33± 11.14 <0.0001
Lymphocyte (percentage) 20.27± 10.69 24.47± 10.01 20.94± 10.80 15.45± 9.25 <0.0001
NLR 5.61± 5.15 4.03± 3.73 4.91± 4.05 7.86± 6.43 <0.0001
Hemoglobin (g/dL) 13.42± 10.35 13.11 ± 1.78 14.57± 17.71 12.59± 1.91 0.210

Platelet Count (109 /L) 211.90±92.57 218.21±96.47 200.34± 84.91 217.16± 95.39 0.155
CRP (mg/L) 47.82± 48.82 22.97± 25.07 54.64± 70.24 65.60± 25.20 <0.0001
ESR (mm/hour) 56.68± 29.78 43.34± 25.54 58.61± 29.13 67.94± 29.31 <0.0001
Blood Sugar (mg/dL) 151.44±80.57 138.24± 61.24 160.51±91.91 155.47±84.05 0.036
Oxygen Saturation (%) 90.38±7.21 91.86± 5.83 91.48± 4.89 87.82± 9.37 <0.0001
BUN (mg/dL) 44.63± 29.01 36.55± 19.98 41.10± 21.61 56.11± 38.09 <0.0001
Serum Creatinine (mg/dL) 1.26±0.68 1.10 ± 0.35 1.19± 0.62 1.48± 0.89 <0.0001
LDH (unit/L) 583.07±283.61 371.33± 62.85 515.33± 74.37 859.47±324.64 <0.0001
Albumin (g/dL) 4.22±0.56 4.60±0.36 4.27±0.46 3.80±0.56 <0.0001
Outcome
Mortality 100 (21) 13 (8.2) 19 (11.9) 68 (42.5) <0.0001
ICU admission 121 (25.4) 15 (9.5) 28 (17.6) 78 (48.8) <0.0001
Hospital stay (day) 6 (6) 6 (5) 6 (6) 8 (10) <0.0001
All data are reported as frequency (%), except for age and laboratory results, which are reported as mean ± standard deviation,
and hospital stay, which is reported as median (IQR). COPD: Chronic obstructive pulmonary disease; NSAIDs: Non-steroidal
anti-inflammatory drugs; IV: intravenous; WBC: White Blood Cell count; CRP: C-Reactive Protein; ESR: Erythrocyte Sedimentation Rate;
BUN: Blood Urea Nitrogen; LDH: Lactate dehydrogenase; NLR: Neutrophil to lymphocyte ratio; ICU: intensive care unit.

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5 Archives of Academic Emergency Medicine. 2022; 10(1): e63

Figure 1: Trend of mortality and intensive care unit (ICU) admission based on quantiles of lactate dehydrogenase to albumin ratio (LAR); P <

0.0001 for trend of mortality and P <0.0001 for trend of ICU admission.

Figure 2: A: Kaplan-Meier survival analysis of COVID-19 cases based on lactate dehydrogenase to albumin ratio (LAR); B: Predicting mortality

of COVID-19 cases using receiver operating characteristic (ROC) curve analysis for LAR in 136 cut-off point.

the third group with LAR≥148.78 (including 160 patients).
The mean age of patients was 58.56 (range: 41 – 76) years.

Two hundred and sixty-three patients (55.1%) were male.

Age and sex distribution were significantly different between

groups with different LARs (p = 0.008 and p = 0.037, respec-

tively). The demographic characteristics, initial symptoms,

comorbidities, types of treatment, and laboratory data are

shown in Table 1. The initial symptoms among all patients

were as follows: cough in 314 patients (65.8%), fever in 248

patients (52%), and the other symptoms had a lower preva-

lence. The groups were similar in terms of initial symptoms

(P > 0.05).

