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Indian Journal of Occupational and Environmental Medicine
Medknow Publications
ISSN: 0973-2284 EISSN: 1998-3670
Vol. 11, Num. 2, 2007, pp. 65-70

Indian Journal of Occupational and Environmental Medicine, Vol. 11, No. 2, May-August, 2007, pp. 65-70

Original Article

Biochemical profile of gin women laborers in Tirupur

Jannet, J.V.; Jeyanthi, G.P.

School of Biotechnology, Karunya University, Coimbatore - 641 114, Tamilnadu
Correspondence Address:School of Biotechnology, Karunya University, Coimbatore - 641 114, Tamilnadu, jannetruban@rediffmail.com

Code Number: oe07014

Abstract

Ginning factories discharge large amounts of cotton dusts that lead to decreased pulmonary function in the exposed subjects. An attempt was made to study the biochemical profile of women laborers employed in ginning factory located in Tirupur, a textile based city in Coimbatore district of Tamilnadu, India. The blood parameters that were analyzed were hemoglobin, total and differential count of leucocytes, erythrocyte sedimentation rate (ESR), total proteins, immunoglobulins, total and isozymic content of lactate dehydrogenase (LDH) and histamine. Student's 't' test was carried out to compare the results with the control women. Correlation analysis was done between/within the biochemical parameters and also between the pulmonary function parameters results reported earlier by Jannet and Jeyanthi. Significant changes in the levels of hemoglobin, ESR, immunoglobins and histamine were reported in this study. Correlation studies between the pulmonary function parameters and biochemical parameters revealed significant negative correlation of FVC, FEV₁ and PEF with ESR ( P <0.05). There was also positive correlation between immunoglobin G and histamine. A significant negative correlation was observed between LDH1 and LDH3 and between albumin and γ globulin. The study suggested that the ginning factory women laborers exhibited significant changes in the levels of certain biochemical parameters apart from the pulmonary functional changes.

Keywords: Biochemical profile, gin laborers, pulmonary function parameters

Introduction

Cotton ginning and pressing have been identified as traditional industries under the unorganized sector which functions on a seasonal basis. Tirupur, a textile city in Coimbatore district of Tamilnadu, is the major exporter in cotton garments and ranks second to Coimbatore city where 18 ginning factories are situated employing 1500 laborers. Women are the major employees in these ginning factories.^[1] Studies have reported a high prevalence of pulmonary abnormalities together with respiratory symptoms in these ginning factories. No detailed study has been conducted so far in these ginning factory women laborers to assess their biochemical profile with relation to the pulmonary dysfunction. Blood is a part of the circulatory system of the body and has several functions. Much valuable information can be readily obtained from hematologic tests. A wide variety of pulmonary diseases like asthma and other lung dysfunctions may show signs or symptoms of a hematologic disease like anemia, eosinophilia and are highly associated with air pollutant hazards.^[2] Pulmonary function tests supported by blood picture might confirm the clinical conditions of an individual. So the present study was aimed to study the biochemical profile of women laborers in a selected ginning factory at Tirupur and to associate its possible correlation between pulmonary dysfunction.

Materials and Methods

Selection of subjects
This study was carried out in continuation of the earlier work done by Jannet and Jeyanthi^[1] in a ginning factory located at Tirupur where 104 women laborers formed the experimental group and forty age and sex matched women of similar economic status were selected as controls. The mean age of the experimental group was 55 years with mean working experience of 12 years. Physical examination of respiratory health of workers and control group were conducted in accordance with recommendations outlined in the Declaration of Helsinki. According to Jannet and Jeyanthi^[1] study reports, among the 104 experimental group participants, 65.7% manifested byssinotic symptoms, 23.7% with chronic bronchitic symptoms and 10.53% with occupational asthmatic symptoms. They have also showed that there was significant reduction in pulmonary function parameters in these women when compared to the control women - (forced vital capacity (FVC): Z = 2.02, significant at 5% level, forced expiratory volume in one second (FEV₁ ): Z = 3.45, significant at 1% level, peak expiratory flow (PEF): Z = 4.76, significant at 1% level), which suggests chronic lung obstruction. With continuation of the above findings, the analysis of selected biochemical parameters were carried out in the experimental and control women.

Analysis of biochemical parameters
5.0 ml of venous blood samples were collected from 104 experimental group and 40 control women for the estimation of blood parameters that included hemoglobin content, total and differential count of leucocytes, erythrocyte sedimentation rate (ESR), total proteins, immunoglobins, total and isozymic content of lactate dehydrogenase (LDH) and histamine.

