Leprosy serology using PGL-I: a systematic review

Moura, Rodrigo Scaliante de; Calado, Karla Lucena; Oliveira, Maria Leide W.; Bührer-Sékula, Samira

doi:10.1590/S0037-86822008000700004

Abstracts

Serology using a species-specific antigen for Mycobacterium leprae, PGL-I, could be a marker for the bacterial load of patients with leprosy. Various studies have identified the potential use of serology in the classification of patients for treatment purposes, case monitoring, identification of the risk of relapse and selection of household contacts with a higher risk of contracting the disease. A systematic review of the literature was conducted and 26 articles were included in this comparative analysis. The results of the use of PGL-I serology in different situations, its limitations and possible applications were evaluated. Studies show the efficacy of PGL-I serology in the classification of patients, treatment monitoring and as a predictive test for leprosy reactions. To improve early diagnosis and follow-up of the population at greatest risk of developing leprosy, the methodologies used in the past have yet to show a favorable cost-benefit ratio, although studies indicate that the use of the test might positively influence leprosy control programs. With simple and robust techniques, the use of PGL-I serology is viable.

Serology; PGL-I; Leprosy; ELISA

A sorologia utilizando o antígeno espécie-específico do Mycobacterium leprae, PGL-I, pode ser um marcador de carga bacteriana em pacientes com hanseníase. Estudos identificaram potencial de uso da sorologia na classificação de pacientes para fins de tratamento, monitoramento de terapia, risco de recidiva e na seleção dos contatos com maior risco de adoecer. Foi realizada uma revisão sistemática e 26 artigos foram incluídos na análise comparativa. Avaliamos os resultados do uso da sorologia PGL-I em diferentes situações, suas limitações e possíveis aplicações. Estudos mostraram eficácia da sorologia PGL-I na classificação de pacientes, monitoramento da terapia, e nas reações hansênicas como teste preditivo. Para diagnóstico precoce e seguimento de população de alto risco, as metodologias utilizadas ainda não demonstraram custo-benefício favorável, porém estudos indicam que a utilização do teste poderá influenciar positivamente nos programas de controle da hanseníase. Com técnicas simples e robustas, o uso da sorologia PGL-I é viável.

Sorologia; PGL-I; Hanseníase; ELISA

ARTICLE

Leprosy serology using PGL-I: a systematic review

Rodrigo Scaliante de Moura^I; Karla Lucena Calado^II; Maria Leide W. Oliveira^II; Samira Bührer-Sékula^I

^ITropical Pathology and Public Health Institute, Federal University of Goiás, Goiânia, Goiás, Brazil

^IIDermatology Service, School of Medicine, Federal University of Rio de Janeiro, RJ, Brazil

Address to

ABSTRACT

Serology using a species-specific antigen for Mycobacterium leprae, PGL-I, could be a marker for the bacterial load of patients with leprosy. Various studies have identified the potential use of serology in the classification of patients for treatment purposes, case monitoring, identification of the risk of relapse and selection of household contacts with a higher risk of contracting the disease. A systematic review of the literature was conducted and 26 articles were included in this comparative analysis. The results of the use of PGL-I serology in different situations, its limitations and possible applications were evaluated. Studies show the efficacy of PGL-I serology in the classification of patients, treatment monitoring and as a predictive test for leprosy reactions. To improve early diagnosis and follow-up of the population at greatest risk of developing leprosy, the methodologies used in the past have yet to show a favorable cost-benefit ratio, although studies indicate that the use of the test might positively influence leprosy control programs. With simple and robust techniques, the use of PGL-I serology is viable.

Key-words: Serology. PGL-I. Leprosy. ELISA.

Since 1991, the World Health Organization (WHO) has sought to achieve the goal of the elimination of leprosy as a public health problem, defined as a prevalence rate of one leprosy case per 10,000 population. In 2007, the global prevalence of leprosy registered at the beginning of the year was 224,717 active cases, 13.2% lower than that registered in 2006⁸³. The significant decline in prevalence was largely due to the introduction of Multi-Drug Therapy (MDT) as the standard treatment and the marker for disease cure (release from treatment), in contrast with dapsone (DDS) treatment over the rest of the patient's lifetime, as was the case until 1982.

Leprosy is still one of the main causes of physical disability, which contributes to the continuation of stigma and social disadvantage for those who have the disease and their family members⁵⁵. The WHO estimates that 25% of patients have some degree of disability due to leprosy⁸¹, which denotes the existence of late diagnosis related to the operational problems of low coverage and case resolution within the health system, in addition to aspects inherent in the insidious evolution of the disease⁷⁹.

Little is known of the real distribution and transmission of leprosy infection and the factors that lead to the onset of disease, mostly due to the fact that it is impossible to cultivate Mycobacterium leprae in vitro. Infection with the bacilli is significantly more prevalent than cases of the disease itself. Therefore, further research is necessary, particularly concerning bacillary transmission, the role of subclinical infection, the progression of infection to disease and incidence tendencies⁷⁵. The generally accepted concept is that multibacillary (MB) patients are the principle source of infection. Therefore, a control strategy based on case diagnosis and treatment should reduce the transmission of the organism. Over time, the chain of transmission would be broken and leprosy would disappear naturally⁴⁵.

The discovery and elucidation of the chemical structure of the glycolipid specific to Mycobacterium leprae in 1981⁴³, and the discovery that it was antigenic in 1982⁵⁸, were great innovations in leprosy research. PGL-I has been used in several studies showing that leprosy patients at the lepromatous end of the spectrum form large quantities of immunoglobulin of the IgM type in response to this antigen (seropositivity of 80-100%), while patients at the tuberculoid end showed specific immunoglobulin at much lower levels (seropositivity of 30-60%)^{9 14 22 44 46 57 59}.

The type of leprosy and the level of proximity and relationship between the household contact and the index-case are other factors that weigh in disease risk evaluation. Patients often have no knowledge of any previous contact with the disease and the majority of incident cases do not report having been in contact with other patients³⁸. However, evidence exists that the fact that individuals live in the same household with leprosy patients does significantly raise the risk of developing the disease^{31 54 76 77}.

A study that monitored contacts over a period of 6 years showed that there is a 7.2-fold greater risk of developing leprosy (MB or PB) in seropositive contacts with antibodies to PGL-I when compared to seronegative contacts, increasing to 24-fold greater risk of developing MB leprosy³². The percentage of contacts that progress to disease among seropositive contacts suggests that serology with anti-PGL-I could be useful as a prognostic test¹⁸.

Although the detection of antibodies may indicate current or past infection of Mycobacterium leprae regardless of the presence of clinical signs^{19 35 46}, antibody titers appear to be more closely associated to the level of exposure to Mycobacterium leprae in the community at large. This is because the distribution of seropositivity in groups of household contacts or leprosy cases has not proved to be higher than non-contacts in highly endemic areas, but significant differences exist between contacts and non-contacts in areas of lower endemicity.

Seropositivity in a general population has a uniform distribution. This may mean that no difference exists between healthy individuals and leprosy cases to distinguish between subclinical infection and disease. In this case, serological tests based on the detection of IgM antibodies against PGL-I should not be used as a diagnostic tool for population screening to detect leprosy cases³⁷.

The diagnosis of leprosy is clinical and, as per WHO recommendations, operational classification is based on the number of skin lesions, where patients with up to 5 lesions are considered paucibacillary (PB) and those with 6 or more lesions are multibacillary (MB)⁵³. Approximately 70% of leprosy patients can be diagnosed via the presence of skin patches with reduced sensitivity. However, 30% of patients, including many MB cases, do not present this sign. Bacilloscopy is an important auxiliary examination, but it is not always available.

Episodes of leprosy reactions are the most significant disease complications and can occur during and/or after treatment, often leaving sequelae. Type I, or reversal reactions are episodes of acute inflammation of the skin and peripheral nerves that are the result of late hypersensitivity to bacilli antigens that occur in as many as 30% of patients⁶². Erythema Nodosum Leprosum, or type II reactions, can occur at the lepromatous end of the spectrum and often begin with the patient in a febrile, weakened state with papular cutaneous nodules accompanied by inflammation in the nerves, eyes and testicles⁸.

