- Case report
- Open Open Peer Review
Unusual manifestations of visceral leishmaniasis in children: a case series and its spatial dispersion in the western region of São Paulo state, Brazil
BMC Infectious Diseasesvolume 19, Article number: 70 (2019)
Visceral leishmaniasis (VL) is becoming endemic in São Paulo state, in the southeastern region of Brazil. Unusual manifestations with non-specific signs and symptoms may make diagnosis difficult and delay treatment, increasing the risk of severity and death, particularly in new endemic areas. There are few studies on patients with these characteristics in Brazil. We describe a case series of unusual manifestations of VL in children and its spatial dispersion in the western region of São Paulo state.
From 2009 to 2014, five clinical cases involving children treated in the Regional Hospital of Presidente Prudente (RH) were selected. Two patients had multiple relapses requiring liposomal amphotericin B; one patient had VL-cytomegalovirus-dengue co-infection and liver injury; one patient was diagnosed with X-linked agammaglobulinemia, a primary immunodeficiency; and one patient was diagnosed with VL-human immunodeficiency virus/acquired immunodeficiency syndrome (VL-HIV/AIDS) co-infection. Primary or secondary immunodeficiencies were found in four children, and associated viral infections were found in three children. Three patients were referred from other hospitals to RH. With regard to the geographic spread of VL, more cases were found in the northern area, in the epicenter of the infection where the first cases were registered, flowing south; a spatial-temporal occurrence was found.
Primary and secondary immunodeficiencies and viral co-infectious should be considered among unusual manifestations of VL, especially in those with multiple relapses. Spatial-temporal occurrence was found. Thus, integrated actions and effective monitoring of the disease are needed to complement curative practices to stem the tide of the epidemic.
VL is considered a neglected disease, with a higher prevalence in subtropical and tropical regions. In 2013, in Latin America, Brazil harbored 96% of cases, with most of the infected individuals living in the northeast region. In recent years, the disease has been spreading fast and has been reported in humans or dogs in 26 Brazilian states, with 19 states reporting cases of autochthonous human VL . In 1996, infected dogs and humans were found in Araçatuba in the northwest of São Paulo state, and in 2006 the disease reached the western region, with 45 municipalities and about 900,000 inhabitants [2, 3]. These municipalities comprise the Regional Health Assistance Network11 (RRAS11), located in Presidente Prudente’s mesoregion. In this region, from 2006, when the first human case was reported in Dracena, a city with high transmission rates, to 2017, 18 of the 45 municipalities reported 492 human cases and 27 deaths, a lethality rate of 5.5% [4, 5]. The vector of VL, Lutzomyia longipalpis was found in 34 municipalities and canine VL was found in 28 municipalities .
In endemic areas of developing countries, about 50% of individuals treated for VL may be children . VL is a long-term febrile disease and the clinical signs are non-specific and characterized by fever, paleness, weight loss, increased abdominal volume, hepatosplenomegaly, and edema. In new endemic areas, because of the non-specific signs and symptoms, VL can be misdiagnosed with delay in treatment, increasing the severity of the disease . There are few studies on patients with these characteristics in Brazil. In this scenario, tertiary public hospitals play a key role in the Unified Public Health System throughout Brazil. They support smaller hospitals and more complex treatment procedures are performed . Spatial analytic techniques have been used as valuable tools in epidemiologic studies, particularly for infectious diseases, including leishmaniasis. They can denote the points of occurrence and the intensity of certain phenomenon, helping public health authorities in their strategies for control and preventive measures. Furthermore, they can predict the dispersion of parasites and vectors and the influence of the neighborhood in the spread of the disease [2, 3, 7]. Here, we describe a case series of unusual manifestations of VL in children and its spatial dispersion in the western region of São Paulo state, considered a new focus of VL in Brazil. Cases were selected based on unusual manifestations in the emergency room, unexpected evolution on treatment, or rare co-morbidities/co-infections.