The hemoglobin content of the experimental and control women were estimated by converting hemoglobin to cyanmethmoglobin and treatment with Drabkin′s solution and colorimetrically estimating the color developed at 540 nm. The values were expressed in grams/dl.^[3] The total leucocyte count (TC) was found by accurately diluting the blood suspension and enumerating the leucocyte number per unit volume using hemocytometer.^[3] The rate of erythrocyte sedimentation was found out by Wintrobe method and expressed in mm/hour. The number of neutrophils, lymphocytes, eosinophils and monocytes were recorded and the proportion of each was calculated and reported in number per litre.^[4] Immunoglobulins IgA, IgM and IgG levels were estimated by radio immuno diffusion (RID) method. The kits were purchased from "The Binding Site Limited" Birmingham, UK and the method was adopted as per the instruction given in the kit. Similarly IgE levels was estimated by enzyme linked immuno sorbent assay: (ELISA)-2 step sandwich assay. The serum protein content was also analyzed by biuret method.^[5] The total LDH level was estimated according to the method given by Bergmeyer and Bernts^[6] and LDH isozymic distribution in serum was also viewed by electrophoresis. For analyzing the blood histamine levels, blood was collected three hours after commencement of shift in a day followed by weekend holiday, from antecubital vein and transferred to heparinized tubes. Processing and estimation of histamine levels in blood was done as per the method prescribed by Parikh et al.^[7]

Statistical analysis
Student′s ′t′ test was carried out to compare the above biochemical parameters between the ginning factory women laborers and the control women. Correlation analysis was done between/within the biochemical parameters and also between the pulmonary function parameters results reported earlier by Jannet and Jeyanthi.^[1]

Results

Biochemical parameters
Hemogloblin and ESR
The mean levels of hemoglobin and ESR of ginning factory women laborers is illustrated in [Table - 1].

The mean levels of hemoglobin in ginning factory women laborers (10.5 ±1.892 g/dl) was significantly lower than control women at 1% level. Normal values of hemoglobin in women range from 12-16 g/dl. Seventy seven women laborers were found to have hemoglobin levels below 9.0 g/dl. Among them two were severely anemic (5.6 g/dl and 7.7 g/dl). This might be due to their low dietary intake of protein and iron, menopausal state and the lowering of appetite due to the presence of mucus that would have secreted by the stimulatory effect of inhaled cotton dust.

The experimental group women recorded significant increase (P< 0.1) in ESR (23.99 + 4.580 mm/hour) compared to control group. The normal limits of ESR is 0-20 mm/hour. ESR is also increased in chronic infectious diseases like asthma and in anemia, which favour the rouleax formation of erythrocytes.^[8] Forty three woman who had decreased levels of hemoglobin also have shown high ESR. Contaminated cotton dust might be one of the reasons for the development of infections. Out of 104 women labourers 93 had ESR values higher than the normal limits. Among them five had ESR values above 30 mm/hour. The high ESR values were more prevalent among chronic bronchitis and asthmatic workers compared to byssinotics and other workers in this study.

Total and differential count of leucocytes
[Table - 2] shows the mean levels of total and differential count of leucocytes in ginning factory women laborers.

Normally the values of total count range from 4000-10,000 x 10⁶ /L. The normal distribution of the different types of leucocytes are Neutrophils - 62.0%, Lymphocytes 30%, Eosinophils - 2.3% and Monocytes - 5.3%.^[9] Although the total count and differential count of leucocytes were within the normal limits, the mean levels of total count (9692.98 ± 1840.905), percentage of Neutrophil, (62.55 ± 7.034%) and Eosinophil (5.13 ± 2.081%) were significantly greater in the ginning factory women laborers at 1% level and the percentage of lymphocytes (32.15 ± 7.842%) was significantly decreased in the ginning factory women laborers at 1% level compared to the control group. A non-significant increase in total count was also observed by Cooper et al.,^[10] when aqueous extract of cotton bracts were administered to normal volunteers. The mean percentage of neutrophil (62.50 ± 7.034%) in ginning factory women laborers was significantly greater at 1% level than the control women. This is in agreement with the findings of Rylander and Haglind,^[11] who reported an increased neutrophil content in cotton dust exposed workers. According to Rastogi and Husain,^[12] this infux represents an increase of the body′s defenses toward inhaled agents. The mean eosinophil percentage of ginning factory women laborers (5.13 ± 2.081) was also found to be significantly increased at 1% level compared to the control group. This increase in eosinophils compared to controls suggested an allergic process commonly found in asthma and pulmonary eosinophilia.^[13] The cotton dust inhaled by these women would have induced the allergic response in them. Increased eosinophil content (above 7%) was observed in all the four asthmatic cases compared to the rest of the clinical symptoms.