Research has sought to evaluate PGL-I serology as a tool in the monitoring of treatment efficacy based on the strong correlation between bacilloscopy and the levels of antibodies to PGL-I in clinical samples of patients.

The current study aimed to review serology for the detection of IgM antibodies against PGL-I, its application as an auxiliary test for diagnosis and the classification of HD patients for treatment purposes, case monitoring, relapse risk identification and the selection of household contacts with a greater risk of contracting the disease.

MATERIAL AND METHODS

Criteria for search and selection

A systematic bibliographic review was conducted using PGL-I serology to define the search parameters in bibliographic medical databases such as BIREME/PAHO/WHO, MEDLINE, Cochrane Library, Brazilian Society of Dermatology, reports from international committees, academic thesis and personal experiences from the authors published in indexed and non-indexed sources. The terms used in the search were PGL*', leprosy, Bacterial index and phenolic glycolipid combined with filters for diagnostic studies such as diagnosis, sensitivity, specificity and epidemio*.

Criteria for the selection of studies for review

The selected studies were included based on an objective evaluation of the methodology and quality of each work, with criteria adopted for inclusion that sought to group similar studies and exclude those without possibility for comparison (Table 1).

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Criteria for inclusion:

Studies that presented a methodology that could be replicated in other contexts;

Use of synthetic glycolipids (DBSA, ND-O-BSA, NT-P-BSA);

Samples of patients that had not yet been treated for leprosy (if the objective was to determine sensitivity);

Research on the presence of IgM antibodies.>

Criteria for exclusion:

Use of native PGL-I;

ELISA using a cut-off point below 0.150 or over 0.300;

Studies including patients only from a pool of PB or MB patients;

Lack of information on the criteria for inclusion/exclusion in the study;

Lack of information on the criteria used for patient classification.

Data extraction

From a total of 109 works, 57 articles were selected for inclusion, and of these, 26 were selected for comparative analysis (Figure 1).

Even among the studies selected, the characteristics of study design, criteria for definition of the groups selected, level of patient exposure to Mycobacterium leprae and immunological response of those infected (in endemic areas or not) differ. In the selection of patients, the gold standard used to define PB or MB varied among the studies and influenced the level of sensitivity observed. The studies that used enzyme-linked immunosorbent assay (ELISA) differed in technique in relation to the type and concentration of antigens, dilution of samples and definition of cut-off points for positivity. These differences interfered in the sensitivity and specificity of the tests.

Analysis

No significant differences occurred between the results using ELISA or faster methods of antibody detection^{41 52 64 74}. A close correlation was observed between studies using samples in filter paper (finger prick)^{25 42 67 69} and those collected by venopunction, despite the fact that the serological titers detected on samples that passed through filter paper were generally lower⁷⁴.

PGL-I in patient classification

Several studies observed a correlation between the levels of antibodies detected with ELISA and bacteriological indexes (BI)^{9 11 12 13 14 15 18 22 25 27 42 57 61 67 73}, justifying studies which use serology as an auxiliary tool in patient classification.

To facilitate the visualization and comparison of the results, the studies were grouped according to their study populations. Table 2 demonstrates the positivity in studies involving MB and PB patients using diverse techniques, including ELISA, dipstick, ML Flow and Passive Hemoagglutination (PHA).

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Average seropositivity among the studies for MB and PB patients was 78% and 23%, respectively, varying between 51.2% and 97.4% in the MB group and from 6.9% to 57.3% in PB. Variations in the classification criteria (PB and MB) used are not clear in many studies, given that the WHO criteria were changed in the middle of the period in question and were not always completely followed. For example, the classification of patients as MB or PB in the 1980s required a smear bacilloscopy. At the end of the 1990s, this classification was changed based on the number of skin lesions present without regard to the number of nerve trunks affected⁸². In general, seropositivity in PB cases presented lower percentages in the studies that used bacilloscopy as the gold standard. In contrast, studies that showed elevated seropositivity also used classification based on the number of lesions or combined this approach with bacilloscopy. This variation in seropositivity percentages is related to the differences in immunological response in different populations. For example, the implementation of research for ML Flow¹⁵ in Nepal showed almost half the seropositivity (31.9%; 340/1066) level of that observed in Brazil (50.8%; 544/1071) and Nigeria (62.9%; 117/186). The low bacterial production in Nepalese patients was confirmed by both bacilloscopy and ML Flow negative results for 38.3% and 15.6% of MB patients classified by the number of skin lesions in Nepal and Brazil, respectively.

Analysis of the results showed that the use of serology as a tool for patient classification would lead to a reduction in the number of patients treated as MB. This is because the counting of skin lesions is a functional operational tool, but has not been well-received by health professionals. When laboratory tests like bacilloscopy and histopathology are not available, there is a strong tendency to classify patients as MB, as seen in the Nigerian study, where a large proportion of patients received the MB treatment regimen unnecessarily¹⁵. Part of this fear may be explained by the fact that classification using the number of lesions ignores the size of the patches and health care workers observe the important relation between the size of lesions and clinical form of the disease. Recently, lesion size was identified as an important aspect in the treatment decision⁶⁷.

PGL-I in case holding

The serological methods based on PGL-I can be used in leprosy case holding. In the majority of patients, antibody levels drop once treatment is initiated, so they are obviously much higher at diagnosis²⁵ and fall 25 to 50% annually afterwards^{23 24 33 47 63}. This decline varies widely among patients, in that this decline can be linear and quickly become negative or take several years after the end of treatment to become so⁴⁰.

PGL-I as a predictor of reactions and relapse

Few studies assessed the utility of serology for diagnosis or to predict which patients may have reactions or relapses; however, they do tend to indicate the same risk factors for reactions and relapse after release from treatment.

As an auxiliary tool in the diagnosis of type I or II reactions during treatment, serological tests did not prove efficient, because similar levels were obtained in patients without reactions and even among the healthy population⁷¹. However, patients with high concentrations of anti-PGL-I IgM at the onset of treatment presented a higher risk of developing type 1 reactions, thus identifying patients for monitoring and early treatment may reduce nerve damage and disability⁶⁵. In posttreatment reactions, patients with a positive PGL-I serology when released from treatment showed a 10.4-fold greater chance of developing reactions compared to those with negative serology⁷.

Research using serology is necessary to identify the patients at higher risk of developing reactions in order to define the best approach to case holding and patient monitoring.

Seropositivity may be the first indicator of leprosy relapse^{50 84}; however, in immunosuppressed patients, seropositivity may not be present⁵⁰. In a clinical trial to reduce the treatment period for leprosy, seropositivity proved to be essential for predicting relapse and only one out of nine patients diagnosed as a relapse case showed negative serology at the onset of treatment and even the one exception was a drug-resistant case¹². A study conducted in Brazil observed a significant association between a higher risk of relapse in patients with a certain set of characteristics, such as being closer to the lepromatous end of the spectrum and being positive for BI and anti PGL-I⁵⁶. This shows that the bacilli can remain relatively protected from the immunological effects of treatment, subsequently proliferating under more propitious conditions.

Household contacts

The high prevalence of seropositives among household contacts of leprosy patients demonstrates that subclinical infection with Mycobacterium leprae is common^{30 52 66} and is related to the leprosy type of the patient under study^{20 30 70}.

Studies in contacts have shown seropositivity in as many as 18.4% (Table 3), with lower levels obtained in contacts of PB patients and higher levels in MB contacts. Monitoring of contacts provided evidence that those who tested seropositive had a higher risk of developing MB leprosy than those who were seronegative³². The BCG vaccine seems to have a protective effect, given that the majority of seropositive contacts that were vaccinated developed only the PB form of leprosy³⁶.

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Research in Rio de Janeiro verified the positive influence of decentralized healthcare in the increase of new case detection, leading to earlier diagnosis, thereby reducing the number of patients that developed disabilities²⁹. Therefore, the detection of antibodies against PGL-I can help to identify infected household contacts without clinical signs or symptoms and may be a useful tool in control programs.

