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- DOI 10.18231/j.ijcbr.2020.047
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CrossMark
- Citation
A study of uric acid levels in serum and pleural fluid as to differentiate between transudate and exudate in pleural effusion
- Author Details:
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Irigu V Kumar
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N Vani
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Kishore Y Jothula *
Introduction
Pleural Effusion is an excessive accumulation of fluid in pleural space and it is the common complication of many disease processes either local or systemic. Normally pleural space contains 0.1 to 0.2 mL/kg body weight of fluid.[1] Effusion is of two types; one is exudative and other one is transudative. In cases of transudative effusions there is no need for further investigations but in cases of an exudative effusions further investigations needed to make a proper diagnosis, to plan management and assess prognosis.[1]
Tuberculosis is the major public health problem in developing countries like India, and Pleura serves as the initial presentation in about 25% of adults as pleural effusion.[2] Tuberculous pleurisy is the second most common form of extra pulmonary tuberculosis and a common cause of pleural effusions in endemic areas of tuberculosis like India.[3] An estimated prevalence of pleural effusion in industrialized countries is 320 per 1,00,00 people with a distribution of aetiologies related to the prevalence of underlying disease.[4] Various causes of pleural effusion are tuberculosis (30%), malignancy (27%), heart failure (20%), pneumonia (18%), and cirrhosis (3%), and other connective tissue disorders. Nearly 2/3rd of malignant pleural effusions occur in women associated with breast and gynaecological malignancies. Pleural effusion associated with systemic lupus erythematous is common in women and pleural effusion with chronic pancreatitis is common in men, with majority of cases were due to alcohol abuse. Rheumatoid effusions also occur commonly in adults whereas in children, pleural effusion is due to an underlying pneumonitis.[5] Fetal pleural effusion was also been reported and under certain circumstances may be treated prior to the delivery.[6]
Distinguishing an exudate from transudate and diagnosing the aetiology of pleural effusion clinically with certainty is a challenging task for physicians. Various pleural fluid parameters have been used to identify the cause. This differentiation is commonly achieved using the Light’s criteria.[7] According to “Light’s criteria”, an exudate may contain one or more of the following, that is pleural fluid total proteins and serum total proteins ratio greater than 0.5, pleural fluid and serum Lactate Dehydrogenase (LDH) ratio greater than 0.6 or an absolute serum LDH more than 200IU/L. However, the Light’s criteria bear a very high sensitivity (98%) but a lower specificity (77%). Recently many new parameters like pleural effusion cholesterol, Pleural effusion to serum bilirubin ratio, Uric acid and pleural effusion malondialdehyde (MDA) have been reported, but none shows better sensitivity and specificity than light’s criteria.[8], [9], [10], [11]
Uric acid or 2,6,8-Trioxypurine [IUPAC name 7,9-Dihydro-1H-purine-2,6,8(3H) –trione] is a heterocyclic compound of carbon, nitrogen, oxygen and hydrogen with the formula C3H4N4O3 is a product of metabolic breakdown of purine nucleotides.[12] Levels of uric acid present more in transudative pleural fluid as compared to exudates.[13] The difference between protein levels in the serum and the pleural fluid is greater than 3.1 gm/dL and serum-effusion albumin gradient greater than 1.2 gm/dL also can indicate that the pleural effusion is most likely a transudative effusion.[14] LDH is an enzyme found in nearly all living cells and catalyses the conversion of lactate to pyruvic acid and Pyruvic acid to lactate, as it converts NAD+ to NADH and it is a reversible step. As it is released during tissue damage, it is a marker of common injuries and diseases such as heart failure.
As there is no reliable biomarker that allows a complete differentiation between transudates and exudates in pleural effusion, Uric acid with other parameters like Total proteins, LDH, Albumin with Light’s criteria will aid in the differentiation of pleural effusion with diverse aetiology. With this background, this study was undertaken to differentiate exudates and transudates in pleura by measuring uric acid level in serum and pleural fluid.
Materials and Methods
Study design
Hospital based cross sectional study.
Study setting
Government Chest hospital, Yerragadda, Hyderabad.
Study population
Patients admitted in Government Chest hospital, Yerragadda, Hyderabad.
Sample size
125 patients with exudative type of pleural effusion and 125 patients with transudative type of pleural effusion. Hence sample size is 250.
Inclusion criteria
Subjects of both sex with age group 20 years and above.
Subjects with pleural effusion.
Haemodynamically stable patients.
Exclusion criteria
Immunocompromised subjects
Pregnant women.
Patients with Trauma to chest wall.
Post-operative subjects.
Consent
An informed consent was taken from all the subjects. After fulfilling the inclusion and exclusion criteria and after prior consent from the subjects, clinical details were recorded and examination was done according to the proforma of the case sheet. A postero-anterior and lateral chest radiographs were done in all cases.
