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Hepatorenal Profile Variations in Occupationally Exposed Domestic Painters

Biol_68_2_47-52

Research Article

Hepatorenal Profile Variations in Occupationally Exposed Domestic Painters

Saba Yasin, Kausar Imran, Komal Mukhtar, Muhammad Amir Iqbal and Nabila Roohi*

Institute of Zoology, University of the Punjab, Lahore, Pakistan.

Abstract | Effect of paint chemicals on liver and renal profile in occupationally exposed household painters was evaluated in this study. For this purpose, 25 healthy male controls and 25 male painters were selected from Lahore, Pakistan. Unpaired Student “t” test was applied to analyse the parameters for statistical interpretation. There was significant increase in Alanine Aminotransferae (ALT), Alanine Phosphatase (ALP) and total bilirubin in painters as compared to control group. However, Aspartate Aminotransferae (AST) was mildly increased in painters. Creatinine and urea exhibited significant elevation in painters as compared to controls. Conclusively, long-term exposure to paints and associated chemicals may lead to severe hepatic and renal damages.


Received | October 07, 2022;; Accepted | December 10, 2022;; Published | December 28, 2022

*Correspondence | Nabila Roohi, Institute of Zoology, University of the Punjab, Lahore, Pakistan; Email: [email protected]

Citation | Yasin, S., K. Imran, K. Mukhtar, M.A. Iqbal and N. Roohi. 2022. Hepatorenal profile variations in occupationally exposed domestic painters. Biologia (Pakistan), 68(2): 47-52.

DOI | https://dx.doi.org/10.17582/journal.Biologia/2022/68.2.47.52

Keywords | Painters, AST, ALT, Bilirubin, Creatnine, Urea

Copyright: 2022 by the authors. Licensee ResearchersLinks Ltd, England, UK.

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).



Introduction

Paints are combination of different solvents, pigments and additives. To give the paints its properties like dryness and hardening; pigments and additives are mixed that usually does not completely solubilize in paints rather they remain suspended in it to form emulsions (Mwatu, 2011). Moreover, paints provide, beauty, protection against corrosion, insulation against electricity and fire proofing. There are variety of ways by which paints can be applied like using brush, roller, spray, disk spraying and powder coating (Handbook of Occupational Safety and Health, 1999).

There are 2.9 billion workers worldwide who are exposed to different chemicals at various work sites. Each year, about 120 million occupational accidents and 200,000 deaths are reported in developing countries (Tadesse et al., 2016). During working hours, workers have to face a lot of occupational risks including chemical agents, physical factors, biological agents and adverse ergonomic conditions. These circumstances may lead towards multiple health risks (Awodele et al., 2014).

About 140 large scale and around 2000 smaller units of paint production are operating in Pakistan. Major demands of country come from institutes of defence, shipyards, dams and railways (National Report, 2017). Data regarding the number of painters in paint industry and the effect of exposure is still scarce in Pakistan.

Spray painting creates paint mist that rapidly fills the space around paint operation and when they come in contact with any kind of ignition source like spark or cigarette, they immediately catch fire (Occupational Safety and Health Branch Labour Department, 2003).

Harmful contents of paints can get entry into the body through inhalation, skin, eye-contact and accidental ingestion, hence, accumulating in different vital organs like liver, kidney and various other lymphatic regions. Serious health outcomes may occur in regions away from the site of contact (Kumar and Gothesfeld, 2008).

Commonly used lead paints are lead carbonates and lead chromates. Lead speeds up the process of drying, enhances durability and fights off the moisture that is responsible for corrosion (Kumar and Gothesfeld, 2008). Lead is a toxicant and it is also known as “The Silent epidemic” (Clark et al., 2006) and can cause disturbances in liver functioning (Chuhitha et al., 2014). Paints containing benzene can also induce hepatic injury (Uzma et al., 2008).

The liver is the main target organ of the chemical induced injury, due to its unique position in the circulatory system. Since, it is the major organ for chemical transformations, hence, any toxicant that get entry into the liver tissue disturbs its biosynthetic machinery (Soyinka et al., 2007; Malaguarnera et al., 2012). Severity of toxicity depends on several factors like quantity of chemicals, duration of exposure and either chemical is present alone or in form of complex (Jones and Kennedy, 1988).