Case series presentation
On February 22, 2014, a 24-month-old girl referred from Dracena’s municipal hospital (Fig. 1, number 1) was admitted to RH and her parents related that she had had a fever for 10 days. In the previous 3 days, her health had worsened significantly with adynamia, pallor, inappetence, oliguria, and choluria. On systematic examination, she was lethargic, her skin was discolored (4+/4+), and hypoactive. A radiographic image on admission suggested pneumonia. Complete blood count showed marked anemia, thrombocytopenia, and a significant increase in hepatic enzymes (Table 1, column 1). Abdominal ultrasonography showed pronounced hepatosplenomegaly. Supported by her health status, laboratory and image examinations, and the fact that she lived in an endemic region, VL was suspected. The laboratory diagnostics (Table 1, column 1) recommended mainly by the Manual of Surveillance and Control of Visceral Leishmaniasis of São Paulo state [8,9,10,11] included direct parasitology consisting of the presence of amastigotes of Leishmania in bone marrow aspirate stained by Giemsa stain; a serological titer ≥1:80 in an indirect fluorescent antibody test (IFAT; Bio-Manguinhos/FIOCRUZ, Rio de Janeiro, Brazil); and in 2010, the rK39 rapid diagnostic test (Kalazar Detect, InBios, Seattle, Washington, USA) was implemented. She was sent to the pediatric intensive care unit (ICU) from the emergency department and treated with liposomal amphotericin B (5 mg/kg/day) for 5 days. Serology screening showed that she was positive for cytomegalovirus (CMV) antibodies IgG and IgM. At the end of VL treatment, she had severe liver injury, presenting hyperbilirubinemia, hypoalbuminemia, and increased liver and canalicular enzymes: alanine transaminase (ALT) 354 IU/mL; aspartate transaminase (AST) 401 IU/mL; alkaline phosphatase 993 mg/dL; γ-glutamyl transferase 1048 mg/dL; total bilirubin 5.77 mg/dL, leading to fecal acholia, jaundice, and hypoalbuminemia (2.7 g/dL). Because there was an outbreak of dengue fever in her home region, dengue was suspected and IgM serology was positive in two different samples. She remained in the pediatric ICU for 12 days and was discharged after 24 days. At discharge, the case was diagnosed as VL-CMV-dengue virus co-infection and liver injury, and she was followed for 1 year as an ambulatory patient with pediatric infectious diseases. In March, 2017, she was hospitalized with severe respiratory distress and renal failure, remaining in the pediatric ICU; she died 2 days later with a diagnosis of Brazilian spotted fever transmitted by ticks for which the causative agent is Rickettsia rickettsii.
On May 28, 2009, a 13-month-old boy residing in Tupi Paulista municipality (Fig. 1, number 2) was admitted with fever, inappetence, and splenomegaly. On systematic examination, he was pale and febrile with a distended abdomen and hepatosplenomegaly. Because he lives in an endemic area, VL was suspected and bone marrow aspirate examinations were conducted according to the laboratory diagnostics recommended by the Manual of Surveillance and Control of Visceral Leishmaniasis of São Paulo state  (Table 1, column 2). At diagnosis, his laboratory results were as follows: total protein 6.8 g/dL, albumin 3.6 g/dL, globulin 3.2 g/dL, and A:G ratio of 1.1 with a 2-fold increase and 12-fold increase in IgG and IgE immunoglobulin levels, respectively. Serum protein electrophoresis revealed polyclonal hypergammaglobulinemia: total protein 7.3 g/dL, albumin 3.95 g/dL, alpha1-globulin 0.41 g/dL, alpha2-globulin 0.76 g/dL, beta1-globulin 0.43 g/dL, beta2-globulin 0.23 g/dL, gamma-globulin 1.53 g/dL (20.9%; reference 10.6%–18.8%). He was treated with liposomal amphotericin B (5 mg/kg/day) for 5 days with improvement in the symptoms and 50% reduction of splenomegaly. CMV IgG and IgM antibodies were detected in the serology screening. After 8 days, he was discharged with a diagnosis of VL-CMV co-infection. However, the patient had a relapse several times at 59 days, 79 days, and 156 days after discharge. On each recurrence, he was admitted to the pediatric ward and underwent the standard treatment for 5 days. After the last infection, he was treated with an HIV-positive immunosuppressed regimen (liposomal amphotericin B, 5 mg/kg/day, 1 day per month for 6 months). A primary immunodeficiency was investigated and immunophenotyping and lymphocyte proliferation were at normal levels (Table 2, column 1). At discharge, he was diagnosed as VL-CMV co-infection and treated with an immunosuppressed regimen. After treatment, immunoglobulin and serum protein electrophoresis showed normal levels. After this protocol, he did not relapse and was followed for 1 year as an ambulatory patient with pediatric infectious diseases.
