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Nitric Oxide Metabolites in Induced Sputum: A Noninvasive Marker of Airway Inflammation in Asthma
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     the Departments of Pediatrics and Experimental Medicine and Biotechnology, Postgraduate Institute of Medical Education & Research, Chandigarh160 012, India.

    Abstract

    Objective: This study was designed to examine for nitric oxide (NO) metabolites in induced sputum as a marker of airway inflammation in asthmatic children. Design. Prospective interventional Setting: Pediatric Allergy and Asthma Clinic of a tertiary care referral hospital in Northern India. Subjects: Twenty-one children with asthma who were not receiving corticosteroids for the preceding 3 months and 10 healthy controls were enrolled. Methods: Hypertonic saline-induced sputum was obtained at study entry in controls, and at study entry and after 6 weeks of inhaled corticostered (ICS) therapy in asthmatic children. Fresh expectorated sputum was treated with dithiothreitol and cytospinned for cell count. NO metabolites were measured in the supernatant by the modified Griess reaction. Results: Asthmatic children, compared with controls, had significantly higher concentration of NO metabolites (224.4 ± 209.69 vs. 39.2 ± 15.9 (moL/L, P <0.01) and a higher percentage of eosinophils (15.3 ± 12.0 vs. 0.8 ± 1.1%, P <0.01) in induced sputum. Both NO metabolites and eosinophil percentage declined following treatment with ICS for 6 weeks (P <0.01). Conclusion: The study confirms that the level of NO metabolites is increased in the tracheobronchial secretions of asthmatic children and decreases following ICS therapy. Measurement of NO metabolites in induced sputum may be useful for monitoring airway inflammation in children with asthma.

    Keywords: Allergic inflammation, Eosinophils.

    Nitric oxide (NO) plays an important role as a vasodilator, neurotransmitter and inflammatory mediator in the airways(1). NO is synthesized from L-arginine by three isoforms of the enzyme, NO synthase: two constitutive NO synthases (cNOS) are involved in the physiological regulation of airways and an inducible form (iNOS) is involved in inflammatory disease of the airways, and in the host defense against infection. All isoforms of NO synthases-endo-thelial NOS neuronal NOS, and inducible NOS have been demonstrated in human airways by immunohistological studies(2,3).

    NO and its free-radicle products are important mediators of airway inflammation in asthma(4-14). Recent studies have shown increased NO levels in exhaled air in adults and children with asthma using chemiluminiscence analyzers(15-23). High exhaled NO levels in asthmatic patients may reflect induction of iNOS, which is known to be inhibited by corticosteroids. Similarly, a decline in exhaled nitric oxide levels has been demonstrated with oral(15,19,22), inhaled(17,18,20,22,23) and intravenous(21) corticosteroid therapy.

    Although, measurement of level of NO in exhaled air is simpler and quicker than measurement in induced sputum, it is much more expensive and requires elaborate equipment(4,24). In future, the products of the L-arginine-NO pathway, such as nitrite (NO2-), nitrate (NO3-), peroxynitrite (ONOO-), nitrosothiols and L-citrulline, in biological fluids may become clinical markers for monitoring of certain pathological conditions and the progress of their treatment(10).

    Previous studies have demonstrated a higher concentration of NO metabolites in induced sputum of adult asthmatics as compared to normal subjects(25,26). In one of these studies, NO metabolite levels showed an insignificant decline following 2 weeks of anti-asthma treatment(25). To the best of our knowledge, there have been no published data demonstrating NO metabolites in induced sputum in children with asthma.

    The aim of this study was to compare NO metabolites between asthmatic and control children and to evaluate the safety of sputum induction using nebulized hypertonic saline in young children. At the same time we looked into the cytological profile of the induced sputum in control and asthmatic children.

    Subjects and Methods

    Twenty-one patients with asthma and 10 control children in the age-group 6-16 years (Table I) participated in this study after informed consent from the parent/guardian. Control children, who volunteered for this study, had no current or past history of asthma or any other respiratory symptoms. They had forced expiratory volume in one second (FEV1) > 75%, and a ratio of FEV1 to forced vital capacity >75%. The patients were selected from the Pediatric Allergy and Asthma Clinic of the Postgraduate Institute of Medical Education and Research, Chandigarh (India) and the physician diagnoses of asthma were based upon their symptoms of recurrent episodic wheezing, cough, and/or dyspnea. No subject had any respiratory infection for 4 weeks prior to the study and none of them had received any form of corticosteroid therapy for the past 3 months. All the subjects had an FEV1 >60%. The study was approved by the Ethics Committee of our Institute.