Immunoglobulins
The mean immunoglobulin levels (Immunoglobuin A, M, G and E in ginning factory women laborers is illustrated in [Table - 3].

Normal values of Ig A is 71 to 360 mg/dl, Ig M - 40 to 260 mg/dl, Ig G - 620-1840 mg/dl and Ig E- upto 200 IU/ml. The levels of different immunoglobulin reported in ginning factory women laborers were within the normal limits. But a significant increase in Ig A (217.13 ± 90.937 mg/dl) at 1% level, Ig M (141.9 ± 56.616) mg/dl at 5% level and Ig G (1626.6 ± 582.0 mg/dl) at 1% level were seen in the ginning factory women laborers when compared to the control women. No significant change was noticed in Ig E levels although the value was higher.

When comparing the immunoglobulin levels among ginning factory women laborers exhibiting different clinical symptoms, the levels of Ig A was high in grade 2 byssinotics compared to other grades of byssinotics, chronic bronchitis, asthma and other. The levels of Ig M were high in Grade 2 byssinotics and chronic bronchitis cases. Ig G levels were increased only in all grades of byssinosis especially Grade 2 byssinotics. Ig E was seen increased only in all the asthmatic cases four cases and in one chronic bronchitis worker. One asthmatic worker showed very high Ig E levels of 2185 IU/ml. Changes in serum immunoglobulins in workers exposed to cotton dust have been suggested to precede or accompany the development of byssinosis - a cotton dust related disease.^[14] Karnik et al.,^[14] have observed a significant increase in Ig G level in byssinotics (1720.6 ± 450.6 mg/dl) and non byssinotics (1610.5 ± 288.7 mg/dl) a non significant rise in Ig A levels in byssinotics and nonbyssinotics (294.3 ± 132.7 mg/dl) and (213.1 ± 75.5 mg/dl) and Ig M in byssinotics and non byssinotics (161.7 ± 73.3 mg/dl and 148.1 ± 45.6 mg/dl). Taylor et al.,^[15] suggested an interaction between cotton dust antigen and serum antibody complex. The antigen reacted with Ig G by precipitation and passive agglutinations. Kamat et al.,^[16] have previously reported a significant rise in Ig G in byssinotics. According to Parkes^[17] precipitating Ig G antibody against an antigen in cotton is present in cotton workers. Our findings agreed with this fact that the antibody titre is highest in workers with byssinosis, lower in those without byssinosis and lowest in the unexposed subjects. The fact that symptoms of grade 2 and grade 3 byssinosis disappeared while the workers were still exposed to the dust could be explained on the grounds that, as long as exposure continues, antibody is progressively removed from the circulation leaving insufficient to produce a reaction; whereas after a period away from the dust, during which antibody is not removed, its titre has increased by the time the worker is re-exposed as suggested by Massoud and Taylor.^[18] The elevated Ig G antibody titres are probably markers of exposure to cotton dust rather than indicators.^[19] A non-significant increase in Ig E levels of textile workers was also reported by Zuskin et al.^[20]

Serum proteins
Our study reported no significant change in the levels of total proteins, albumin globulin ratio, percentage of albumin and globulin levels in the serum of ginning factory women laborers [Table - 4].
But the levels of total proteins in all grades of byssinotics were found to be decreased. Similarly non-significant decrease in albumin globulin ratio, increase in β and γ globulins was also observed in byssinotics by Karnik et al.^[14]

LDH
The normal range of LDH in serum is 230-460 IU/L.^[21] Normal serum is richest in LDH1 and LDH2 with less of LDH3 and least of LDH4 and LDH5 which sometimes may even not be detected. Changes in isozymes may be seen even when total LDH activity is still within normal limits.^[21] The present study aimed to estimate the total LDH level in serum and to assess LDH isozyme patterns particularly LDH3 levels which is the primary LDH isozyme of the lungs.

The serum LDH levels and its isozymes distribution are portrayed in [Table - 5].