On November 13, 2014, a 14-month-old girl residing in Ouro Verde municipality (Fig. 1, number 3) was referred from Dracena’s municipal hospital; her parents related that she had been vomiting and had had a fever for 9 days. VL was suspected and bone marrow aspirates, IFAT and rK39 were conducted according to the laboratory diagnostics recommended by the Manual of Surveillance and Control of Visceral Leishmaniasis of São Paulo state  (Table 1, column 3). On systematic examination, her health status was regular, but she was pale (1+/4+), with a distended abdomen and hepatosplenomegaly (Table 1, column 3). She was treated with liposomal amphotericin B (5 mg/kg/day) for 5 days and was found to have severe anemia. Red blood cells (15 mL/kg/day) were transfused twice, and the patient was discharged 15 days later with a diagnosis of VL. However, the patient had a relapse several times at 98 days, 131 days, 156 days, and 171 days, with the same symptoms at different time intervals. On each recurrence, she was admitted to the pediatric ward and underwent the standard treatment for 5 days. After the last hospitalization (at 171 days), she was treated with an HIV-positive immunosuppressed regimen (liposomal amphotericin B, 5 mg/kg/day, 1 day per month for 6 months). A primary immunodeficiency was investigated and immunophenotyping showed normal levels, however a decrease in lymphoproliferation against mitogens and CMV antigen was found (Table 2, column 2). In the course of the relapse treatment, she had multiple upper airway infections (community-acquired pneumonia, tonsillitis, and sinusitis). Specific antibody responses to pneumococcal polysaccharide vaccine (representing a T cell- independent response) and tetanus, diphtheria, and hepatitis B virus after vaccination (representing a T cell-dependent response) were investigated. The concentration of antibodies was below protective levels after vaccination. Furthermore, the patient showed a poor polysaccharide antibody response to a 23-valent pneumococcal vaccine. After completing the immunosuppressed regimen, she did not relapse, and she is being followed as an ambulatory patient with pediatric infectious diseases and immunodeficiencies.
On November 23, 2010, a 8-month-old boy referred from Dracena’s municipal hospital (Fig. 3, number 4) was admitted to RH with fever, cough, and vomiting for the previous 5 days. On systematic examination, he was pale, febrile, dehydrated with tachydyspnea, distended abdomen, and hepatosplenomegaly. He was sent to the pediatric ICU and treated for community-acquired pneumonia. Because he lives in an endemic area, VL was suspected and bone marrow aspirate examinations were conducted according to the laboratory diagnostics recommended by the Manual of Surveillance and Control of Visceral Leishmaniasis of São Paulo state . (Table 1, column 4). He was treated with liposomal amphotericin B (5 mg/kg/day) for 5 days. Immunoglobulin levels were determined, resulting in pan-hypogammaglobulinemia. Immunophenotyping and lymphocyte proliferation were investigated, and he was diagnosed as X-linked agammaglobulinemia (XLA). Patients with XLA have absent or reduced number of peripheral B cells and a profound deficiency in all immunoglobulin isotypes (Table 2, column 3). He was discharged after 20 days, and he is being followed as an ambulatory patient with immunodeficiencies with human IgG immunoglobulin (400 mg/kg) replacement at intervals of 28 days.
In 2011, a 11-year-old girl, residing in Paulicéia municipality (Fig. 3, number 5), was admitted to RH (personal data ). She was AIDS-C3 with low levels of CD4, high viral load, severe diarrhea, oral and perineal candidiasis, severe thrombocytopenia, and protein-caloric malnourishment. She had sepsis and renal and cardiac failure. She was sent to the pediatric ICU, and because she lives in an endemic region, VL was suspected. Bone marrow aspirate examinations according to the laboratory tests recommended by the Manual of Surveillance and Control of Visceral Leishmaniasis of São Paulo state were conducted  (Table 1, column 5). Her symptoms improved significantly after administration of liposomal amphotericin B. However, on the 47th day of hospitalization, she had a relapse with thrombocytopenia and retreatment with liposomal amphotericin B and intravenous human IgG immunoglobulin was given. She was discharged after 71 days, diagnosed as VL-HIV/AIDS co-infection. The patient was lost to follow-up.