    Study methodology

    At the first visit, a questionnaire for symptoms and medications was answered by the child and his/her parents and physical examination and spirometry using the Vitalo-graph (Maids Moreton House, Buckingham, UK) were performed. Clinical severity of asthma was classified according to the International Consensus Report(27). Induced sputum was then collected. The patients received regular inhaled corticosteroids (ICS) (budesonide or fluticasone propionate as per the choice of the treating physician) delivered by metered-dose inhalers along with a spacer device and inhaled salbutamol by metered-dose inhaler as needed. Dosage range used for budesonide was 50-200 μg BD and 25-125 μg BD for fluticasone propionate. The patients were followed after 6 weeks of ICS therapy and clinical assessment, spirometry and sputum induction repeated.

    The sputum induction and processing were performed according to the method previously described by Popov, et al. and Fahy, et al.(28,29). Briefly, PEFR was measured in all children using the mini-Wright peak flow meter. All children were pre-medicated with inhaled salbutamol two puffs (200 μg) using a spacer device. Children were asked to rinse the mouth, and blow the nose to minimize contamination with saliva and post-nasal drip prior to sputum induction. They were then asked to inhale nebulized sterile 3% saline solution for 30 minutes from an ultrasonic nebulizer (ITALIANA AS 1001, Microsonic, Italy) (oscillation frequency 2.35 MHz; mean aerodynamic diameter 0.5-5 μm) at the maximum output. The reservoir of the nebulizer was filled with 3% saline solution (Shree Krishna Keshav Laboratories, Ahmedabad, India). Ten minutes after the start of nebulization and every 5 minutes thereafter children were encouraged to cough sputum into a graduated container. The nebulization was stopped after 30 minutes or earlier if a sample of good quality was obtained. PEFR measurement was repeated after induction. If PEFR had fallen by > 20% the child was required to wait until it returned to the baseline value. An adequate sample was defined as a minimum of 1.5 ml of induced sputum. Previous studies have shown that inhaled hypertonic saline may cause bronchoconstriction(28). None of the children in the current study developed significant symptoms or fall in PEFR >20%.

    Sputum cytology

    Sputum was treated by adding equal volumes of 0.1% dithiothreitol followed by phosphate-buffered saline. The sample was then mixed gently and subsequently centrifuged at 400g for 10 minutes. The cytospinned specimens were stained with Leishmann and Hansel stains (Fig. 1) and differential cell counts of 400 non-squamous cells were then performed and expressed as a percentage of the total non-squamous cell count.

    Fig. 1. Induced sputum cytology showing prominent eosinophilia (1000 x).

    Nitrate and nitrite assay

    Nitric oxide metabolites (nitrate + nitrite) were assayed colorimetrically by the Greiss reaction as previously described(30). Two hundred μL of sputum sample or standard was deproteinated by adding 20 μL of NaOH and 30 μL of ZnSO4. Samples were mixed with 5 × 102 units of nitrate reductase, 20 μL of 0.2 mol/L N-trimethyl aminoethane sulfonic acid and 20 μL of 0.5 moL/L of sodium formate. Anerobic incubation was done at room temperature for 20 minutes. One mL of water was added to the samples and nitrite assayed in the supernatant obtained by centri-fugation (5 minutes, 260 g). Deproteinated samples were mixed with 20 μL of 1% sulfanilamide in 15% phosphoric acid. After 10 minutes, 20 μL of 0.1% N-(1-naphthyl) ethylenediamine was added and absorption at 540 nm was determined by colorimetric method. Results were expressed in μmol/L of induced sputum.

    Statistical analysis

    All data were analyzed using the SPSS version 7.5 for Windows (SPSS. Chicago, Ill, USA). Data are expressed as mean ± SD. Comparison of continuous variables was performed using Student’s t-test for variables with normal distribution and Mann-Whitney U-test for variables with non-normal distribution; P <0.05 was considered significant.