Sample collection
5ml of the venous blood was collected from all the study participants under aseptic conditions in a sterile plain bottle/vacutainer by using sterile disposable syringe. Sample is centrifuged at 3000rpm for 10 mins and serum was separated within two hours of collection of blood. Care was taken to prevent hemolysis of the sample. Lipaemic and icteric samples were discarded.5ml of pleural fluid sample was collected in a clean, sterile glass bottle.
Parameters analysed
Serum and Pleural fluid Uric acid by uricase / peroxidase method using semi-autoanalyzer.
Serum and Pleural fluid Total proteins using Colorimetric Biuret method-
Serum and Pleural fluid Albumin by Bromo-cresol-Green (BCG) method using Colorimetrically.
Serum and Pleural fluid LDH by an enzymatic End point method using Semi autoanalyzer.
Statistical analysis
Data was entered in Microsoft excel and analysis was done using SPSS statistical package version 23. Categorical data and continuous data was presented as proportion, mean with standard deviation. Student unpaired ‘t’ test was used to assess statistical significance between two means and p<0.05 was considered as significant.
Results
Majority (35.2%) of the participants were of age group 30 – 40 years and male (64%) ([Table 1]).
Mean age of participants with exudate type of pleural fluid is 34.77 years and transudate type of pleural fluid is 35.21 years ([Table 2]).
Mean serum uric acid level and pleural fluid uric acid level was higher in subjects with transudate type when compared to exudate type and the difference was found to be statistically significant (p=0.009, p=0.033) ([Table 3]).
Mean serum total protein level, serum albumin and pleural albumin level was higher in subjects with transudate type when compared to exudate type and the difference was found to be statistically significant (p=0.001). Mean pleural fluid total protein level, serum LDH and pleural fluid LDH level was higher in subjects with exudate type when compared to transudate type and the difference was found to be statistically significant (p=0.001) ([Table 4]).
Mean serum uric acid level and pleural fluid uric acid level was higher in subjects with transudate type when compared to exudate type and the difference was found to be statistically significant in both genders ([?] [Table 5]).
| Age group | Frequency | Percentage (%) |
| 20 – 30 years | 82 | 32.8 |
| 30 – 40 years | 88 | 35.2 |
| 40 – 50 years | 80 | 32 |
| Sex | Frequency | Percentage (%) |
| Male | 160 | 64 |
| Female | 90 | 36 |
| Pleural fluid | Frequency (%) | Mean age in years |
| Exudate | 125 (50) | 34.77 |
| Transudate | 125 (50) | 35.21 |
| Uric acid levels | Mean value in subjects with Exudate (n=125) | Mean value in subjects with Transudate(n=125) | p value |
| Serum | 4.898 ± 0.04 mg/dL | 7.626 ± 0.06 mg/dL | 0.009 |
| Pleural fluid | 2.494 ± 0.06 mg/dL | 10.27 ± 0.07 mg/dL | 0.033 |
| Biochemical parameters | Mean value in subjects with Exudate (n=125) | Mean value in subjects with Transudate (n=125) | p value |
| Serum Total proteins | 6.266 ± 0.04 gm/dL | 8.788 ± 0.07 gm/dL | 0.001 |
| Pleural fluid Total proteins | 4.983 ± 0.06 gm/dL | 3.739 ± 0.04 gm/dL | 0.001 |
| Serum LDH | 795.5 ± 5.844 IU/L | 349.7 ± 9.584 IU/L | 0.001 |
| Pleural fluid LDH | 640.9 ± 8.33 IU/L | 180.5 ± 4.18 IU/L | 0.001 |
| Serum albumin | 3.494 ± 0.06 gm/dL | 4.604 ± 0.08 gm/dL | 0.001 |
| Pleural fluid albumin | 2.714 ± 0.05 gm/dL | 2.99 ± 0.08 gm/dL | 0.001 |
| Gender | Uric acid levels | Pleural fluid Type | Number of subjects | Mean ± SD (mg/dl) | p value |
| Male | Serum | Exudate | 82 | 4.870 ± 0.55 mg/dl | 0.001 |
| Transudate | 78 | 5.941 ± 0.95 mg/dl | |||
| Pleural | Exudate | 82 | 2.545 ± 0.66 mg/dl | 0.003 | |
| Transudate | 78 | 3.703 ± 3.30 mg/dl | |||
| Female | Serum | Exudate | 43 | 4.953 ± 0.51 mg/dl | 0.001 |
| Transudate | 47 | 6.315 ± 1.06 mg/dl | |||
| Pleural | Exudate | 43 | 2.398 ± 0.85 mg/dl | 0.009 | |
| Transudate | 47 | 3.605 ± 2.90 mg/dl |
Discussion
Majority (35.2%) of the participants were of age group 30 – 40 years and male (64%). The study participants were divided into two groups based upon Light’s criteria. Group-1(Exudates) and Group-2(Transudates). Mean age of participants with exudate type of pleural fluid is 34.77 years and transudate type of pleural fluid is 35.21 years.