Discussion and conclusions
American Tegumentar Leishmaniasis (AT) and VL are found in all regions of Brazil. The main causative agents of AT are Leishmania (Leishmania) amazonensis, Leishmania (Viannia) guyanensis, and Leishmania (Viannia) braziliensis which is responsible for the muco-cutaneous form in São Paulo state. Countrywide, Leishmania infantum (syn. Leishmania chagasi) is the causative agent of VL, and it is found especially in dogs (the main domestic reservoir), in cats and in humans [9,10,11]. Using different independent molecular methods, the genetic diversity of L. infantum isolates obtained from different endemic areas in Brazil revealed 18 very similar genotypes .
Despite the measures adopted by public authorities to control VL throughout São Paulo state, there is evidence that the disease is spreading at an alarming rate throughout the western region [4, 12, 13]. Since 2009, RH has been a reference center for the diagnosis and treatment of children thought to be infected with VL in the RRAS11 region. From January 2005 to December 2017, 157 children have been diagnosed and treated.
VL is an immune-mediated disease affecting mostly children because of their immature cell-mediated immune system, the cornerstone effector mechanism in VL infection, and older people as a result of senescence [4,5,6,7,8,9,10,11,12]. Among the patients selected for this study, four (80%) showed immune deregulation at diagnosis or during follow-up.
Case 1 involved co-infection with VL and dengue virus, both blood-borne diseases with a biological cycle in the liver and liver dysfunction. In patients infected with VL, a good prognosis is associated with reduction in the effects on the liver and spleen by 50% from onset to discharge and a decrease or normalization of the hepatic enzymes at the end of treatment [14, 15]. The cells of the reticuloendothelial system in the liver harbor VL parasites, and hepatomegaly is common. In India, functional derangement of the liver in individuals infected with VL was found to be common . Surprisingly, in our patient, at the end of treatment for VL, she had severe liver injury, and dengue IgM serology confirmed VL-dengue virus co-infection. Liver involvement in acute dengue infection is frequently observed, leading to liver dysfunction. The severity depends on hypoxic injury as a result of decreased perfusion, the degree of viral load, and the deregulated immunologic lesions triggered by inflammatory immune mediators . The spectrum of involvement ranges from asymptomatic increased levels of hepatic enzymes to acute liver failure. As in our patient, in children infected with dengue, increased AST/ALT levels, hepatomegaly, jaundice, and hypoalbuminemia are the main features. In Thailand and in Northern India, dengue was the major cause of acute liver failure in children with rates of 18.5 and 34%, respectively [17, 18]. However, to our knowledge, a VL-dengue co-infection has not been described previously.
Cases 2 and 3 were characterized by relapses with repeated treatments with liposomal amphotericin B. Following the Manual of Surveillance and Control of American Visceral Leishmaniasis of the State of São Paulo , the use of amphotericin B is restricted to a few special conditions. In 2006, in an effort to lower death rates from VL, especially in children, attributed to the use of pentavalent antimony as first-line therapy, São Paulo state recommended liposomal amphotericin B therapy for all children up to 10 years of age . Relapse after treatment with liposomal amphotericin B is associated with increased lethality rates, poor prognosis, and disease severity among children [14, 20]. Little is known regarding the characteristics of apparently immunocompetent patients with VL who relapsed among different regions, treatment regimens, and study populations. In the Brazilian guidelines, there are no instructions on how to manage these patients. In Sudan, relapsed patients showed splenomegaly at diagnosis and at discharge [15, 21]; in Georgia, delay in the diagnosis for > 90 days, low levels of hemoglobin, and age < 1 year ; in India, male sex, aged 5–45 years, a smaller decrease in splenomegaly at discharge, and a shorter duration of symptoms before seeking treatment were strongly associated with relapse . In patients with acquired immunodeficiency, mostly patients with HIV infection, the burden of VL infection and relapse is aggravated by impaired T cell number and function and, consequently, decreased T and B cell interaction [23, 24]. In an attempt to find the primary immunodeficiency that explained the increased number of relapses in our patients, immunophenotyping, lymphocyte proliferation, and humoral response against vaccines were conducted. A normal range of peripheral immune cells was found in both patients, however, patient 3 (Table 2, column 2) showed a decrease in lymphoproliferation against OKT3 (anti-CD3) mitogen and CMV antigen. Furthermore, she did not respond to T cell-dependent vaccines, anti-HBS and anti-tetanus, or to T cell-independent pneumo-23 polysaccharide vaccines. These results explain in part the repeated upper airways infections that affected the patient during treatment with liposomal amphotericin B in the relapsing period. Conversely, at onset of diagnosis of VL, patient 2 (Table 2, column 1) showed polyclonal gammopathy with increased levels of IgG and IgE and a slight hypergammaglobulinemia that quickly decreased to normal levels after treatment. Both patients recovered when the protocol for secondary prophylaxis to immunosuppressed patients was applied. Patients 2 and 3 required great effort from our team who contacted many other hospitals and doctors to discuss the drug and the duration of treatment to be adopted. Currently, a new protocol addressing these issues is being proposed in the state of São Paulo. Increasing rates of relapse against liposomal amphotericin B, the standard treatment for children, are occurring in our region. Of 157 children treated, 15 have relapsed (9.5%).