    Results

    Asthmatic children had significantly lower PEFR and FEV1 than control children (Table I). Among the 21 patients, 13 had mild persistent symptoms (mean age 9.1 ± 1.7 years; 10 males and 3 females) and 8 had moderate persistent asthma (mean age 8.4 ± 2.0; 6 males and 2 females). The clinical characteristics of patients with mild persistent and moderate persistent asthma are shown in Table II. The process of sputum induction was monitored by measuring pre-and post-induction PEFR. Post-induction PEFR was reduced only at initial induction in asthmatics and not in controls or 6 weeks post-treatment in asthmatics (Table III). None of the patients suffered any acute symptoms and all patients were able to go home within 30 minutes of sputum induction. Average volume of sputum obtained was 1.8 ± 0.5 mL.

    All values are expressed as mean ± SD.

    Sputum cytology

    There was no difference in squamous cell count of sputum between subjects and controls at baseline (26.0 ± 9.2 vs. 28.7 ± 6.5, P = 0.4) and it did not change with ICS therapy. Differential count was performed as a percentage of non-squamous cells and eosinophil count was noted to be significantly higher in asthmatic children than in control children (15.3 ± 12.0 vs. 0.8 ± 1.1%, P < 0.01), whereas the percentage of macrophages was significantly lower (59.9 ± 10.9 vs. 77.0 ± 3.8%, P <0.01) in asthmatic children. The percentage of sputum eosinophils was higher in patients with moderate persistent asthma (n = 8) as compared to those with mild persistent asthma (n = 13) (16.9 ± 14.4 vs. 14.4 ± 10.9%), although the difference was not statistically significant (P >0.1). No significant differences were noted between asthmatic and control children in the percentage of squamous cells, neutrophils and lymphocytes (Table IV).

    All values are mean (% of non-squamous cell count) ± SD.

    Parentheses indicate P value with controls (for baseline values) and with baseline (for 6 weeks follow up values).

    NO metabolites

    The level of NO metabolites in the sputum was significantly higher in asthmatic children with a mean value of 224.4 ± 209.6 (mol/L (range 50.9 - 742.6), compared with control children, with a mean level of 39.2 ± 15.9 (mol/L (range 19.3 - 66.1 (mol/L). Children with moderate persistent asthma (n = 8) tended to have significantly higher values of NO metabolites in their sputum in comparison with mild persistent asthmatic children (n = 13) (315.5 ± 238.8 vs. 68.3 ± 136.0 (mol/L, P < 0.05).

    Changes in NO metabolites, eosinophils following therapy

    On reviewing the patient records at the end of the study period, 12 were taking budesonide (Group B) and 9 fluticasone propionate (Group FP). Nine of the patients on budesonide were classified as mild persistent asthma while 4 patients in the fluticasone group had mild persistent symptoms. There was no statistical difference at study entry in the two treatment groups.

    Significant improvement in symptoms and lung function tests was seen following ICS therapy given for a period of 6 weeks. Peak expiratory flow rate was noted to increase from 68.7 ± 9.5 to 78.3 ± 7.1% at 6 weeks of therapy (P <0.01). This improvement was associated with a significant decline in sputum eosinophil counts (15.3 ± 12.0 to 2.2 ± 1.5% at 6 weeks, P <0.01). Mean reduction in eosinophil count was 85.6% at week 6 of therapy as compared to baseline.

    There was a significant decline in level of sputum NO metabolites following ICS therapy (224.4 ± 209.6 to 86.5 ± 53.4 (moL/L at 6 weeks, P <0.01) (Fig. 2). Mean reduction in NO metabolites was 61.5% at week 6 of treatment as compared to baseline. However, levels of both eosinophils and NO metabolites in sputum continued to be higher than controls even after 6 weeks of anti-inflammatory therapy (P <0.05 for both).

    Fig 2. Nitric Oxide metabolities at baseline and following inhaled corticosteroid therapy

    Discussion`

    The results of the study indicate that the level of NO metabolites was increased in the tracheobronchial secretion of asthmatic children and reflected the severity of asthma. Induced sputum NO metabolites may be useful in monitoring airway inflammation and anti-inflammatory therapy in bronchial asthma.