There was no significant change in total LDH level and in LDH1, LDH2, LDH3 levels in serum among the ginning factory women laborers compared to control women. But a non-significant increase in LDH1 and non-significant decrease in LDH3 was observed in the ginning factory women laborers. The increase in LDH1 and decrease in LDH3 was seen more in the case of byssinotics compared to other group. A significant alteration in LDH1 and LDH3 isozymes in byssinotics was also observed by Karnik et al.^[14]

Histamine
Cotton dust extract induces the release of histamine from samples of human lung tissue in vitro. Therefore it is believed that histamine release is responsible for the major symptoms of byssinosis, viz, "chest tightness".^[7]

The mean blood histamine in ginning factory women laborers (9.4223 ± 5.844 µg/ml) significantly increased at 1% level compared to the control women. Bhatt et al.,^[22] have also reported significantly high histamine levels (6.02 ± 4.79 µg/ml) in cotton dust exposed textile workers at Ahmedabad. Likewise Patel et al.,^[23] have also observed significantly increased histamine levels in cotton mill workers (Byssinotics 10.24 ± 2.15 µg/ml). Similar results were also observed in the present study where byssinotics showed increased histamine levels compared to other clinical symptoms. Increased histamine level on the first working day is in agreement with monday morning syndrome. One grade 1 byssinotic worker showed highest blood histamine level (23.0 µg/ml).

Nowier et al.,^[24] have also reported higher blood histamine levels in cotton dust exposed workers. This increased level of blood histamine in ginning factory women laborers might be due to the histamine liberating factor of cotton extracts namely endotoxins of gram negative bacteria.^[25] It may also be due to the release of leucocytes mainly basophils contain histamine granules and respond to agents that cause release of histamine.^[25] This was also supported by the work of Ellisade et al.,^[26] and Panchal et al.,^[27] who suggested that mast cell degranulation with its release of histamine had been strongly implicated in the acute symptoms in cotton textile workers.

Correlation studies
Correlation studies between the pulmonary function parameters^[1] and biochemical parameters revealed significant negative correlation of FVC, FEV₁ and PEF with ESR (P< 0.05). PEF was significantly negatively correlated with total protein and total count of leucocytes at 5% level. Correlation within the biochemical parameters is shown in [Table - 6].

The existence of high correlation of IgG with histamine was also reported by Kamat et al.,^[16] in byssinotic cotton textile workers. The significant increase in LDH1 associated with decrease in LDH3 (negative correlation), negative correlation of albumin with b and g globulin was also in concordance to the results reported by Karnik et al.,^[14] in cotton textile workers.

Discussion

The present study suggested that the ginning factory women laborers exhibited significant changes in the levels of certain biochemical parameters apart from the pulmonary functional changes, which was reported in earlier studies. Routine analysis of pulmonary function parameters in these women supported with biochemical analysis will help to frame the medical treatment for the affected women. Change in the levels of ESR, LDH3 and Histamine may be used as indicators to assess pulmonary dysfunction in the workers those are exposed to cotton dust. The elevated Ig G antibody titres can be propabably used as markers of exposure to cotton dust. It was suggested that the low hemoglobin and poor immunity against diseases may also predispose the out come pulmonary dysfunction at an earlier stage.

The following recommendations were suggested for controlling the occupational lung diseases and the associated biochemical changes caused by cotton dust in the ginning factory women laborers:

Periodic health surveillance to be made essential to control both pulmonary abnormalities and biochemical changes.
Proper treatment to be given to the affected women.
Awareness to be created among the proprietors and the workers.
Some low cost iron rich foods like greens, drumstick leaves and jaggeries were recommended to be added in their diet.

Acknowledgement

We deeply acknowledge the Management of Karunya University, Coimbatore, Department of biochemistry, Avinashilingam University, Coimbatore and Dr. Mahadevan, Pulmonologist, KG Hospitals, Coimbatore, for their encouragement and support in this study.