Study population

Table 4 demonstrates that the seropositivity rate varies and appears to be dependent on the leprosy incidence rate in the community^{3 4 17 18 34 41 42 80}.

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While different rates of seropositivity in endemic areas, as opposed to non-endemic areas, may reflect subclinical infection⁴⁶, as yet, no evidence exists of a correlation between seroprevalence of PGL-I and the incidence of leprosy. Additionally, studies have not yet shown how to use serology in the evaluation of leprosy control activities.

In school children aged 10 to 12, different patterns of seropositivity distribution in endemic countries, such as Indonesia and Brazil, did not permit confirmation of PGL-I seropositivity as an indicator of the magnitude of the disease in a given area^{10 80}. In Indonesia, such a correlation was shown, but could not be confirmed in Brazil. Despite the fact that the two studies included similar populations, the methods differed; in Indonesia, children almost exclusively in that age group were included, while clusters of similar age were used in Brazil. The study of clusters may not be appropriate to represent the infection rate in the population, but the cost-benefit ratio of including all children in a particular age group would not justify the use of serology as a simple tool to evaluate leprosy endemicity in a determined region^{13 78}.

Conclusion

Serologic tests to detect IgM immunoglobulin to PGL-I are useful to assist in diagnosis when the results are considered together with clinical information^{2 6 11 67}. They may be used to classify patients as MB or PB and in the monitoring of treatment efficacy, which must be accompanied by reduced circulating antibody titers^{1 22 26 25 85}.

For leprosy reactions, PGL-I also proved to be useful as a predictive tool^{7 65}.

For early diagnosis and monitoring of those at higher risk, the methodologies used to date have still not shown a favorable cost-benefit ratio, although studies indicate that the use of this type of test could positively influence leprosy control programs.

Almost thirty years after the identification of PGL-I, we affirm that the evolution of related research has generated simple and robust methodologies that are useful for epidemiological studies and as auxiliary tools in the classification of and treatment definition for leprosy.