Case 4 arrived in the emergency room with fever, tachydyspnea, and cough, and community-acquired pneumonia associated with VL was diagnosed. Certainly, the undiagnosed primary immunodeficiency contributed to the severity of his condition. XLA deficiency is caused by mutations of the Bruton tyrosine kinase gene and is the most common form of severe inherited antibody deficiency. It is characterized by a fully penetrant X-linked recessive disorder with recurrent bacterial infections, including upper and lower airways infections, profound hypogammaglobulinemia, and marked decrease or absence of peripheral mature B cells . As shown in Table 2, column 3, he exhibited normal levels of T cell subsets and lymphocyte proliferation against mitogens. However, total depletion of CD19+ B cells, no antibody response to vaccine antigens, representing a decrease in a B and T cell-dependent response, and hypogammaglobulinemia were found. He was not receiving intravenous immunoglobulin replacement therapy at the diagnosis of VL. To our knowledge, this is the first report of VL-XLA infection worldwide.
Case 5 represents an unwelcome synergy and was the first case of a child co-infected with HIV/AIDS and VL described in the western region of São Paulo state . In Brazil, from January 1980 to June 2016, 842,710 cases of AIDS were reported, and the rate of detection of AIDS in children < 5 years of age has been used as a proxy indicator for monitoring the vertical transmission of HIV, with a local and countrywide reduction [26,27,28]. HIV-VL co-infection is considered an emerging disease in some developed and developing countries, with increasing rates since the beginning of the 1990s. The burden of the disease is fueled by geographic superposition of the two infections as a consequence of the urbanization of VL and the internalization of HIV infection [28, 29]. Previously, VL was restricted to rural areas in the northeastern region, responsible for 70–90% of cases, but since the 1980s, the formation of shantytowns with very poor living conditions favored important outbreaks in large Brazilian cities. Conversely, as a result of the countrywide spread of HIV infection in all social classes, outbreaks have moved from large urban centers to the smaller towns [28,29,30]. This new scenario represents a challenge for the control of HIV-VL co-infection . In Brazil, HIV-VL co-infection has increased from 0.7% in 2001 to 8.5% in 2012 [23, 24]. HIV/AIDS is burdensome for children co-infected with VL, with decreasing anti-leishmania antibodies titers and therapeutic response, increasing susceptibility to severe hospital-acquired infections, greatly increased probability of relapse, and high mortality rates [12, 23, 24, 30]. The onset of clinical manifestations, diagnosis, and treatment of VL and discharge of the patient at 71 days was longer than usual in children treated in RH. In new endemic areas, lack of awareness of the occurrence of unusual manifestations may cause considerable difficulties in establishing the diagnosis [4, 12], and should be considered the reason for the delay in the diagnosis of VL in this case report.
In these selected case reports, 50% were associated with viral infections: CMV, dengue, and HIV. Co-infection of CMV with leishmaniasis produces a diagnostic dilemma because of the similarity of some clinical features and hematologic parameters, including fever, leukopenia, and thrombocytopenia . Moreover, CMV infection has an immunomodulating and immunosuppressant effect on humoral and cellular immune responses, predisposing the patient to other infections. CMV may also be part of the super-infections reported in patients with VL .