References

1.	Jannet JV, Jeyanthi GP. Pulmonary health status of ginning factory women laborers in Tirupur, India. Indian J Occup Environ Med 2006;10:116-20. Back to cited text no. 1
2.	Connellan SJ. In: Cash Text book of Chest, Heart and Vascular disorders for physiotherapists, 4^th ed. Jaypee Brothers Medical Publishers: New Delhi; 1993. p. 83-9. Back to cited text no. 2
3.	Wintrobe MM, Miller WC, Smith FK. Clinical haemotology. 7^th ed. Lea and Febiger Publications: Philadelphia; 1965. p. 118, 127, 245. Back to cited text no. 3
4.	Linne JJ, Ringsrud KM. Basic techniques in clinical laboratory science, 3^rd ed. Mosby Year Books: 1992. p. 202-93. Back to cited text no. 4
5.	Samuel, KM. Notes on Clinical Lab techniques. MKG. Iyya and Sons Publishers; Chennai; 1992. p. 255-8. Back to cited text no. 5
6.	Bergmeyer HU, Bernt E. Lactate dehydrogenase - UV assay with pyruvate and NADH. In: Methods in enzymatic analysis, Volume II. Academic Press: NewYork; 1974. p. 574. Back to cited text no. 6
7.	Parikh JR, Venkatakrishna-Bhatt H, Panchal GM. Blood Histamine levels in cotton dust exposed workers in a textile mill of Ahmedabad. Am J Ind Med 1987;12:439-43. Back to cited text no. 7
8.	Treseler KM. Clinical Laboratory and Diagnostic tests, 2^nd ed. Appleton and Lange: California; 1988. p. 128, 133. Back to cited text no. 8
9.	Guyton A, Hall JE. Resistance of the body to infection. In: Text book of Medical Physiology. WB Saunders Company: Philadelphia; 1998. p. 435. Back to cited text no. 9
10.	Cooper JA, Merril WW, Buck MG, Schacter EN. The relationship between Broncho-alveolar Neutrophil Recruitment and Bronchoconstriction induced by a soluble extracts of cotton Bracts. Am Rev Respir Dis 1986;134:975-82. Back to cited text no. 10
11.	Rylander R, Haglind P. Blood neutrophil and platelet changes after exposure to cotton dust. Am Rev Respir Dis 1985;131:A209. Back to cited text no. 11
12.	Rastogi SK, Husain T. Role of histamine release in Byssinosis: An overview. Indian J Occup Health 1992;35:30-4. Back to cited text no. 12
13.	Golwalla AF, Golwalla SA. Medicine for students, Empress Courts, Mumbai; 1985. p. 251-5. Back to cited text no. 13
14.	Karnik AB, Parikh JR, Suthar AM, Patel MM, Thakore KN, Patel HH, et al. Immunoglobulins, Serum proteins and Lactate Dehydrogenase levels in workers exposed to cotton dust. Indian J Med Res 1987;85:222-6. Back to cited text no. 14
15.	Taylor G, Massoud A, Lucas E. Study on aetiology of byssinosis. Br J Ind Med 1971;23:143. Back to cited text no. 15
16.	Kamat SR, Kamat GR, Salpekar VY, Lobo E. Distinguishing byssinosis from chronic obstructive pulmonary disease. Results of a prospective five-year study of cotton mill workers in India. Am Rev Respir Dis 1981;124:31-40. Back to cited text no. 16
17.	Parkes WR. Byssinosis. In: Occupation lung disorders, 2^nd ed. Butterworths: London; 1982. p. 435-46. Back to cited text no. 17
18.	Massoud A, Taylor G. Byssinosis: Antibody to cotton antigens in normal subjects and in cotton card room workers. Lancet 1964;2:607-10. Back to cited text no. 18
19.	Pickering C. Byssinosis and other cotton related diseases, In: Hunter's Diseases of Occupation. 9^th ed. Oxford University Press: London; 2000. p. 621-31. Back to cited text no. 19
20.	Zuskin E, Kancelijak B, Schachter EN, Witek TJ, Mustajbegovic J, Maayani S, et al. Immunological findings and respiratory function in cotton textile workers. Int Arch Occup Environ Health 1992;64:31-7. Back to cited text no. 20
21.	Varley H. Practical clinical biochemistry, 6^th ed. CBS publishers and Distributors: New Delhi; 1996. p. 230-309. Back to cited text no. 21
22.	Bhatt HV, Mohanrao N, Panchal GM. Additive effect of smoking on blood histamine level induced action in respect of pulmonary function tests in cotton dust exposed workers. In: Proceedings of the symposium on harmful effects of common environment toxicants: Allahabad; 1989. p. 43-50. Back to cited text no. 22
23.	Patel BD, Panchal H, Bhatt HV, Mohanrao N, Kulkarni PK. Circulating Histamine among cotton dust exposed workers and its relation with lung function. In: Proceedings of the International Seminar on Clinical Pharmacology in developing countries: Lucknow; 1986. Vol 2. p. 148-53. Back to cited text no. 23
24.	Nowier MH, Abdulkader AM, Omran F. Blood histamine concentrations in workers exposed to cotton and flax dust. Br J Ind Med 1984;41:203-8. Back to cited text no. 24
25.	Ainsworth SK, Neumen RE, Harley RA. Histamine release from platelets for assay of byssinogenic substances in cotton mill dust and related materials. Br J Ind Med 1979;36:35-42. Back to cited text no. 25
26.	Ellisade MN, Greenblatt GA, Ziprin RL. The role of prostaglandin E in byssinosis. Am Ind Hyg Assoc J 1980;41:382-4. Back to cited text no. 26
27.	Panchal GM, Bhatt HV, Mohanrao N, Kulkarni PK. Circulating Histamine levels in relation to lung function test of cotton mill workers. Arch Hyg Rad Taksikol 1988;39:371-9. Back to cited text no. 27

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