The current study found that mean serum uric acid level and pleural fluid uric acid level was higher in subjects with transudate type when compared to subjects with exudate type and the difference was found to be statistically significant (p=0.009, p=0.033) which reflects the usefulness of estimating uric acid levels in differentiating transudates from exudates. Low uric acid levels are demonstrated in exudative pleural effusion which is secondary to the local factors that play role on capillary permeability increased or lymphatic flow obstruction or decreased. But in transudates, there is imbalances in hydrostatic and oncotic forces without change in the capillary permeability.[15] Increased Uric acid in pleural fluid can be due to tissue hypoxia in which synthesis of uric acid synthesis is upregulated in tissue hypoxia and oxidative stress. Similar findings were observed in Jain A et al. study where uric acid level in pleural fluid of transudative pleural effusion is higher (9.25 ± 1.83mg/dl) than in exudative pleural effusion(4.81 ± 0.64 mg/dl).[12] Hazarika B et al. found an increased uric acid level in pleural fluid of transudative than exudative effusion and the optimum cut off level for pleural fluid uric acid was 5.35mg/dl.[16]
In the present study, it was observed that mean total serum protein level in participants with exudate type of pleural effusion was 6.266 ± 0.04 gm/dL and in participants with transudate type of pleural effusion was 8.788 ± 0.07 gm/dL and the difference was found to be statistically significant (p=0.001). It was also observed that mean total protein level in pleural fluid of participants with exudate type of pleural effusion was 4.983 ± 0.06 gm/dL and in participants with transudate type of pleural effusion was 3.739 ± 0.04 gm/dL and the difference was found to be statistically significant (p=0.001). The pleural fluid to serum total protein ratio was >0.5 in exudative condition, whereas it was <0.5 in transudative condition. Das AK et al. observed that, the pleural fluid to serum protein is 0.5 and in this study 23 cases were exudates and 17 cases were transudative type of effusion which is similar to our study.[17] Pergulwar A et al. explained that, the total proteins levels are increased in tubercular pleural effusion due to increased permeability of capillaries by delayed hyper sensitivity reaction. This causes Inflammation of the pleura, and leakage of proteins from the pleural capillaries into the pleural space, thus total protein level increases.[15]
Measurement of LDH activity and it’s isoenzymes in serum and in pleural fluid specially in Broncho Alveolar Lavage fluid will aid as indicators of lung damage or inflammation.[18] In the present study, it was observed that mean serum LDH level in participants with exudate type of pleural effusion was 795.5 ± 5.844 IU/L and in participants with transudate type of pleural effusion was 349.7 ± 9.584 IU/L and the difference was found to be statistically significant (p=0.001). It was also observed that mean LDH level in pleural fluid of participants with exudate type of pleural effusion was 640.9 ± 8.33 IU/L and in participants with transudate type of pleural effusion was 180.5 ± 4.18 IU/L and the difference was found to be statistically significant (p=0.001).Das AK et al in their study concluded that LDH is useful in differentiating transudates and exudates in pleural effusion.[17]
In the current study, it was observed that mean serum albumin level in participants with exudate type of pleural effusion was 3.494 ± 0.06 gm/dL and in participants with transudate type of pleural effusion was 4.604 ± 0.08 gm/dL and the difference was found to be statistically significant (p=0.001). It was also observed that mean albumin level in pleural fluid of participants with exudate type of pleural effusion was 2.714 ± 0.05 gm/dL and in participants with transudate type of pleural effusion was 2.99 ± 0.08 gm/dL and the difference was found to be statistically significant (p=0.001). According to Palange P et al. study, in Serum to pleural fluid albumin gradient, Serum Albumin- Pleural fluid Albumin level of 1.2gm/dl or less indicates Exudates and greater than 1.2gm/dl indicates Transudates. In Serum to pleural fluid protein gradient serum Protein levels of 3.1gm/dl or less indicates Exudates and greater than 3.1gm/dl indicates Transudate.[19]
The present study also observed that mean serum uric acid level and pleural fluid uric acid level was higher in subjects with transudate type when compared to exudate type and the difference was found to be statistically significant in both genders. These findings highlight the importance of assessing uric acid levels in differentiating transudate and exudate type of pleural fluid.
Conclusion
There is multifactorial aetiology in the development of pleural effusion, it is important to differentiate transudates and exudates in pleural effusion to establish clear diagnosis. Uric acid is relatively better predictive, simple and cost ineffective to the patient and can do easily by using blood and pleural fluid samples from the subjects with pleural effusion with diverse aetiology. Total proteins, LDH, Albumin play a role in association with Uric acid and are supportive to Light’s criteria in the differentiation of transudates and exudates in pleural effusion. Hence, Uric acid levels can be a better biomarker to differentiate transudate and exudative pleural effusion easily, to diagnose and for better management of the patient.
Acknowledgement
The authors were grateful to all the participants who had participated in the study.
Source of Funding
None.
Conflict of Interest
None Declared.
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