REFERENCES

1. Bach MA, Wallach D, Flageul B, Hoffenbach A, Cottenot F. Antibodies to phenolic glycolipid-1 and to whole Mycobacterium leprae in leprosy patients: evolution during therapy. International Journal of Leprosy and Other Mycrobacteriology Diseases 54: 256-267, 1986.
2. Bagshawe AF, Garsia RJ, Baumgart K., Astbury L. IgM serum antibodies to phenolic glycolipid-I and clinical leprosy: two years' observation in a community with hyperendemic leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 58: 25-30, 1990.
3. Bakker MI, Hatta M, Kwenang A, Faber WR, van Beers SM, Klatser PR, Oskam L. Population survey to determine risk factors for Mycobacterium leprae transmission and infection.International Journal of Epidemiology 33: 1329-1336, 2004.
4. Bakker MI, Hatta M, Kwenang A, Klatser PR, Oskam L. Epidemiology of leprosy on five isolated islands in the Flores Sea, Indonesia. Tropical Medicine and International Health 7: 780-787, 2002.
5. Brett SJ, Draper P, Payne SN, Rees RJ. Serological activity of a characteristic phenolic glycolipid from Mycobacterium leprae in sera from patients with leprosy and tuberculosis. Clinical and Experimental Immunology 52: 271-279, 1983.
6. Brett SJ, Payne SN, Gigg J, Burgess P, Gigg R. Use of synthetic glycoconjugates containing the Mycobacterium leprae specific and immunodominant epitope of phenolic glycolipid I in the serology of leprosy. Clinical and Experimental Immunology 64: 476-483, 1986.
7. Brito MFM. Ximenes RAA, Gallo ME. Associação entre reação hansênica após alta e a carga bacilar avaliada utilizando sorologia anti PGL-I e baciloscopia . Universidade Federal de Pernambuco (UFPE), 2008.
8. Britton WJ. Lockwood DN. Leprosy. Lancet 363: 1209-1219, 2004.
9. Buhrer SS, Smits HL, Gussenhoven GC, van Ingen CW, Klatser PR. A simple dipstick assay for the detection of antibodies to phenolic glycolipid-I of Mycobacterium leprae The American Society of Tropical Medicine and Hygiene58:133-136, 1998.
10. Bührer-Sékula S, van Beers S, Oskam L, Lecco R, Madeira ES, Dutra MAL, Luis MC, Faber W, and Klatser P. The relation between seroprevalence of antibodies to phenolic glycolipid-I among school children and leprosy endemicity in Brazil. Revista da Sociedade Brasileira de Medicina Tropical 41(supl 2) 81-88, 2008.
11. Buhrer-Sekula S, Cunha MG, Ferreira WA, Klatser PR. The use of whole blood in a dipstick assay for detection of antibodies to Mycobacterium leprae: a field evaluation. FEMS Immunology and Medical Microbiology 21: 197-201, 1998.
12. Buhrer-Sekula S, Cunha MG, Foss NT, Oskam L, Faber WR, Klatser PR. Dipstick assay to identify leprosy patients who have an increased risk of relapse. Tropical Medicine and International Health 6: 317-323, 2001.
13. Buhrer-Sekula S, Sarno EN, Oskam L, Koop S, Wichers I, Nery JA., Vieira LM, de Matos HJ, Faber WR, Klatser PR. Use of ML dipstick as a tool to classify leprosy patients. International Journal of Leprosy and Other Mycrobacteriology Diseases 68: 456-463, 2000.
14. Buhrer-Sekula S, Smits HL, Gussenhoven GC, van Leeuwen J, Amador S, Fujiwara T, Klatser PR, Oskam L. Simple and fast lateral flow test for classification of leprosy patients and identification of contacts with high risk of developing leprosy. Jornal of Clinical Microbiology 41: 1991-1995, 2003.
15. Buhrer-Sekula S, Visschedijk J, Grossi MA, Dhakal KP, Namadi AU, Klatser PR, Oskam L. The ML flow test as a point of care test for leprosy control programmes: potential effects on classification of leprosy patients. Leprosy Review 78: 70-79, 2007.
16. Cardona-Castro NM, Restrepo-Jaramillo S, Gil de la Ossa M, Brennan PJ. Infection by Mycobacterium leprae of household contacts of lepromatous leprosy patients from a post-elimination leprosy region of Colombia. Memórias do Instituto Oswaldo Cruz 100: 703-707, 2005.
17. Cartel JL, Chanteau S, Boutin JP, Plichart R, Richez P, Roux JF, Grosset JH. Assessment of anti-phenolic glycolipid-I IgM levels using an ELISA for detection of M. leprae infection in populations of the South Pacific Islands. International Journal of Leprosy and Other Mycrobacteriology Diseases 58: 512-517, 1990.
18. Cellona RV, Walsh GP, Fajardo T T Jr, Abalos RM, la Cruz EC, Guido-Villahermosa L, Felicio-Balagon MV, Steenbergen GJ, Douglas JT. Cross-sectional assessment of ELISA reactivity in leprosy patients, contacts, and normal population using the semisynthetic antigen natural disaccharide octyl bovine serum albumin (ND-O-BSA) in Cebu, The Philippines. International Journal of Leprosy and Other Mycrobacteriology Diseases 61: 192-198, 1993.
19. Chanteau S, Cartel JL, Guidi C, Plichart R, Bach MA. Seroepidemiological study on 724 household contacts of leprosy patients in French Polynesia using disaccharide-octyl-BSA as antigen. International Journal of Leprosy and Other Mycrobacteriology Diseases 55: 626-632, 1987.
20. Chanteau S, Cartel JL, Roux J. [Leprosy serology: current status and perspectives]. Acta Leprologica 8: 65-70, 1992.
21. Chanteau S, Cartel JL, Roux J, Plichart R, Bach MA. Comparison of synthetic antigens for detecting antibodies to phenolic glycolipid I in patients with leprosy and their household contacts. Journal of Infectious Diseases 157: 770-776, 1988.
22. Chanteau S, Plichart R, Boutin JP, Roux J, Cartel JL. Finger-prick blood collection and computer-assisted enzyme-linked immunosorbent assay for large-scale serological studies on leprosy.Transactions of the Royal Society of Tropical Medicine and Hygiene 83: 414-416, 1989.
23. Chaturvedi V, Sinha S, Girdhar BK, Katoch K, Bhatia AS, Sengupta U. Association of mycobacterial-specific and Mycobacterium leprae specific antibody levels with clinical activity in tuberculoid leprosy: a comparative study of three serological enzyme-immunoassays. Leprosy Review 62: 122-133, 1991.
24. Cho SN, Cellona RV, Fajardo TT Jr, Abalos RM, la Cruz EC, Walsh GP, Kim JD, Brennan PJ. Detection of phenolic glycolipid-I antigen and antibody in sera from new and relapsed lepromatous patients treated with various drug regimens. International Journal of Leprosy and Other Mycrobacteriology Diseases 59: 25-31, 1991.
25. Cho SN, Cellona RV, Villahermosa LG, Fajardo TT Jr, Balagon MV, Abalos RM, Tan EV, Walsh GP, Kim JD, Brennan PJ. Detection of phenolic glycolipid I of Mycobacterium leprae in sera from leprosy patients before and after start of multidrug therapy. Clinical and Diagnostic Laboratory Immunology 8: 138-142, 2001.
26. Cho SN, Yanagihara DL, Hunter SW, Gelber RH, Brennan PJ. Serological specificity of phenolic glycolipid I from Mycobacterium leprae and use in serodiagnosis of leprosy. Infection and Immunity 41:1077-1083, 1983.
27. Chujor CS, Bernheimer H, Levis WR, Schwerer B. Serum IgA1 and IgM antibodies against Mycobacterium leprae-derived phenolic glycolipid-I: a comparative study in leprosy patients and their contacts. International Journal of Leprosy and Other Mycrobacteriology Diseases 59: 441-449, 1991.
28. Cunha MGS, Foss NT. Níveis de anti-PGL1 no soro de pacientes com hanseníase tratados com quinolona e poliquimioterapia. Dissertação de mestrado. Universidade de Ribeirão Preto, UNAERP, Brasil. 1998.
29. Cunha MD, Cavaliere FA, Hercules FM, Duraes SM, de Oliveira ML, de Matos HJ. The impact of leprosy elimination strategy on an endemic municipality in Rio de Janeiro State, Brazil. Cadernos de Saúde Pública 23: 1187-1197, 2007.
30. Desforges S. Specific Anti-M. leprae PGL-1 Antibodies and Mitsuda Reactions in the Management of Household Contacts in New Caledonia.International Journal of Leprosy 57: 794-800, 1989.
31. Douglas J. Prospective study on the early detection of leprosy in household contacts in Cebu. Abstracts, 96^th General Meeting of the American Society for Microbiology. 129, 1996.
32. Douglas JT, Cellona RV, Fajardo TT Jr, Abalos RM, Balagon MV, Klatser PR. Prospective study of serological conversion as a risk factor for development of leprosy among household contacts.Clinical and Diagnostic Laboratory Immunology 11: 897-900, 2004.
33. Douglas JT, Steven LM, Fajardo T, Cellona RV, Madarang MG, Abalos RM, Steenbergen GJ. The effects of chemotherapy on antibody levels in lepromatous patients. Leprosy Review 59: 127-135, 1988.
34. Douglas JT, Steven LM, Hirsch DS, Fujiwara T, Nelson KE, Madarang MG, Cellona RV. Evaluation of four semi-synthetic Mycobacterium leprae antigens with sera from healthy populations in endemic and non-endemic areas. Leprosy Review 63: 199-210, 1992.
35. Douglas JT. Worth RM. Field evaluation of an ELISA to detect antibody in leprosy patients and their contacts. International Journal of Leprosy and Other Mycrobacteriology Diseases 52: 26-33, 1984.
36. Duppre NC, Camacho LAB, Buhrer-Sekula S. Risco de desenvolver hanseníase em contatos de pacientes, segundo positividade ao teste anti PGL-I e situação vacinal (BCG) Fundação Oswaldo Cruz, 2008.
37. Fine PE, Ponnighaus JM, Burgess P, Clarkson JA, Draper CC. Seroepidemiological studies of leprosy in northern Malawi based on an enzyme-linked immunosorbent assay using synthetic glycoconjugate antigen. International Journal of Leprosy and Other Mycrobacteriology Diseases 56: 243-254, 1988.
38. Fine PE, Sterne JA, Ponnighaus JM, Bliss L, Saui J, Chihana A, Munthali M, Warndorff DK. Household and dwelling contact as risk factors for leprosy in northern Malawi. American Journal of Epidemiology 146: 91-102, 1997.
39. Foss NT, Callera F, Alberto FL. Anti-PGL1 levels in leprosy patients and their contacts. Brazilian Journal of Medical and Biological Research 26: 43-51, 1993.
40. Gelber RH, Li F, Cho SN, Byrd S, Rajagopalan K, Brennan PJ. Serum antibodies to defined carbohydrate antigens during the course of treated leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 57: 744-751, 1989.