Three (60%) of our patients were referred from other hospitals, and three (50%) were sent from the emergency room to the ICU because of worsening of their clinical status, reinforcing the role of tertiary hospitals in the Brazilian public health system and fueled by the severity of unusual manifestations of VL.
São Paulo state has experienced a rapid spread of the vector and canine and human VL over the last two decades, and some regions, including the western region, are becoming new endemic areas in Brazil [4, 13]. In this region, the epicenter of the infection was in the northern part, with clusters of municipalities harboring higher numbers of cases (48–153), bordered by municipalities with a medium (14–36) and low number of cases (1–4), in 2005–2015 (Fig. 2). These municipalities, are linked by contiguity to the municipality of Andradina, outside RRAS11 and considered endemic by the Brazilian Ministry of Health since 2005 [4, 12, 13] (Fig. 3). All children in this report lived in municipalities in which the disease was first described in 2005–2006. Cases 1 and 4 lived in Dracena, case 2 in Tupi Paulista, case 3 in Ouro Verde, and case 5 in Paulicéia (Figs. 1 and 2). With the exception of Paulicéia, the other municipalities registered medium or high number of cases in 2005–2015 (Fig. 2). From Dracena, the disease spread toward the north and then toward the municipalities of Pontal of Paranapanema, the poorest and most undeveloped region of São Paulo, and toward Paraná state in the south (Figs. 1 and 3). Considering these results, a spatial-temporal geographic occurrence in the spread of VL was found in the western region of São Paulo state.
The reasons why VL is spreading in such a fast and alarming way in this region are not well understood. A complex array of factors may be fueling the epidemic and sustaining endemic transmission . In São Paulo state, the association of the spread of VL throughout the area around the Marechal Candido Rondon Highway, the Bolivia-Brazil railway, and the gas pipeline construction (GASBOL), linking the endemic region of Mato Grosso state in direction of São Paulo, is overwhelming  (Fig. 3). Similarly, we suggest that in RRAS11, the dispersion of canine VL and human VL vectors is associated with the Euclides Figueiredo Highway as the primary axis, and the Julio Budinsky Highway as the secondary axis. Nevertheless, dissemination of the vectors of VL could be aggravated by the extensive watershed flowing into the three biggest rivers of southwestern and southern Brazil, with nine large lakes and a flooded area of 2384 mile2, supporting hydroelectric plants and bridges. These bridges link dozens of small towns and villages connected by a large number of highways (1480 miles). They support a daily flow of people, cars, animals, and goods linking endemic regions to VL-free areas (Fig. 3).
Some shortcomings should be mentioned when interpreting our data. This is a retrospective study over 10 years with selection bias as a result of different investigators. The protocol for VL diagnosis changed during the study period and immunophenotyping and lymphocyte proliferation were not available for all patients.
Primary and secondary immunodeficiencies and viral co-infections should be considered among unusual manifestations of VL, especially in those with multiple relapses. In this scenario, tertiary reference hospitals have a key role in the Brazilian public health system. In the geographic spread of VL, a higher number of cases were demonstrated in the northern part, in the epicenter of the area where the first cases were registered, flowing to the south and a spatial-temporal occurrence was found. Thus, integrated actions and effective monitoring of the disease are needed to complement curative practices to stem the tide of the epidemic.
Human immunodeficiency virus/acquired immunodeficiency syndrome
Intensive care unit
Regional Hospital of Presidente Prudente
Regional Health Assistance Network11
Pan American Health Organization. LEISHMANIASES Epidemiological Report of the Americas. Report Leishmaniases No 4 - July, 2016. http://iris.paho.org/xmlui/bitstream/handle/123456789/34856/LeishReport6_eng.pdf?sequence=1&isAllowed=y.
Oliveira AM, Vieira CP, Dibo MR, Guirado MM, Rodas LAC, Chiaravalloti-Neto F. Dispersal of Lutzomyia longipalpis and expansion of canine and human visceral leishmaniasis in São Paulo State, Brazil. Acta Tro. 2016;164:233–42.
Cardim MFM, Guirado MM, Dibo MR, Chiaravalloti F. Visceral leishmaniasis in the state of Sao Paulo, Brazil: spatial and space-time analysis. Rev Saude Publica. 2016;50:48.