Hypertension (34.8%) and diabetes mellitus (30.6%) were the

most common comorbidities. Coexisting comorbidities, in-

cluding hyper/hypothyroidism and CKD, were significantly

different between groups with different LARs (p = 0.037 and

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N. Alizadeh et al. 6

Table 2: Multivariable logistic regression analysis for independent predictive factors of mortality and intensive care unit (ICU) admission

among COVID-19 cases after adjustment for potential confounding variables

Variables Group 1 (n=158) Group 2 (n=159) Group 3 (n=160) P* 1 unit change#
Mortality
Age 1 1.05 (0.44-2.51) 3.73 (1.65-8.62) <0.0001 1.02 (1.01-1.03)
Age and sex 1 1.52 (1.05-3.26) 7.90 (4.04-15.43) <0.0001 1.02 (1.01-1.03)
Multivariate 1 1.53 (0.73-3.25) 7.78 (3.95-15.26) <0.0001 1.01 (1.00-1.02)
ICU Admission
Age 1 2.04 (1.03-4.02) 8.54 (4.57-15.95) <0.0001 1.01 (1.00-1.01)
Age and sex 1 2.03 (1.03-4.02) 8.47 (4.52-15.88) <0.0001 1.01 (1.00-1.02)
Multivariate 1 1.45(0.65-2.21) 4.49 (2.01-9.04) <0.0001 1.02 (1.01-1.03)
*: P value for trend. #: 1-unit increase in LAR. All measures are presented as adjusted odds ratio with 95% confidence interval.
Group 1: LAR < 101.46, Group 2: 101.46 ≤ LAR < 148.78, and Group 3: LAR ≥ 148.78. LAR: lactate dehydrogenase to albumin ratio.

p = 0.008, respectively). The treatment of patients varied ac-

cording to the patients’ clinical condition. Use of IV corti-

costeroids, oral antiviral therapy, and IV antibiotics were sig-

nificantly different between groups with different LARs (p

<0.0001).

WBC, neutrophil count, NLR, CRP, ESR, BS, BUN, Cr, and

LDH were significantly increased among all laboratory re-

sults. In contrast, lymphocyte count, blood oxygen satu-

ration, and Alb were significantly decreased in groups with

higher LAR (p <0.0001).

3.2. Outcomes

The outcomes of the population study are shown in table

1. Among all patients, 100 patients (21%) died, 121 patients

(25.4%) were admitted to ICU, and 256 patients (53.6%) were

discharged. The median length of hospitalization was six

days. The mortality rate, ICU admission, and length of hos-

pitalization were significantly different between groups with

different LARs (p <0.0001).

After adjustment for CKD, hyper/hypothyroid, IV corticos-

teroids, oral antiviral therapy, IV antibiotics, WBC, NLR, CRP,

ESR, BS, O2, BUN, and Cr (based on potential confounding

variables, which were significantly different between tertiles

of LAR), in the third group, the risk of mortality increases 7.78

times (OR=7.78, CI (3.95-15.26)) compared to the first group

(P-value for trend < 0.0001).

Besides, the risk of ICU admission among the patients with

LAR ≥ 148.78 was 4.49 times (OR=4.49, CI (2.01-9.04)) com-
pared to those with LAR<101.46 (P-value for trend < 0.0001).

The results suggested that each one-unit increase in LAR in-

creases the risk of mortality and ICU admission 1.01 times

(1.00-1.02) and 1.02 times (1.02-1.03), respectively (Table 2).

The repetition of this analysis in the more-stratified LAR lev-

els (quantiles of LAR) indicated significantly higher mortality

(P-value for trend< 0.0001) and ICU admission (P-value for

trend < 0.0001) with increase in LAR. The trends of mortality

and ICU admission based on quantiles of LAR are shown in

figure 1.

The probability of survival based on tertiles of LAR was esti-

mated using Kaplan Meier method. As shown in figure 2, the

probability of survival increases with decrease in LAR, espe-

cially in the first fourteen days of hospital admission.

LAR was taken as a candidate for ROC analysis (figure 3).

The AUC of LAR was 0.7684 (95% CI 0.69- 0.81), which indi-

cates that LAR can be an accurate predictor of mortality (p <

0.0001). Using the Yuden index, LAR ≥ 136, with the sensitiv-
ity and specificity of 72% (95%CI: 62.1-80.5) and 70% (95%CI:

64.9-74.4), respectively, was the optimal cut-off value in pre-

dicting mortality (positive predictive value 38.7 (95%CI: 31.7-

46.1), negative predictive value 90.4 (95% CI: 86.4-93.5)).

4. Discussion

In the present study, the mortality rate, ICU admission, and

length of hospitalization were significantly increased in pa-

tients with higher LAR. LAR ≥ 136, with the sensitivity and
specificity of 72% and 70%, respectively, was the optimal pre-

dictive threshold for COVID-19 mortality.