41. Gonzalez-Abreu E, Pon JA, Hernadez P, Rodriguez J, Mendoza E, Hernandez M, Cuevas E, Gonzalez AB. Serological reactivity to a synthetic analog of phenolic glycolipid I and early detection of leprosy in an area of low endemicity. Leprosy Review 67: 4-12, 1996.
42. Groenen G, Pattyn SR, Ghys P, Tshilumba K, Kuykens L, Colston MJ. A longitudinal study of the incidence of leprosy in a hyperendemic area in Zaire, with special reference to PGL-antibody results. The Yalisombo Study Group. International Journal of Leprosy and Other Mycrobacteriology Diseases 58: 641-650, 1990.
43. Hunter SW, Brennan PJ. A novel phenolic glycolipid from Mycobacterium leprae possibly involved in immunogenicity and pathogenicity. Jornal of Bacteriology 147:728-735, 1981.
44. Hussain R, Jamil S, Kifayet A, Firdausi F, Dockrell HM, Lucas S, Hasan R. Quantitation of IgM antibodies to the M. leprae synthetic disaccharide can predict early bacterial multiplication in leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 58: 491-502, 1990.
45. International Leprosy Association. Epidemiology and Control. International Journal of Leprosy and Other Mycrobacteriology Diseases 70( (suppl I): S46-S52, 2002.
46. Klatser PR, Cho SN, Brennan PJ. The contribution of serological tests to leprosy control. International Journal of Leprosy and Other Mycrobacteriology Diseases 64 (suppl 4): S63-S66, 1996.
47. Klatser PR, de Wit MY, Fajardo TT, Cellona RV, Abalos RM, de la Cruz EC, Madarang MG, Hirsch DS, Douglas JT. Evaluation of Mycobacterium leprae antigens in the monitoring of a dapsone-based chemotherapy of previously untreated lepromatous patients in Cebu, Philippines. Leprosy Review 60: 178-186, 1989.
48. Kumar B, Sinha R, Sehgal S. High incidence of IgG antibodies to phenolic glycolipid in non-leprosy patients in India. Journal of Dermatology 25: 238-241, 1998.
49. Levis WR, Meeker HC., Schuller-Levis G, Sersen E, Schwerer B. IgM and IgG antibodies to phenolic glycolipid I from Mycobacterium leprae in leprosy: insight into patient monitoring, erythema nodosum leprosum, and bacillary persistence. Journal of Investigative Dermatology 86: 529-534, 1986.
50. Lien RA, Faber WR, van Rens MM, Leiker DL, Naafs B, Klatser PR. Follow-up of multibacillary leprosy patients using a phenolic glycolipid-I-based ELISA. Do increasing ELISA-values after discontinuation of treatment indicate relapse? Leprosy Review 63: 21-27, 1992.
51. Lyons NF, Shannon EJ, Ellis BP, Naafs B. Association of IgG and IgM antibodies to phenolic glycolipid-1 antigen of Mycobacterium leprae with disease parameters in multibacillary leprosy patients. Leprosy Review 59: 45-52, 1988.
52. Menzel S, Harboe M, Bergsvik H, Brennan PJ. Antibodies to a synthetic analog of phenolic glycolipid-I of Mycobacterium leprae in healthy household contacts of patients with leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 55: 617-625, 1987.
53. Ministério da Saúde. Guia de Vigilância Epidemiológica. 6Ş edição. Secretaria de Vigilância em Saúde, 2005.
54. Moet FJ, Meima A, Oskam L, Richardus JH. Risk factors for the development of clinical leprosy among contacts, and their relevance for targeted interventions. Leprosy Review 75: 310-326, 2004.
55. Nicholls PG, Bakirtzief Z, Van Brakel WH, Das-Pattanaya RK., Raju MS, Norman G, Mutatkar RK. Risk factors for participation restriction in leprosy and development of a screening tool to identify individuals at risk. Leprosy Review 76: 305-315, 2005.
56. Oliveira MLW. Cura da Hanseníase: Magnitude das recidivas no Brasil, estudo de coortes de diferentes esquemas terapêuticos e fatores de risco. Universidade Federal do Rio de Janeiro, 1996.
57. Parkash O, Kumar A, Pandey R, Nigam A, Girdhar BK. Performance of a lateral flow test for the detection of leprosy patients in India. Journal of Medical Microbiology 57: 130-132, 2008.
58. Payne SN, Draper P, Rees RJ. Serological activity of purified glycolipid from Mycobacterium leprae International Journal of Leprosy and Other Mycrobacteriology Diseases 50: 220-221, 1982.
59. Petchclai B, Khupulsup K, Hiranras S, Sampatavanich S, Sampoonachot P, Leelarusamee A. A passive hemagglutination test for leprosy using a synthetic disaccharide antigen. International Journal of Leprosy and Other Mycrobacteriology Diseases 56: 255-258, 1988.
60. Prakash K, Sehgal VN, Aggarwal R. Evaluation of phenolic glycolipid-I (PGL-I) antibody as a multidrug therapy (MDT) monitor. Journal of Dermatology 20: 16-20, 1993.
61. Ravindran R, Anam K, Bairagi BC, Saha B, Pramanik N, Guha SK, Goswami RP, Banerjee D, Ali N. Characterization of immunoglobulin G and its subclass response to Indian kala-azar infection before and after chemotherapy. Infection and Immunity 72: 863-870, 2004.
62. Rego VP, Machado PR, Martins I, Trindade R, Parana R. [Type 1 reaction in leprosy: characteristics and association with hepatitis B and C viruses]. Revista da Sociedade Brasileira de Medicina Tropical 40: 546-549, 2007.
63. Roche PW, Britton WJ, Failbus SS, Neupane KD, Theuvenet WJ. Serological monitoring of the response to chemotherapy in leprosy patients. International Journal of Leprosy and Other Mycrobacteriology Diseases 61: 35-43, 1993.
64. Roche PW, Failbus SS, Britton WJ, Cole R. Rapid method for diagnosis of leprosy by measurements of antibodies to the M. leprae 35-kDa protein: comparison with PGL-I antibodies detected by ELISA and "dipstick" methods. International Journal of Leprosy and Other Mycrobacteriology Diseases 67: 279-286, 1999.
65. Roche PW, Theuvenet WJ, Britton WJ. Risk factors for type-1 reactions in borderline leprosy patients. Lancet 338: 654-657, 1991.
66. Saad MH, Medeiros MA, Gallo ME, Gontijo PP, Fonseca LS. IgM immunoglobulins reacting with the phenolic glycolipid-1 antigen from Mycobacterium leprae in sera of leprosy patients and their contacts. Memórias do Instituto Oswaldo Cruz 85:191-194, 1990.
67. Schuring RP, Moet FJ, Pahan D, Richardus JH, Oskam L. Association between anti-pGL-I IgM and clinical and demographic parameters in leprosy. Leprosy Review 77: 343-355, 2006.
68. Schuring RP, Richardus JH, Steyerberg EW, Pahan D, Faber W, Oskam L. Preventing nerve function impairment in leprosy: validation and updating of a prediction rule. PLoS Negleted Tropical Diseases. 2008 2: e283, 2008.
69. Soares DJ, Failbus S, Chalise Y, Kathet B. The role of IgM antiphenolic glycolipid-1 antibodies in assessing household contacts of leprosy patients in a low endemic area. Leprosy Review 65: 300-304, 1994.
70. Soebono H, Klatser PR. A seroepidemiological study of leprosy in high- and low-endemic Indonesian villages. International Journal of Leprosy and Other Mycrobacteriology Diseases 59: 416-425, 1991.
71. Stefani MM, Martelli CM, Morais-Neto OL, Martelli P, Costa MB, de Andrade AL. Assessment of anti-PGL-I as a prognostic marker of leprosy reaction. International Journal of Leprosy and Other Mycrobacteriology Diseases 66: 356-364, 1998.
72. Sticht-Groh V, Alvarenga AE, Vettom L, von Ballestrem W. Use of a different buffer system in the phenolic glycolipid-I ELISA. International Journal of Leprosy and Other Mycrobacteriology Diseases 60: 570-574, 1992.
73. Sulcebe G. Nakuci M. Anti-phenolic glycolipid 1 IgM antibodies in leprosy patients and in their household contacts. Leprosy Review 61: 341-346, 1990.
74. Tomimori-Yamashita J, Nguyen TH, Maeda SM, Flageul B, Rotta O, Cruaud P. Anti-phenolic glycolipid-I (PGL-I) determination using blood collection on filter paper in leprosy patients. Revista do Instituto de Medicina Tropical de São Paulo 41: 239-242, 1999.
75. Ulrich M, Smith PG, Sampson C, Zuniga M, Centeno M, Garcia V, Manrique X, Salgado A, Convit J. IgM antibodies to native phenolic glycolipid-I in contacts of leprosy patients in Venezuela: epidemiological observations and a prospective study of the risk of leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 59: 405-415, 1991.
76. van Beers SM, de Wit MY, Klatser PR. The epidemiology of Mycobacterium leprae: recent insight. FEMS Microbiology Letter 136: 221-230, 1996.
77. van Beers SM, Hatta M, Klatser PR. Patient contact is the major determinant in incident leprosy: implications for future control. International Journal of Leprosy and Other Mycrobacteriology Diseases 67: 119-128, 1999.
78. van Beers SM, Izumi S, Madjid B, Maeda Y, Day R, Klatser PR. An epidemiological study of leprosy infection by serology and polymerase chain reaction. International Journal of Leprosy and Other Mycrobacteriology Diseases 62: 1-9, 1994.
79. Van Brakel WH. Disability and leprosy: the way forward. Annals Academy of Medicine Singapore 36: 86-87, 2007.
80. van Beers S, Hatta M, Klatser PR. Seroprevalence rates of antibodies to phenolic glycolipid-I among school children as an indicator of leprosy endemicity. Annals Academy of Medicine Singapore 67: 243-249, 1999.
81. World Health Organization. Expert Committee on Leprosy, Fourth Report. Report No.: 459, 1970.
82. World Health Organization. Expert Committee on Leprosy, Seventh Report. Geneva: World Health Organization, Report No.: 874, 1998.
83. World Health Organization. Global leprosy situation, 2007. Weekly Epidemiological Record 82: 225-232, 2007.
84. Wu Q, Yin Y, Zhang L, Chen X, Yu Y, Li Z, Yu H, Lu C, Feng S, Li X, Huo W, Ye G. A study on a possibility of predicting early relapse in leprosy using a ND-O-BSA based ELISA. IInternational Journal of Leprosy and Other Mycrobacteriology Diseases 70: 1-8, 2002.
85. Wu QX, Ye GY, Li XY. Serological activity of natural disaccharide octyl bovine serum albumin (ND-O-BSA) in sera from patients with leprosy, tuberculosis, and normal controls. International Journal of Leprosy and Other Mycrobacteriology Diseases 56: 50-55, 1988.
86. Yamashita JT, Cruaud P, Papa F, Rotta O, David HL. Circulating immune complexes in leprosy sera: demonstration of antibodies against mycobacterial glycolipidic antigens in isolated immune complexes. International Journal of Leprosy and Other Mycrobacteriology Diseases 61: 44-50, 1993.