Naufal Spir PR, Prestes-Carneiro LE, Fonseca ES, Dayse A, Giuffrida R, D’Andrea LAZ. Clinical characteristics and spatial distribution of Visceral leishmaniasis in children in São Paulo state: an emerging focus of Visceral leishmaniasis in Brazil. Pathog Glob Health. 2017;111:91–7.
Governo do Estado de São Paulo. Secretaria da Saúde. Centro de vigilância epidemiológica. 2014 a 2017 Casos confirmados de Leishmaniose Visceral segundo LPI e ano de notificação, Estado de São Paulo. http://www.saude.sp.gov.br/resources/cve-centro-de-vigilancia-epidemiologica/areas-de-vigilancia/doencas-de-transmissao-por-vetores-e-zoonoses/dados/leish/lv1418_lpi.pdf.
Palumbo E. Visceral leishmaniasis in children: a review. Minerva Pediatr. 2010;2(4):389–95.
Sevá A da P, Mao L, Galvis-Ovallos F, Tucker Lima JM, Valle D. Risk analysis and prediction of visceral leishmaniasis dispersion in São Paulo State, Brazil. PLoS Negl Trop Dis. 2017;11:e0005353.
São Paulo. Manual de Vigilância e Controle da Leishmaniose Visceral Americana do Estado de São Paulo. Secr. Estado da Saúde. 2006;161. http://www.saude.sp.gov.br/resources/sucen/homepage/downloads/arquivos-leishmaniose-visceral-americana/manual_lva.pdf.
Metzdorf IP, da Costa LMSJ, de Fatima CMM, de Souza Filho AF, de Souza TRA, Franco KG, Shapiro JT, de Almeida BF. Molecular characterization of Leishmania infantum in domestic cats in a region of Brazil endemic for human and canine visceral leishmaniasis. Acta Trop. 2017;166:121–5.
Coutinho CE, Santos DO, Baptista C, Figueiredo FB, Madeira MF. Evaluation of Leishmania (Leishmania) chagasi strains isolated from dogs originating from two visceral leishmaniasis endemic areas in Brazil using multilocus enzyme electrophoresis. Rev Soc Bras Med Trop. 2011;44(5):572–5.
Segatto M, Ribeiro LS, Costa DL, Costa CH, Oliveira MR, Carvalho SF, Macedo AM, Valadares HM, Dietze R, Brito CF, Lemos EM. Genetic diversity of Leishmania infantum field populations from Brazil. Mem Inst Oswaldo Cruz. 2012;107(1):39–47.
Naufal Spir PR, Zampieri D’Andrea LA, Fonseca ES, Prestes-Carneiro LE. Epidemiology of human immunodeficiency virus-visceral leishmaniasis-co-infection. J Microbiol Immunol Infect. 2013;49:295–9.
D’Andrea LAZ, Fonseca E da S, Prestes-Carneiro LE, Guimarães RB, Yamashita RC, Soares CN, et al. The shadows of a ghost: a survey of canine leishmaniasis in Presidente Prudente and its spatial dispersion in the western region of São Paulo state, an emerging focus of visceral leishmaniasis in Brazil. BMC Vet Res. 2015;11:273.
Burza S, Sinha PK, Mahajan R, Lima MA, Mitra G, Verma N, et al. Risk factors for visceral leishmaniasis relapse in immunocompetent patients following treatment with 20 mg/kg liposomal amphotericin B (Ambisome) in Bihar,India. PLoS Negl Trop Dis. 2014;8(1):e2536.
Gorski S, Collin SM, Ritmeijer K, Keus K, Gatluak F, Mueller M, et al. Visceral leishmaniasis relapse in Southern Sudan (1999-2007): a retrospective study of risk factors and trends. PLoS Negl Trop Dis. 2010;4(6):e705.
Mathur P, Samantaray JC, Samanta P. High Prevalence of Functional Liver Derangement in Visceral Leishmaniasis at an Indian Tertiary Care Center Clin. Gastroenterol Hepatol. 2008;6:1170–2.
Kye Mon K, Nontprasert A, Kittitrakul C, Tangkijvanich P, Leowattana W, Poovorawan K. Incidence and Clinical Outcome of Acute Liver Failure Caused by Dengue in a Hospital for Tropical Diseases, Thailand. Am J Trop Med Hyg. 2016;95(6):1338–44.
