Volume 8, number 2
 Views: (Visited 93 times, 1 visits today)    PDF Downloads: 1021

Julius A, Jayesh S. R. Biochemical Changes Due to Insecticide Exposure. Biosci Biotech Res Asia 2011;8(2)
Manuscript received on : 18 October 2011
Manuscript accepted on : 25 November 2011
Published online on:  --
How to Cite    |   Publication History    |   PlumX Article Matrix

Biochemical Changes Due to Insecticide Exposure

A. Julius and S. Raghavendra Jayesh

Department of Biochemistry, Sree Balaji Dental College and Hospital, Bharath University of Higher Education and Research, Narayanapuram, Pallikaranai, Chennai – 600 100 India.

ABSTRACT: This study indicates that there is decrease in the levels of Protein and related parameters like Albumin, Globulin and A/G ratio to the people who exposed to insecticides and pesticides spray for longer duration.

KEYWORDS: A/G ratio (Albumin Globulin ratio); Organophosphorous compounds; Organochlorine compounds

Download this article as: 
Copy the following to cite this article:

Julius A, Jayesh S. R. Biochemical Changes Due to Insecticide Exposure. Biosci Biotech Res Asia 2011;8(2)

Copy the following to cite this URL:

Julius A, Jayesh S. R. Biochemical Changes Due to Insecticide Exposure. Biosci Biotech Res Asia 2011;8(2). Available from: https://www.biotech-asia.org/?p=9848

Introduction

India is endemic to vector-borne diseases requiring spraying insecticides (Sharma, 1985).  In terms of acute toxicity, the more recently introduced insecticides are certainly less toxic  and persistant than the older organochlorine, organophosphorous and carbamate insecticides. Neverthless, there are still incidents of acute poisoning from a wide range of skin contamination following careless handling of pesticide concentrates. However a few people may suffer permanent damage of some kind (Proudfoot, 1988).

Chronic toxicity is present, where the effects are produced by long term intake of lower or intermittent doses (Sharp, 1986).  The distribution of malathion is significant in lungs, liver, kidneys, spleen, brain, heart, blood, muscles, urine and gastric contents, (Jadhav et al, 1992).

The spraymen were not aware of the potential hazards of pesticides and did not try their best to personal hygiene (Parron et al., 1996).  The incidence of skin damage, nose bleeds and nail damage in the paraquot spraymen in Sri Lanka is reported higher than in the control group (Senanyake et al., 1993).  Exposure to organochlorine increases the risk of developing breast cancer (Hoffman, 1996).  Organochlorine predominantly accumulates in the lipid fractions of the human food chain, by which animal fatty foods have become a major route of exposure for humans.

The most important aspect of pesticides is how they affect humans. There is increasing anxiety about the importance of small residues of pesticides, often suspected of being carcinogens or disrupting endocrine activities, in drinking water and food. In spite of stringent regulations by international and national regulatory agencies, reports of pesticide residues in human foods, both imported and home-produced, are numerous.