Endereço para correspondência:

Dra. Samira Bührer-Sékula

Departamento de Imunologia, sala 335/Instituto de Patologia Tropical e Saúde Pública/UFG

Rua 235, s/no; Setor Universitário

74605-050, Goiânia, GO, Brasil

Tel: 55 62 3209-6111

e-mail:

buhrersekula@iptsp.ufg.br;

samira@buhrer.net

Publication Dates

Publication in this collection
17 July 2009
Date of issue
2008

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

[1] 1. Bach MA, Wallach D, Flageul B, Hoffenbach A, Cottenot F. Antibodies to phenolic glycolipid-1 and to whole Mycobacterium leprae in leprosy patients: evolution during therapy. International Journal of Leprosy and Other Mycrobacteriology Diseases 54: 256-267, 1986.

[2] 2. Bagshawe AF, Garsia RJ, Baumgart K., Astbury L. IgM serum antibodies to phenolic glycolipid-I and clinical leprosy: two years' observation in a community with hyperendemic leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 58: 25-30, 1990.

[3] 3. Bakker MI, Hatta M, Kwenang A, Faber WR, van Beers SM, Klatser PR, Oskam L. Population survey to determine risk factors for Mycobacterium leprae transmission and infection.International Journal of Epidemiology 33: 1329-1336, 2004.

[4] 4. Bakker MI, Hatta M, Kwenang A, Klatser PR, Oskam L. Epidemiology of leprosy on five isolated islands in the Flores Sea, Indonesia. Tropical Medicine and International Health 7: 780-787, 2002.

[5] 5. Brett SJ, Draper P, Payne SN, Rees RJ. Serological activity of a characteristic phenolic glycolipid from Mycobacterium leprae in sera from patients with leprosy and tuberculosis. Clinical and Experimental Immunology 52: 271-279, 1983.

[6] 6. Brett SJ, Payne SN, Gigg J, Burgess P, Gigg R. Use of synthetic glycoconjugates containing the Mycobacterium leprae specific and immunodominant epitope of phenolic glycolipid I in the serology of leprosy. Clinical and Experimental Immunology 64: 476-483, 1986.

[7] 7. Brito MFM. Ximenes RAA, Gallo ME. Associação entre reação hansênica após alta e a carga bacilar avaliada utilizando sorologia anti PGL-I e baciloscopia . Universidade Federal de Pernambuco (UFPE), 2008.

[8] 8. Britton WJ. Lockwood DN. Leprosy. Lancet 363: 1209-1219, 2004.

[9] 9. Buhrer SS, Smits HL, Gussenhoven GC, van Ingen CW, Klatser PR. A simple dipstick assay for the detection of antibodies to phenolic glycolipid-I of Mycobacterium leprae The American Society of Tropical Medicine and Hygiene58:133-136, 1998.

[10] 10. Bührer-Sékula S, van Beers S, Oskam L, Lecco R, Madeira ES, Dutra MAL, Luis MC, Faber W, and Klatser P. The relation between seroprevalence of antibodies to phenolic glycolipid-I among school children and leprosy endemicity in Brazil. Revista da Sociedade Brasileira de Medicina Tropical 41(supl 2) 81-88, 2008.

[11] 11. Buhrer-Sekula S, Cunha MG, Ferreira WA, Klatser PR. The use of whole blood in a dipstick assay for detection of antibodies to Mycobacterium leprae: a field evaluation. FEMS Immunology and Medical Microbiology 21: 197-201, 1998.

[12] 12. Buhrer-Sekula S, Cunha MG, Foss NT, Oskam L, Faber WR, Klatser PR. Dipstick assay to identify leprosy patients who have an increased risk of relapse. Tropical Medicine and International Health 6: 317-323, 2001.

[13] 13. Buhrer-Sekula S, Sarno EN, Oskam L, Koop S, Wichers I, Nery JA., Vieira LM, de Matos HJ, Faber WR, Klatser PR. Use of ML dipstick as a tool to classify leprosy patients. International Journal of Leprosy and Other Mycrobacteriology Diseases 68: 456-463, 2000.

[14] 14. Buhrer-Sekula S, Smits HL, Gussenhoven GC, van Leeuwen J, Amador S, Fujiwara T, Klatser PR, Oskam L. Simple and fast lateral flow test for classification of leprosy patients and identification of contacts with high risk of developing leprosy. Jornal of Clinical Microbiology 41: 1991-1995, 2003.

[15] 15. Buhrer-Sekula S, Visschedijk J, Grossi MA, Dhakal KP, Namadi AU, Klatser PR, Oskam L. The ML flow test as a point of care test for leprosy control programmes: potential effects on classification of leprosy patients. Leprosy Review 78: 70-79, 2007.

[16] 16. Cardona-Castro NM, Restrepo-Jaramillo S, Gil de la Ossa M, Brennan PJ. Infection by Mycobacterium leprae of household contacts of lepromatous leprosy patients from a post-elimination leprosy region of Colombia. Memórias do Instituto Oswaldo Cruz 100: 703-707, 2005.

[17] 17. Cartel JL, Chanteau S, Boutin JP, Plichart R, Richez P, Roux JF, Grosset JH. Assessment of anti-phenolic glycolipid-I IgM levels using an ELISA for detection of M. leprae infection in populations of the South Pacific Islands. International Journal of Leprosy and Other Mycrobacteriology Diseases 58: 512-517, 1990.

[18] 18. Cellona RV, Walsh GP, Fajardo T T Jr, Abalos RM, la Cruz EC, Guido-Villahermosa L, Felicio-Balagon MV, Steenbergen GJ, Douglas JT. Cross-sectional assessment of ELISA reactivity in leprosy patients, contacts, and normal population using the semisynthetic antigen natural disaccharide octyl bovine serum albumin (ND-O-BSA) in Cebu, The Philippines. International Journal of Leprosy and Other Mycrobacteriology Diseases 61: 192-198, 1993.

[19] 19. Chanteau S, Cartel JL, Guidi C, Plichart R, Bach MA. Seroepidemiological study on 724 household contacts of leprosy patients in French Polynesia using disaccharide-octyl-BSA as antigen. International Journal of Leprosy and Other Mycrobacteriology Diseases 55: 626-632, 1987.

[20] 20. Chanteau S, Cartel JL, Roux J. [Leprosy serology: current status and perspectives]. Acta Leprologica 8: 65-70, 1992.

[21] 21. Chanteau S, Cartel JL, Roux J, Plichart R, Bach MA. Comparison of synthetic antigens for detecting antibodies to phenolic glycolipid I in patients with leprosy and their household contacts. Journal of Infectious Diseases 157: 770-776, 1988.

[22] 22. Chanteau S, Plichart R, Boutin JP, Roux J, Cartel JL. Finger-prick blood collection and computer-assisted enzyme-linked immunosorbent assay for large-scale serological studies on leprosy.Transactions of the Royal Society of Tropical Medicine and Hygiene 83: 414-416, 1989.

[23] 23. Chaturvedi V, Sinha S, Girdhar BK, Katoch K, Bhatia AS, Sengupta U. Association of mycobacterial-specific and Mycobacterium leprae specific antibody levels with clinical activity in tuberculoid leprosy: a comparative study of three serological enzyme-immunoassays. Leprosy Review 62: 122-133, 1991.

[24] 24. Cho SN, Cellona RV, Fajardo TT Jr, Abalos RM, la Cruz EC, Walsh GP, Kim JD, Brennan PJ. Detection of phenolic glycolipid-I antigen and antibody in sera from new and relapsed lepromatous patients treated with various drug regimens. International Journal of Leprosy and Other Mycrobacteriology Diseases 59: 25-31, 1991.