    Nitric oxide and its free-radicle products are important in the pathogenesis of airway inflammation in asthma(4-7,14,26). Cytokines produced in asthmatic inflammation cause an increased expression of iNOS in airway epithelial cells and an elevation of NO levels(4,6). "Hyper-nitrosopnea" refers to the presence in the lung of an abnormally high concentration of NO(7). This elevation in NO increases in response to allergen challenge and is suppressed after treatment with corticosteroids. Nitric oxide increases airway inflammation by causing airway edema, efflux of eosinophils from airway vessels and formation of reactive nitrogen species(8-10). Nitric oxide also exacerbates the airway inflammation by inducing shedding of epithelial cells and thereby triggering axon reflexes from underlying neurons(13,14). Nitric oxide may amplify allergic inflammation by selective inhibition of T lymphocytes that secrete IFN-g (TH1 cells), which suppress the proliferation of TH2 cells(6,31). Increased number of TH2 cells leads to an increase in several cytokines such as IL-10, IL-4 and IL-5 which further increase airway inflammation(6). Inhibitors of NO synthesis may be useful in asthma by decreasing airway inflammation(3,6).

    To the best of our knowledge, the present study is the first of its kind in children. Notably, sputum NO metabolites in children in this study were much lower than that reported in adults(25,26). The mean value of sputum NO metabolites in adult asthmatics was reported as 1086 ± 325 μmol/L by Kanazawa, et al. and 1252.5 ± 203.3 μmol/L by Jang, et al.(26) while we found it to be 224.4 ± 209.9 μmol/L in asthmatic children. The values in adult controls were similarly higher (577±115 μmol/L by Kanazawa, et al. and 557.2 ± 101.5 μmol/L by Jang, et al.) as compared to the controls in our study (39.2 ± 15.9 μmol/L). The reason for these differences are not entirely clear may be related in part to the lung-size or to environmental factors.

    Further, it was observed that an occasional asthmatic child showed very high or low sputum nitrate levels irrespective of the severity of asthma. This has also been noted in studies done on adults. In a previous study, asthmatic adults (n = 25) had values of sputum NO metabolites ranging from 149.4 to 2232.0 μmol/L(25). The variability was also seen in the control adults with a range from 65.1 to 1107.3 μmol/L. In the present study the range was 50.9 to 742.6 μmol/L for asthmatic children and 19.3 to 66.1 μmol/L for controls. Both these studies were done on a small number of patients. Larger studies are required to find normative data and make the test available for clinical use.

    Induced sputum cytology showed a significantly higher eosinophil count in asthmatics as compared to normal children, which reflects the eosinophilic airway inflammation. Sputum eosinophil count declined significantly after 6 weeks of anti-inflammatory therapy with inhaled cortico-steroids. Similar elevation in sputum eosinophil counts and decline following anti-inflammatory therapy has been reported previously by other workers(25,26,28,29). Eosinophils play a major role in the inflammation of asthma, primarily by secretary inflammatory mediator products, which cause damage to the airway epithelium(32-35). There was no significant difference in the differential counts of other cells in induced sputum between asthmatic and control children either at baseline or on follow-up. Patients with moderate persistent asthma tended to have higher sputum eosinophil counts (16.9 ± 14.4%) as compared to those with mild persistent asthma (14.4 ± 10.9%), although the difference was not statistically significant (P >0.5).

    Corticosteroids are the most effective asthma therapy that suppresses inflammation in asthmatic airways, and they inhibit almost every aspect of the inflammatory process(33). This anti-inflammatory effect is through increased transcription and expression of anti-inflammatory proteins, such as IL-1 receptor antagonist, IL-10, and neutral endopeptidase and through repression of several inflammatory genes(34). Corticosteroids inhibit the activation and recruitment of inflammatory cells, particularly eosinophils, T lymphocytes, macrophages, dendritic cells and mast cells at the airway surface. Corticosteroids also inhibit the release of inflammatory mediators from structural cells in the airways, such as epithelial, smooth muscle and endothelial cells and fibroblasts(33,35). Corticosteroids inhibit the induction of Ca2+-independent NOS without any effect on the activity of either the constitutive or inducible enzymes (35). This may form a major mechanism of action of inhaled corticosteroids in asthma.