Over the last fifty years many human illnesses and deaths have occurred as a result of exposure to pesticides, with up to 20,000 deaths reported annually. Some of these are suicides, but most involve some form of accidental exposure to pesticides, particularly among farmers and spray operators in developing countries, who are careless in handling pesticides or wear insufficient protective clothing and equipment. Moreover, there have been major accidents involving pesticides that have led to the death or illness of many thousands. One instance occurred in Bhopal, India, where more than 5,000 deaths resulted from exposure to accidental emissions of methyl isocyanate from a pesticide factory. Hundreds of patients with chronic illness from chemical overexposure were found to  have toxic encephalopathy, reactive airway disease, and other chemically induced organ system damage when the patients become ill from pesticide spraying, they usually do not head for an emergency room, where they typically experience long waits in an environment containing germicidal residue, scented products, carbonless copy paper, hospital linens with heavy fabric softener, and other exposures. The patients have experienced severe neurologic and respiratory exacerbations as well as other organ system damage, such as significant increase in liver enzymes, Persons who are at increased risk for symptom from pesticide spraying individuals with migraines, chronic sinus problems, asthma, reactive airway disease, autoimmune diseases (many of which are exacerbated by pesticide exposure), and conventional allergies (Kipen et al. 1994). There is increased respiratory inflammation with conventional allergies, and pesticides more readily enter the body because the barrier function of the respiratory tract is further compromised. In addition, Karpati et al. (2004) failed to take note of the U.S. Environmental Protection Agency (EPA) final report “Principles of Neurotoxicity Risk Assessment (U.S. EPA 1994). This document confirmed the lack of a blood–brain barrier between the nose and the brain, so that pesticides readily enter the body through the nose and pass directly to the brain. This report further confirmed the unusual vulnerability of the brain to neurotoxicants: pesticides are lipophilic and therefore seek out lipid tissue such as the brain, and because the brain has unusually long neurons, repair of damage in the neurons occurs much less readily than in other body cells.Other groups at increased risk of pesticides are those with chronic obstructive lung disease, toxic encephalopathy, and neural degenerative diseases. Pyrethroid pesticides are significant neurotoxins (Eells et al. 1992McDaniel and Moser 1993; Tippe 1993; Vijverberg and van den Bercken 1990), and because they are increasingly replacing organophosphates, they now account for a large proportion of the pesticide-induced chronic illness among my patients. In my experience, the use of nebulized glutathione, the major antioxidant and major detoxifying agent of the body (Klaassen et al. 1986), when combined with lipoic acid, helps to improve an individual’s ability to detoxify (Packer et al. 1995); lipoic acid reactivates glutathione in lipid-and water-based tissues. Also, nebulized glutathione combined with adequate buffered vitamin C reactivates glutathione in water-based tissues.

Materials and Methods

The study was carried out on the Spraymen engaged in spraying in the highly endemic areas with high density of vectors causing malaria, filaria and brain fever. Seasonable epidemics were a regular feature in these areas.

A total of 193 spraymen with an age ranging from 24-55years were included in this study.

Age and sex matched healthy subjects with similar socio-economic status and who were not involved in spraying operation in anytime formed the control group (n=120)

Total Protein and albumin in plasma were estimated by the method of Reinhold (1953)

Results and Discussion

Plasma proteins and their distribution

Particulars Controls Spraymen
Proteins

(g/dl)

7.27±1.21

(120)

6.42±0.89***

(193)

Albumin

(g/dl)

3.96

(120)

3.12±0.86***

(193)

Globulin

(g/dl)

3.31±0.77

(120)

3.29±0.45

(193)

Albumin/Globulin

Ratio

(g/dl)

1.27±0.38

(120)

0.97±0.33***

(193)

Bilirubin Conjugated

(mg/dl)

0.28±0.11

(120)

0.25±0.14

(193)

Bilirubin Total

(mg/dl)

1.02±0.88

(120)

0.99±0.69

(193)

 Values  are expressed as mean ± S.D.  Figures in parentheses indicate number of samples.

***  – Statistical significance is shown at the level of  P <  0.001.

The levels of proteins, Albumin, Globulin and AG ratio are  shown above.  Total proteins and Albumin showed a significant  decrease in the spraymen (P<.001)  when compared with the controls.  Globulin showed no alteration and  A/G ratio decreased significantly (P<0.001).

Conjugated bilirubin and total bilirubin showed no significant variation suggesting no change in pigment metabolism.

A marked decrease in the levels of total proteins, albumin and A/G ratio is observed in the spraymen with the increase in the durations of exposure.  The lowest values are seen in the spraymen exposed for more than ten years . Altered A/G ratio has been observed in 58 % of spraymen engaged in Allahabad, India (Joshi et al., 1996).

The membranotoxic effect of Malathion , an insecticide is associated with changes in protein fractions of the CSF by a fall of globulins and a rise in albumins, thus attesting to the predominance of pathological processes in the brain, especially in the initial period of intoxication, and to the impairment of the blood-brain barrier.