With the limited health care capacity, numerous studies

have investigated factors allowing the prediction of COVID-

19 severity and mortality in the early stages. The prognos-

tic role of elevated CRP, ESR, BUN, and Cr has been high-

lighted in several investigations of COVID-19 progression (13,

14, 21, 22). Besides, previous studies indicated that older

age, one or more coexisting comorbidities, high WBC, el-

evated neutrophil count, elevated LDH, lower lymphocyte

count, and low serum Alb levels are associated with adverse

outcomes in patients with COVID-19 (28-30). The present

study’s findings showed that in patients with higher LAR,

lymphocyte count and serum albumin levels were signifi-

cantly decreased. In contrast, age, coexisting chronic kidney

disease and hyper/hypothyroidism, white blood cell count,

neutrophil count, NLR, CRP, ESR, BS, BUN, creatinine, and

LDH were significantly increased. Besides, in the current

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7 Archives of Academic Emergency Medicine. 2022; 10(1): e63

study population, the probability of survival decreased with

increase in LAR. In patients with LAR≥148.78, the risk of mor-
tality and ICU admission increased 7.78 and 4.49 times, re-

spectively, compared to those with LAR<101.46.

LDH and albumin are routinely tested and readily available

markers in many clinical practices. Since different mech-

anisms regulate these two biomarkers, LAR can reduce the

impact of a single factor on the regulation mechanism (24).

Several studies have examined the prognostic role of LAR in

many respiratory and infectious diseases.

LAR was independently associated with in-hospital death in

a Korean population of patients with severe infections requir-

ing intensive care (31). Similarly, the prognostic role of LAR

in patients with lower respiratory tract infection (LRTI) who

were admitted to an emergency department was explored by

Lee BK et al.; LAR was considered an independent prognostic

factor for in-hospital mortality in patients with LRTI (32). The

predictive value of LAR, particularly in patients with COVID-

19, has not been sufficiently investigated. In a recent study

conducted in China on 321 COVID-19 patients, LAR was sig-

nificantly associated with in-hospital death and had a high

specificity and sensitivity in differentiating critical patients

from mild ones (24).

In conclusion, to the best of our knowledge, the current study

is one of the first investigations to describe a cut-off value

for LAR as an influential predictor of COVID-19 severity and

mortality. These findings will help healthcare workers iden-

tify high-risk patients who should be prioritized and improve

COVID-19 survival.

4.1. Limitation

This study has certain limitations that have to be taken into

consideration. First, since this study was retrospective in na-

ture, it thus has innate limitations regarding selection bias.

Second, not all laboratory biomarkers with the potential for

prognosis have been obtained (such as D-Dimer and fer-

ritin). Third, we only included patients for whom LDH and

albumin were measured. Forth, all laboratory data were ob-

tained in the first 48 hours of hospital admission; thus, a sin-

gle measurement may have limited prognostic value, and ad-

ditional measurements may provide more reliable informa-

tion. Fifth, the data was collected from a single center, limit-

ing these results’ generalizability. In the future, further inves-

tigations with large populations, multiple centers, and con-

tinuous monitoring are required to describe the prognostic

role, diagnostic sensitivity, specificity, and positive and neg-

ative predictive values of LAR with more precision.

5. Conclusion

The mortality rate, ICU admission, and length of hospital-

ization were significantly increased in patients with higher

LAR. LAR ≥ 136, with the sensitivity and specificity of 72%
and 70%, was the optimal predictive threshold for COVID-19

mortality.

6. Declarations

6.1. Acknowledgments

None.

6.2. Authors’ contributions

Conceptualization: MD. Data curation: NA. Formal analysis:

SA. Funding acquisition: None. Methodology: SA, NA, NF. Vi-

sualization: FT, NF, NA, AA. Writing—original draft: FT, AA.

Writing—review, and editing: FT, AA, AM. All authors read

and approved the final draft.

6.3. Funding and supports

None.

6.4. Conflict of interest

The authors have no conflicts of interest to declare for this

study.

6.5. Data availability

Data of the study are available and will be provided if anyone

needs them.

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	Introduction
	Methods
	Results
	Discussion
	Conclusion 
	Declarations
	References