    The modulation of NO release may lead to application of novel therapies in diseases such as asthma and other inflammatory lung diseases(33). Monitoring of NO levels may also be useful in monitoring compliance in non-responsive children. Previous studies have shown a decline in exhaled air(15,17-23) and induced sputum NO levels(26) following corticosteroid therapy. In the present study, NO metabolites in induced sputum were higher at baseline and declined significantly following anti-inflammatory therapy, although the levels were still higher as compared to controls. These findings may reflect persistence of low level airway inflammation despite control in symptoms with inhaled corticosteroids.

    Induced sputum analysis is a relatively inexpensive test with the only major investment being the ultrasonic nebulizer with a cost range of 10-30,000 INR. The processing cost of sputum was approximately INR 8 per sample. Most samples in this study were processed individually and therefore, the cost should reduce further if the samples are processed in batches. As a comparison, the analyzer for exhaled NO costs to the tune of 500,000 INR. A possible drawback of sputum induction is the requirement of a trained respiratory technician to be present through-out induction of sputum. However, it is a promising new way of monitoring airway inflammation in asthma and this alone should not deter its potential.

    Contributors: NR developed the study protocol, and was involved in patient screening, enrolment, outcome assessment, data analysis and writing the manuscript. LK conceptualized the study, participated in development of the protocol and contributed to writing the manuscript. SM was involved in the methodology of measurement of metabolites, contributed to the data analysis and writing of the manuscript.

    Funding: None.

    Key Messages

    Sputum induction can be safely and successfully performed even in young children and easily repeated on multiple occasions.

    Airway inflammation in bronchial asthma may be monitored by measuring nitric oxide (NO) derivatives in induced sputum.

    NO derivatives are important inflammatory markers in asthma and decline with anti-inflammatory therapy.

    References

    1. Barnes PJ. NO or no NO in asthma Thorax 1996; 51: 218-220.

    2. Moncada S, Palmer RMJ, Higgs EA. Biosynthesis of nitric oxide from L-arginine. A pathway for the regulation of cell function and communication. Biochem Pharmacol 1989; 11: 1709-1715.

    3. Monacada S, Palmer RMJ, Higgs EA. Nitric oxide: physiology, pathophysiology and Pharmacology. Pharmacol Rev 1991; 443: 109-142.

    4. Barnes PJ, Liew FY. Nitric oxide and asthmatic inflammation. Immunol Today 1995; 16: 128-130.

    5. Kharitonov S, Alving K, Barnes PJ. Exhaled and nasal nitric oxide measurements: recommendations- ERS task force report. Eur Respir J 1997; 10: 1683-1693.

    6. Al-Ali MK, Howarth PH. Nitric oxide and the respiratory system in health and disease. Resp Med 1998; 92: 701-715.

    7. Nelson BV, Seare S, Wood J, Ling CY, Hunt J, Clapper LM, et al. Expired nitric oxide as a marker for childhood asthma. J Pediatr 1997; 10: 423-427.

    8. Bernarregi M, Mitchell JA, Barnes PJ, Belvisi MG. Dual action of nitric oxide on airway plasma leakage. Am J Respir Crit Care Med. 1997; 155: 869-879.

    9. Feder LS, Stelts D, Chapman RW, Manfra D, Crawley Y, Jones H, et al. Role of nitric oxide on eosinophilic lung inflammationin allergic mice. Am J Respir Cell Mol Biol. 1997; 17: 436-442.

    10. Silkoff PE, Robbins RA, Gaston B, Lundberg JON, Townley RG. Endogenous nitric oxide in allergic airway disease. J Allergy Clin Immunol 2000; 105: 438-488.

    11. Nikamp FP, Folkerts G. Nitric oxide and bronchial reactivity. Clin Exp Allergy 1994; 24: 905-914.

    12. Crapo JD, Day BJ. Modulation of nitric oxide responses in asthma by extracellular anti-oxidants. J Allergy Clin Immunol 1999; 104: 743-746.

    13. Laitinen LA, Heino M, Laitinen A, Kara T, Haahatela T. Damage of the airway epithelium and bronchial reactivity in patients with asthma Am Rev Respir Dis 1985; 131: 599-606.

    14. Barnes PJ. Asthma as an axon reflex. Lancet 1986; 1: 242-245.

    15. Yates DH, Kharitonov SA, Robbins RA, Thomas PS, Barnes PJ. Effects of a NOS inhibitor and a glucocorticoid on exhaled NO. Am J Respir Crit Care Med. 1995; 152: 892-896.