Jagadishkumar K, Jain P, Manjunath VG, Umesh L. Hepatic involvement in dengue fever in children. Iran J Pediatr. 2012;22(2):231–6.
Madalosso G, Fortaleza CM, Ribeiro AF, Cruz LL, Nogueira PA, Lindoso JA. American visceral leishmaniasis: factors associated with lethality in the state of São Paulo, Brazil. J Trop Med. 2012;281572:2012.
Braga AS, Toledo Junior AC, Rabello A. Factors of poor prognosis of visceral leishmaniasis among children under 12 years of age. A retrospective monocentric study in Belo Horizonte, State of Minas Gerais, Brazil, 2001-2005. Rev Soc Bras Med Trop. 2013;46(1):55–9.
Mueller M, Ritmeijer K, Balasegaram M, Koummuki Y, Santana MR, Davidson R. Unresponsiveness to AmBisome in some Sudanese patients with kala-azar. Trans R Soc Trop Med Hyg. 2007;101:19–24.
Kajaia M, Morse DL, Kamkamidze G, Butsashvili M, Chubabria G, Zenaishvili O, et al. Risk factors for relapse of visceral leishmaniasis in Georgia. Trop Med Int Heal. 2011;186–192(25):16.
Lindoso JA, Cunha MA, Queiroz IT, Moreira CH. Leishmaniasis – HIV coinfection : current challenges. HIV AIDS (Auckl). 2016;7(8):147–56.
Lindoso JA, Cota GF, da Cruz AM, Goto H, Maia-Elkhoury AN, Romero GA et al. Visceral leishmaniasis and HIV coinfection in Latin America. PLoS Negl Trop Dis. 2014; 18;8(9):e3136.
Vu QV, Wada T, Le HT, Le H, Van Nguyen A, Osamu O, et al. Clinical and mutational features of Vietnamese children with X-linked agammaglobulinemia. BMC Pediatr. 2014;14:129.
Lúcia V, Alves M, Troiani C, Ribeiro AA, Rodrigues P, Spir N, et al. Vertical transmission of HIV-1 in the western region of the State of São Paulo. Rev Soc Bras Med Trop. 2011;44:4–7.
Prestes-Carneiro LE, Miguel NA, Ascencio EL, Amancio M, Alcantara VLM, Portelinha-Filho JA. Rapid HIV diagnostic test in undocumented pregnant women applied at an inner-city teaching hospital. Rev Inst Med Trop Sao Paulo. 2009;51:273–6.
Ministério da Saúde. Boletim Epidemiológico HIV AIDS 2016. http://www.aids.gov.br/pt-br/pub/2016/boletim-epidemiologico-de-aids-2016.
Ministério da Saúde. Manual de recomendações para diagnóstico, tratamento e acompanhamento de pacientes com a coinfecção Leishmania-HIV 2015. http://bvsms.saude.gov.br/bvs/publicacoes/manual_recomendacoes_diagnostico_leishmania_hiv.pdf.
World Health Organization. Visceral leishmaniasis, Leishmania–HIV coinfection. http://www.who.int/leishmaniasis/epidemic/special_conditions_hiv_coinfection/en/
Prasad R, Muthusami S, Pandey N, Tilak V, Shukla J, Mishra OP. Unusual presentations of Visceral leishmaniasis. Indian J Pediatr. 2009;76:843–5.
Halkic N, Ksontini R, Scholl B, Blanc C, Kovacsovics T, Meylan P, et al. Recurrent cytomegalovirus disease, visceral leishmaniosis, and Legionella pneumonia after liver transplantation: a case report. Can J Anaesth. 2004;51(1):84–7.
No funding support was received.
Availability of data and materials
All data generated or analyzed during this study are included in this article.
Ethics approval and consent to participate
The study was approved by the research ethics committee at Universidade do Oeste Paulista and Plataforma Brasil (certificate of ethical approval protocol number 2.127.403). Written informed consent was obtained from the parents of the reported cases for this paper to be published.
Consent for publication
Written informed consent was obtained from the guardians of patients described in these case reports. A copy of the written consent is available for review by the Editor of this journal.
The authors declare that they have no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.