Liver produces several enzymes that can be used as a marker to find liver injury. Serum alanine aminotransferase (ALT), aspartate aminotransferase (AST), alkaline phosphatase (ALP) and total bilirubin are routinely used in both clinical analysis and research purposes, any deviation in these biomarkers can disturb the normal liver metabolism (Senior, 2012).

Urea and creatinine are very good indicators of renal health status (Fliser et al., 2012). Kidneys play vital role in their filtration. About 90% of creatinine is filtered by the glomerulus in kidney of healthy individuals but it gets disturbed due to structural damages in the kidney tubules due to long-term exposure of chemicals (Pimenta et al., 2016).

In this regard, present study is an endeavour to investigate the hazardous effects of continuous exposure of paint chemicals on hepatic and renal profile of painters.

Materials and Methods

For blood sampling, healthy males (n=25) with age ranging from 23-42 were selected from the Department of Zoology, University of the Punjab, Lahore, Pakistan. Similarly, healthy painters (n= 25) with no any previous medical history, having 10-15 years period of exposure to paints and age ranging from 25-65, were recruited from local paint market, Lahore Pakistan. A proforma was designed to collect demographic information, anthropometric measurements, presence or absence of disease, smoking or drinking habits, etc. Subjects with any kind of disease were excluded from both groups. Fasting of at least 12 hours was necessary for taking blood samples of both groups. A registered technician was hired to collect the blood.

Afterwards further blood processing was performed to separate the serum. Blood samples were centrifuged at the rate of 3000 rounds per minute for at least 10 minutes. Clear serum was placed in labelled Eppendorf and stored in refrigerators at -20 degree. Samples were thawed at room temperature for further biochemical analysis. Serum samples of painters and control group were analysed to evaluate liver and renal profile including ALT, ALP, AST, total bilirubin, creatinine and urea by means of Clinical Chemistry Analyser Photometer (Model 5010 Robert Riele GmbH and Co. KG. D-13467. Berlin, Germany) using commercially available kits of DiaSys, Diagnostic System.

Statistical analysis

Statistical analysis was done by Graphpad Prism (Version 6.0) and data was presented as mean ± SEM. Variations between two groups were compared at significance level of 0.05, CI: 95% by applying two tail Unpaired Student “t” test.

Results and Discussion

The results of present study have shown a significant increase in parameters of liver profile i.e., ALT (P=0.006), ALP (P=0.03) and total bilirubin of painters when compared with control group. Moreover, AST (P=0.3) of painters was non-significantly increased. Marked elevation (P<0.0001) of Total bilirubin was present in painters as compared to control group. Urea and creatinine have shown significant rise P=0.04, 0.03 in painters as compared to control group, respectively. Mild elevation was present in systolic (SBP) and diastolic blood pressure (DBP) of painters as compared to control group (Figure 1, Table 1).

Serum ALT levels of painters were significantly elevated when compared with control group. There was mild increase in serum AST of painters. Further, serum ALP level was significantly increased in painters as compared to control group and total bilirubin of painters was also significantly increased in this study.

Liver enzymes mainly reside inside the liver cells but after liver damage these enzymes begin to leak into the blood stream, thus elevation in the levels of ALT in the blood indicates liver damage (Dafour et al., 2000). If the liver is damaged, ALT level in blood can be increased by 50 folds (Huang et al., 2006).

The elevated liver enzymes may be due to paint constituents like lead, cadmium, chromium, toluene, benzene etc. which are a potential source of risk for painters’ health (U.S. Army Public Health Command, 2011). Toluene when gets entery into the body, it generates free radicals in liver during its biotransformation resulting in the increased level of serum liver enzymes ultimately leading to liver damage (Moro et al., 2012).

Moreover, benzene being a vital paint constituent can induce hepatic injury, detected by elevated levels of serum liver enzymes as their leakage depicts malformed liver (Uzma et al., 2008). Previous investigations have also documented prominent increase in serum levels of ALT and ALP due to exposure to benzene (Fayed et al., 2017). Physicoochemical properties of benzene include low evaporation temperature and vapor pressure that is responsible for its direct incorporation into the atmosphere (Uzma et al., 2008). Inhalation is the chief route of entry of benzene in the body and the liver is the main location of its metabolism. Depending upon the concentration of benzene, exposure time and pulmonary ventilation humans can absorb 30-52% of inhaled benzene (Snyder and Hedli, 1996).