    16. Dotsch J, Demirakca S, Terbrack HG, Huls G, Rascher WE, Kuhl PG. Airway nitric oxide in asthmatic children and patients with cystic fibrosis. Eur Respir J 1996; 9: 2537-2540.

    17. Kharitonov SA, Yates DH, Barnes PJ. Inhaled glucocorticoids decrease nitric oxide in exhaled air of asthmatic patients. Am J Respir Crit Care Med 1996; 153: 454-457.

    18. van Rensen ELJ, Straathof KCM, Veselic-Charvat MA, Zwinderman AH, Bel EH, Sterk PJ. Effect of inhaled steroids on airway hyperresponsiveness, sputum eosinophils, and exhaled nitric oxide levels in patients with asthma. Thorax 1999; 54: 403-408.

    19. Baraldi E, Azzolin NM, Zanconato S, Daroi C, Zacchello F. Corticosteroids decrease exhaled nitric oxide in children with acute asthma. J Pediatr 1997; 131: 381-385.

    20. Jatakanon A, Lim S, Chung KF, Barnes PJ. An inhaled steroid improves markers of airway inflammation in patients with mild asthma. Eur Respir J 1998; 12: 1084-1088.

    21. Massaro AF, Gaston B, Kita D, Fanta C, Stamler JS, Drazen JM. Expired nitric oxide levels during treatment of acute asthma. Am J Respir Crit Care Med. 1995; 152: 800-803.

    22. Stirling RC, Kharitonov SA, Campbell D, Robinson DS, Durham SR, Chung KF, et al. Increase in exhaled nitric oxide levels in patients with difficult asthma and correlation with symptoms and disease severity despite treatment with oral and inhaled corticosteroids. Thorax 1998; 53: 1030-1034.

    23. Colon-Semidey AJ, Marshik P HW. Correlation between reversibility of airway obstruction and exhaled nitric oxide levels in children with bronchial asthma. Pediatr Pulmonol 2000; 30: 385-392.

    24. Barnes PJ, Kharitonov SA. Exhaled nitric oxide: a new lung function test. Thorax 1996; 51: 233-237.

    25. Kanazawa H, Shoji S, Yamada M, Fuji T, Kawaguchi T, Kudoh S, et al. Increased levels of nitric oxide derivatives in induced sputum of patients with asthma. J Allergy Clin Immunol 1997; 99: 624-629.

    26. Jang AS, Choi IS, Lee S. Nitric oxide metabolites in induced sputum: a marker of airway inflammation in asthmatic subjects. Clin Exp Allergy 1999; 29: 1136-1142.

    27. National Heart, Lung and Blood Institute, National Institutes of Health. International consensus report on diagnosis and treatment of asthma. Eur Resp J 1992; 5: 601-641.

    28. Popov TA, Pizzichini MMM, Pizzichini E. Some technical factors influencing the induction of sputum for cell analysis. Eur Respir J 1995; 8: 559-565.

    29. Fahy JV, Liu J, Wong H, Boushey HA. Analysis of cellular and biochemical constituents in induced sputum after allergen challenge: a method for studying allergic airway inflammation. J Allergy Clin Immunol 1994; 93: 1031-1039.

    30. Phizackerley PJR, Al-Dabbagh SA. The estimation of nitrate and nitrite in saliva and urine. Anal Biochem 1983; 131: 242-245.

    31. Taylor-Robinson AW, Liew FY, Severin A. Regulation of the immune response by nitric oxide differentially produced by Th1 and Th2 cells. Eur J Immunol 1994; 24: 980-984.

    32. Chadevergne FM, Le Bourgeois M, de Blic J, Scheimann P. The role of inflammation in childhood asthma. Arch Dis Child 2000; 82 (suppl II): ii6-ii9.

    33. Barnes PJ. Efficacy of inhaled corticosteroids in asthma. J Allergy Clin Immunol 1998; 102: 531-538.

    34. Barnes PJ. Antiinflammatory actions of glucocorticoids: molecular mechanism. Clin Sci 1998; 94: 557-572.

    35. Schweibert LM, Stellato C, Schleimer RP. The epithelium as a target for glucocorticoid action in the treatment of asthma. Am J Respir Crit Care Med 1996; 154: 516-520.(Lata Kumar, Nitin Rajput )