[25] 25. Cho SN, Cellona RV, Villahermosa LG, Fajardo TT Jr, Balagon MV, Abalos RM, Tan EV, Walsh GP, Kim JD, Brennan PJ. Detection of phenolic glycolipid I of Mycobacterium leprae in sera from leprosy patients before and after start of multidrug therapy. Clinical and Diagnostic Laboratory Immunology 8: 138-142, 2001.

[26] 26. Cho SN, Yanagihara DL, Hunter SW, Gelber RH, Brennan PJ. Serological specificity of phenolic glycolipid I from Mycobacterium leprae and use in serodiagnosis of leprosy. Infection and Immunity 41:1077-1083, 1983.

[27] 27. Chujor CS, Bernheimer H, Levis WR, Schwerer B. Serum IgA1 and IgM antibodies against Mycobacterium leprae-derived phenolic glycolipid-I: a comparative study in leprosy patients and their contacts. International Journal of Leprosy and Other Mycrobacteriology Diseases 59: 441-449, 1991.

[28] 28. Cunha MGS, Foss NT. Níveis de anti-PGL1 no soro de pacientes com hanseníase tratados com quinolona e poliquimioterapia. Dissertação de mestrado. Universidade de Ribeirão Preto, UNAERP, Brasil. 1998.

[29] 29. Cunha MD, Cavaliere FA, Hercules FM, Duraes SM, de Oliveira ML, de Matos HJ. The impact of leprosy elimination strategy on an endemic municipality in Rio de Janeiro State, Brazil. Cadernos de Saúde Pública 23: 1187-1197, 2007.

[30] 30. Desforges S. Specific Anti-M. leprae PGL-1 Antibodies and Mitsuda Reactions in the Management of Household Contacts in New Caledonia.International Journal of Leprosy 57: 794-800, 1989.

[31] 31. Douglas J. Prospective study on the early detection of leprosy in household contacts in Cebu. Abstracts, 96^th General Meeting of the American Society for Microbiology. 129, 1996.

[32] 32. Douglas JT, Cellona RV, Fajardo TT Jr, Abalos RM, Balagon MV, Klatser PR. Prospective study of serological conversion as a risk factor for development of leprosy among household contacts.Clinical and Diagnostic Laboratory Immunology 11: 897-900, 2004.

[33] 33. Douglas JT, Steven LM, Fajardo T, Cellona RV, Madarang MG, Abalos RM, Steenbergen GJ. The effects of chemotherapy on antibody levels in lepromatous patients. Leprosy Review 59: 127-135, 1988.

[34] 34. Douglas JT, Steven LM, Hirsch DS, Fujiwara T, Nelson KE, Madarang MG, Cellona RV. Evaluation of four semi-synthetic Mycobacterium leprae antigens with sera from healthy populations in endemic and non-endemic areas. Leprosy Review 63: 199-210, 1992.

[35] 35. Douglas JT. Worth RM. Field evaluation of an ELISA to detect antibody in leprosy patients and their contacts. International Journal of Leprosy and Other Mycrobacteriology Diseases 52: 26-33, 1984.

[36] 36. Duppre NC, Camacho LAB, Buhrer-Sekula S. Risco de desenvolver hanseníase em contatos de pacientes, segundo positividade ao teste anti PGL-I e situação vacinal (BCG) Fundação Oswaldo Cruz, 2008.

[37] 37. Fine PE, Ponnighaus JM, Burgess P, Clarkson JA, Draper CC. Seroepidemiological studies of leprosy in northern Malawi based on an enzyme-linked immunosorbent assay using synthetic glycoconjugate antigen. International Journal of Leprosy and Other Mycrobacteriology Diseases 56: 243-254, 1988.

[38] 38. Fine PE, Sterne JA, Ponnighaus JM, Bliss L, Saui J, Chihana A, Munthali M, Warndorff DK. Household and dwelling contact as risk factors for leprosy in northern Malawi. American Journal of Epidemiology 146: 91-102, 1997.

[39] 39. Foss NT, Callera F, Alberto FL. Anti-PGL1 levels in leprosy patients and their contacts. Brazilian Journal of Medical and Biological Research 26: 43-51, 1993.

[40] 40. Gelber RH, Li F, Cho SN, Byrd S, Rajagopalan K, Brennan PJ. Serum antibodies to defined carbohydrate antigens during the course of treated leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 57: 744-751, 1989.

[41] 41. Gonzalez-Abreu E, Pon JA, Hernadez P, Rodriguez J, Mendoza E, Hernandez M, Cuevas E, Gonzalez AB. Serological reactivity to a synthetic analog of phenolic glycolipid I and early detection of leprosy in an area of low endemicity. Leprosy Review 67: 4-12, 1996.

[42] 42. Groenen G, Pattyn SR, Ghys P, Tshilumba K, Kuykens L, Colston MJ. A longitudinal study of the incidence of leprosy in a hyperendemic area in Zaire, with special reference to PGL-antibody results. The Yalisombo Study Group. International Journal of Leprosy and Other Mycrobacteriology Diseases 58: 641-650, 1990.

[43] 43. Hunter SW, Brennan PJ. A novel phenolic glycolipid from Mycobacterium leprae possibly involved in immunogenicity and pathogenicity. Jornal of Bacteriology 147:728-735, 1981.

[44] 44. Hussain R, Jamil S, Kifayet A, Firdausi F, Dockrell HM, Lucas S, Hasan R. Quantitation of IgM antibodies to the M. leprae synthetic disaccharide can predict early bacterial multiplication in leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 58: 491-502, 1990.

[45] 45. International Leprosy Association. Epidemiology and Control. International Journal of Leprosy and Other Mycrobacteriology Diseases 70( (suppl I): S46-S52, 2002.

[46] 46. Klatser PR, Cho SN, Brennan PJ. The contribution of serological tests to leprosy control. International Journal of Leprosy and Other Mycrobacteriology Diseases 64 (suppl 4): S63-S66, 1996.

[47] 47. Klatser PR, de Wit MY, Fajardo TT, Cellona RV, Abalos RM, de la Cruz EC, Madarang MG, Hirsch DS, Douglas JT. Evaluation of Mycobacterium leprae antigens in the monitoring of a dapsone-based chemotherapy of previously untreated lepromatous patients in Cebu, Philippines. Leprosy Review 60: 178-186, 1989.

[48] 48. Kumar B, Sinha R, Sehgal S. High incidence of IgG antibodies to phenolic glycolipid in non-leprosy patients in India. Journal of Dermatology 25: 238-241, 1998.

[49] 49. Levis WR, Meeker HC., Schuller-Levis G, Sersen E, Schwerer B. IgM and IgG antibodies to phenolic glycolipid I from Mycobacterium leprae in leprosy: insight into patient monitoring, erythema nodosum leprosum, and bacillary persistence. Journal of Investigative Dermatology 86: 529-534, 1986.

[50] 50. Lien RA, Faber WR, van Rens MM, Leiker DL, Naafs B, Klatser PR. Follow-up of multibacillary leprosy patients using a phenolic glycolipid-I-based ELISA. Do increasing ELISA-values after discontinuation of treatment indicate relapse? Leprosy Review 63: 21-27, 1992.

[51] 51. Lyons NF, Shannon EJ, Ellis BP, Naafs B. Association of IgG and IgM antibodies to phenolic glycolipid-1 antigen of Mycobacterium leprae with disease parameters in multibacillary leprosy patients. Leprosy Review 59: 45-52, 1988.

[52] 52. Menzel S, Harboe M, Bergsvik H, Brennan PJ. Antibodies to a synthetic analog of phenolic glycolipid-I of Mycobacterium leprae in healthy household contacts of patients with leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 55: 617-625, 1987.

[53] 53. Ministério da Saúde. Guia de Vigilância Epidemiológica. 6Ş edição. Secretaria de Vigilância em Saúde, 2005.

[54] 54. Moet FJ, Meima A, Oskam L, Richardus JH. Risk factors for the development of clinical leprosy among contacts, and their relevance for targeted interventions. Leprosy Review 75: 310-326, 2004.