 

Table 1: Average values of liver and renal profile of painters and control group.

Parameters

Control (N= 25)

Painters (N= 25)

P-value

% difference

ALT (U/L)

23.40 ±1.54

30.24±1.86

0.006

29↑**

AST (U/L)

25.68±1.35

27.24±1.20

0.3

6↑

ALP (U/L)

162.2±10.92

191.1±7.33

0.03

18↑*

Total Bilirubin (mg/dL)

0.40±0.35

0.58±0.01

˂0.0001

45↑***

Urea (mg/dL)

23.60 ± 4.64

26.28 ± 4.39

0.04

11.35 ↑*

Creatinine (mg/dL)

0.84 ± 0.11

0.91 ± 0.12

0.03

8.33 ↑*

Systolic (mmHg)

132.8 ± 3.61

135.0 ± 3.61

0.53

2 ↑

Diastolic (mmHg)

87.52 ± 1.82

93.16 ± 2.73

0.09

6.44 ↑

 

*, **, *** represents significance at P < 0.05, 0.01 and 0.001, respectively. represents increase in values of parameters.

 

In our investigation, total bilirubin of painters was also significantly increased. Lead causes oxidative stress by generating reactive oxygen species (Clark et al., 2006). These free radicals cause lipid peroxidation of membrane of red blood cell (RBCs) causing breakdown of RBCs (Saxena and Flora, 2004). As bilirubin is formed by breakdown of RBCs in several events which involves breakdown of heme portion of blood cells into biliverdin in the presence of heme oxygenase. Biliverdin is further converted into bilirubin (non-conjugated) in presence of biliverdin reductase. This non-conjugated bilirubin after combining with albumin enters in liver where glucuronic acid is attached with it thus, forming conjugated bilirubin which then moves to intestine. From intestine bilirubin gets absorbed in blood and some of its proportion also removed from the body (Agarwal and Deorari, 2002). So, when the free radicals increase in body, breakdown of RBCs takes place resulting in increasing total bilirubin in blood.

In the present study, renal profile assessment has shown that urea level is significantly increased in painters as compared to control group. Urea is a by- product of protein metabolism and excreted by kidneys. Increased serum urea level indicates impaired renal functioning which may be due to the renal tubular necrosis (Jacob et al., 2007).

In our study, the significant increase in serum creatinine was evidenced in painters. This elevated serum creatinine can be a manifestation of disturbed renal functioning. Structural damages in the glomerular part of the nephron hinder normal filtration process, thus reducing the creatinine clearance leading to its elevated state (Samra et al., 2012).

Although, hepatic parameters like ALT, AST, ALP and total bilirubin of painters are more than that of control group but still these parameters are within the normal range. Hence, it cannot be said that the painters have any kind of serious liver ailment because of exposure to paints but if the exposure goes unchecked, it could cause severe liver damage (liver cirrhosis) and jaundice.

The renal profile alterations have also indicated that occupational painters are at risk of developing renal impairment due to prolonged and unchecked exposure of paint chemicals.

Conclusions and Recommendations

Conclusively, prolonged exposure to paint chemicals affects adversely the hepatorenal functions resulting in severe health problems.

Painters should get regular medical check-up. Government should educate and implement SOPs regarding the workplace environments to minimize the health issues associated with paints through print and social media. Further research is required to find out the mechanism of liver and renal damages caused by the exposure to paint chemicals so that reasonable medical procedures could be employed to address the issues.

Acknowledgement

Authors of present investigation gratefully acknowledge Institute of Zoology for providing the opportunity and facilities for present research.

Novelty Statement

This study reflects significant changes in hepatorenal profile of occupationally exposed household painters. However, precautionary measures can reduce the risk associated with exposure.

Author’s Contribution

Saba Yasin and Kausar Imran: Helped in biochemical analysis of hepatic profile.

Komal Mukhtar: Helped in arranging experiment.

Muhammad Amir Iqbal: Helped in statistical analysis.

Nabila Roohi: Supervision of study.

Conflict of interest

The authors have declared no conflict of interest.

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