Hypoalbuminia was observed with low total protein in the plasma of spraymen engaged for longer duration.  A/G ratio was also significantly reduced.

Figure 1 Figure 1

 

Click here to View figure

References

  1. Eells JT, Bandettini PA, Holman PA, Propp JM. (1992). Pyrethroid insecticide-induced alterations in mammalian synaptic membrane potential. J Pharmacol Exp Ther.;262:1173–1181.
  2. Karpati AM, Perrin MC, Matte T, Leighton J, Schwartz J, Barr RG. (2004) Pesticide spraying for West Nile virus control and emergency department asthma visits in New York City, 2000. Environ Health Perspect.;112:1183–1187.
  3. Kipen HM, Blume R, Hutt D. (1994) Asthma experience in an occupational medicine clinic. Low dose reactive airway dysfunction syndrome. J Occup Environ Med.;36:1133–1137.
  4. Klaassen CD. ed. (2001). Casarett and Doull’s Toxicology: The Basic Science of Poisons. 6th ed. New York:McGraw-Hill.
  5. W (1996) Organochlorine compounds: Risk of non Hodgkin’s lymphoma and breast cancer? Arch Environ Health. 51(3) :  189 – 192.
  6. Jadhav R K., Sharma  K.,   Rao G.J.,  Sarat A.K.,  Chandra  H, (1992) Distribution of malathion in body tissues and fluids. Forensic – Sci. Int.52(2), 223 – 229.
  7. Joshi P.L., Bhattacharya M., Yadava R.L., Chand B., Narasiman M.V.,  Nigam D.K., Jain C.K (1996)
  8. A community based study on the effect of hexachlorocyclohexane  (HCH)  in the spraymen and general population.Commun. Dis,: 28(3) :189 – 98.
  9. McDaniel KL, Moser VC. (1993). Utility of neurobehavioral screening battery for differentiating the effects of two pyrethroids, permethrin and cypermethrin. Neurotoxicol Teratol.;15(2):71–83.
  10. Packer L, Witt EH, Tritschler HJ. (1995). Alpha-lipoic acid as a biological  Free Rad Biol Med.;19:227–250.
  11. Parron T. Hernandoz Pla.  Villnueva  E.  (1996) Clinical and Biochemical changes in greenhouse sprayers chronically exposed to pesticides.  Human and Experimental  Toxicology 15(12) : 957 – 963.
  12. Proudfoot T. (1988) Poisoning treatment centre admissions following acute incidents   involving     pesticides Human Toxicology., 7 : 255 – 8.Reinhold, J.G, (1953)
  13. In : Standard methods in Clinical Chemistry. Reiner, M.(ed), Vol. I, Academic Press, New York, P.88.
  14. Senanyake N. Gurunathan G. Hart. T.B. Ameransinghe  Babapulle M. Ellapola S.B.  Udupihille  M.  Basanayake.  V  (1993)
  15. An epidemiological study of the health of srilankan tea plantation workers   association with   long term exposure to paraquat. British Journal of Industrial Medicines 50(3) : 257 – 263
  16. Sharma V.P. (1985) Malaria problems of pollution and prospects of integrated disease vector control    in India.  Regional meeting of the national MAS.  Committees of Central and South Asian Countries, New Delhi, India.
  17. Sharp D.S et al. (1986) Delayed health hazards of pesticide exposure. Annal review of public health 1986 : 7,441 – 471.
  18. Tippe A  (1993). Are pyrethroids harmless? Evaluation of experimental data. Zentralbl Hyg Umweltmed.;194:342–359.
  19. U.S. EPA (Environmental Protection Agency) (1994).Principles of neurotoxicity risk assessment.Fed Reg 42360–42404.
  20. Vijverberg HP, van den Bercken J. (1990). Neurotoxicological effects and the mode of action of pyrethroid pesticides. Crit Rev Toxicol.;21:105–126.
(Visited 93 times, 1 visits today)

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.