[55] 55. Nicholls PG, Bakirtzief Z, Van Brakel WH, Das-Pattanaya RK., Raju MS, Norman G, Mutatkar RK. Risk factors for participation restriction in leprosy and development of a screening tool to identify individuals at risk. Leprosy Review 76: 305-315, 2005.

[56] 56. Oliveira MLW. Cura da Hanseníase: Magnitude das recidivas no Brasil, estudo de coortes de diferentes esquemas terapêuticos e fatores de risco. Universidade Federal do Rio de Janeiro, 1996.

[57] 57. Parkash O, Kumar A, Pandey R, Nigam A, Girdhar BK. Performance of a lateral flow test for the detection of leprosy patients in India. Journal of Medical Microbiology 57: 130-132, 2008.

[58] 58. Payne SN, Draper P, Rees RJ. Serological activity of purified glycolipid from Mycobacterium leprae International Journal of Leprosy and Other Mycrobacteriology Diseases 50: 220-221, 1982.

[59] 59. Petchclai B, Khupulsup K, Hiranras S, Sampatavanich S, Sampoonachot P, Leelarusamee A. A passive hemagglutination test for leprosy using a synthetic disaccharide antigen. International Journal of Leprosy and Other Mycrobacteriology Diseases 56: 255-258, 1988.

[60] 60. Prakash K, Sehgal VN, Aggarwal R. Evaluation of phenolic glycolipid-I (PGL-I) antibody as a multidrug therapy (MDT) monitor. Journal of Dermatology 20: 16-20, 1993.

[61] 61. Ravindran R, Anam K, Bairagi BC, Saha B, Pramanik N, Guha SK, Goswami RP, Banerjee D, Ali N. Characterization of immunoglobulin G and its subclass response to Indian kala-azar infection before and after chemotherapy. Infection and Immunity 72: 863-870, 2004.

[62] 62. Rego VP, Machado PR, Martins I, Trindade R, Parana R. [Type 1 reaction in leprosy: characteristics and association with hepatitis B and C viruses]. Revista da Sociedade Brasileira de Medicina Tropical 40: 546-549, 2007.

[63] 63. Roche PW, Britton WJ, Failbus SS, Neupane KD, Theuvenet WJ. Serological monitoring of the response to chemotherapy in leprosy patients. International Journal of Leprosy and Other Mycrobacteriology Diseases 61: 35-43, 1993.

[64] 64. Roche PW, Failbus SS, Britton WJ, Cole R. Rapid method for diagnosis of leprosy by measurements of antibodies to the M. leprae 35-kDa protein: comparison with PGL-I antibodies detected by ELISA and "dipstick" methods. International Journal of Leprosy and Other Mycrobacteriology Diseases 67: 279-286, 1999.

[65] 65. Roche PW, Theuvenet WJ, Britton WJ. Risk factors for type-1 reactions in borderline leprosy patients. Lancet 338: 654-657, 1991.

[66] 66. Saad MH, Medeiros MA, Gallo ME, Gontijo PP, Fonseca LS. IgM immunoglobulins reacting with the phenolic glycolipid-1 antigen from Mycobacterium leprae in sera of leprosy patients and their contacts. Memórias do Instituto Oswaldo Cruz 85:191-194, 1990.

[67] 67. Schuring RP, Moet FJ, Pahan D, Richardus JH, Oskam L. Association between anti-pGL-I IgM and clinical and demographic parameters in leprosy. Leprosy Review 77: 343-355, 2006.

[68] 68. Schuring RP, Richardus JH, Steyerberg EW, Pahan D, Faber W, Oskam L. Preventing nerve function impairment in leprosy: validation and updating of a prediction rule. PLoS Negleted Tropical Diseases. 2008 2: e283, 2008.

[69] 69. Soares DJ, Failbus S, Chalise Y, Kathet B. The role of IgM antiphenolic glycolipid-1 antibodies in assessing household contacts of leprosy patients in a low endemic area. Leprosy Review 65: 300-304, 1994.

[70] 70. Soebono H, Klatser PR. A seroepidemiological study of leprosy in high- and low-endemic Indonesian villages. International Journal of Leprosy and Other Mycrobacteriology Diseases 59: 416-425, 1991.

[71] 71. Stefani MM, Martelli CM, Morais-Neto OL, Martelli P, Costa MB, de Andrade AL. Assessment of anti-PGL-I as a prognostic marker of leprosy reaction. International Journal of Leprosy and Other Mycrobacteriology Diseases 66: 356-364, 1998.

[72] 72. Sticht-Groh V, Alvarenga AE, Vettom L, von Ballestrem W. Use of a different buffer system in the phenolic glycolipid-I ELISA. International Journal of Leprosy and Other Mycrobacteriology Diseases 60: 570-574, 1992.

[73] 73. Sulcebe G. Nakuci M. Anti-phenolic glycolipid 1 IgM antibodies in leprosy patients and in their household contacts. Leprosy Review 61: 341-346, 1990.

[74] 74. Tomimori-Yamashita J, Nguyen TH, Maeda SM, Flageul B, Rotta O, Cruaud P. Anti-phenolic glycolipid-I (PGL-I) determination using blood collection on filter paper in leprosy patients. Revista do Instituto de Medicina Tropical de São Paulo 41: 239-242, 1999.

[75] 75. Ulrich M, Smith PG, Sampson C, Zuniga M, Centeno M, Garcia V, Manrique X, Salgado A, Convit J. IgM antibodies to native phenolic glycolipid-I in contacts of leprosy patients in Venezuela: epidemiological observations and a prospective study of the risk of leprosy. International Journal of Leprosy and Other Mycrobacteriology Diseases 59: 405-415, 1991.

[76] 76. van Beers SM, de Wit MY, Klatser PR. The epidemiology of Mycobacterium leprae: recent insight. FEMS Microbiology Letter 136: 221-230, 1996.

[77] 77. van Beers SM, Hatta M, Klatser PR. Patient contact is the major determinant in incident leprosy: implications for future control. International Journal of Leprosy and Other Mycrobacteriology Diseases 67: 119-128, 1999.

[78] 78. van Beers SM, Izumi S, Madjid B, Maeda Y, Day R, Klatser PR. An epidemiological study of leprosy infection by serology and polymerase chain reaction. International Journal of Leprosy and Other Mycrobacteriology Diseases 62: 1-9, 1994.

[79] 79. Van Brakel WH. Disability and leprosy: the way forward. Annals Academy of Medicine Singapore 36: 86-87, 2007.

[80] 80. van Beers S, Hatta M, Klatser PR. Seroprevalence rates of antibodies to phenolic glycolipid-I among school children as an indicator of leprosy endemicity. Annals Academy of Medicine Singapore 67: 243-249, 1999.

[81] 81. World Health Organization. Expert Committee on Leprosy, Fourth Report. Report No.: 459, 1970.

[82] 82. World Health Organization. Expert Committee on Leprosy, Seventh Report. Geneva: World Health Organization, Report No.: 874, 1998.

[83] 83. World Health Organization. Global leprosy situation, 2007. Weekly Epidemiological Record 82: 225-232, 2007.

[84] 84. Wu Q, Yin Y, Zhang L, Chen X, Yu Y, Li Z, Yu H, Lu C, Feng S, Li X, Huo W, Ye G. A study on a possibility of predicting early relapse in leprosy using a ND-O-BSA based ELISA. IInternational Journal of Leprosy and Other Mycrobacteriology Diseases 70: 1-8, 2002.

[85] 85. Wu QX, Ye GY, Li XY. Serological activity of natural disaccharide octyl bovine serum albumin (ND-O-BSA) in sera from patients with leprosy, tuberculosis, and normal controls. International Journal of Leprosy and Other Mycrobacteriology Diseases 56: 50-55, 1988.

[86] 86. Yamashita JT, Cruaud P, Papa F, Rotta O, David HL. Circulating immune complexes in leprosy sera: demonstration of antibodies against mycobacterial glycolipidic antigens in isolated immune complexes. International Journal of Leprosy and Other Mycrobacteriology Diseases 61: 44-50, 1993.