We included 216 CTS cases in this analysis. Case-patients were more frequently female than male (ratio 1.8:1) except in the 11–17 year age group (Figure 2). Median age among CTS case-patients was 40 years (interquartile range 22.5–56.0 years) (Table 2); 29 (13%) patients were <18 years of age. Overall, 11% of patients had occupations with disease-related risk factors, including 9 veterinarians, 5 veterinary students, 3 pet sitters, and 2 gardeners. The most frequent clinical form of sporotrichosis was lymphocutaneous (n = 136, 63%), followed by fixed cutaneous (n = 53, 25%), ocular (n = 21, 10%), mixed forms (n = 5, 2%), and cutaneous disseminated (n = 1, <0.5%). We observed that some CTS case-patients had unusual clinical manifestations (Figure 3).

Overall, 84 (39%) patients had proven CTS and 132 (61%) had probable CTS. Among probable CTS cases, we tested 18 patients by microscopy and culture, and all tested negative. Laboratory testing was not requested for the 14 remaining probable CTS case-patients; the main causes for not testing were specimen unavailability for microbiology testing and previous initiation of antifungal treatment. Among the proven CTS cases, Sporothrix isolates were collected from direct swabbing of lesion secretions for 50 patients, skin biopsy for 29, and aspirate from abscesses for 5. Average times for positive Sporothrix culture results varied by specimen type: specimens collected using the swab method averaged 6 days (range 3–17 days), compared with 13 days (range 4–30 days) for specimens collected by biopsy (p<0.0001). On the basis of phylogenetic analysis of calmodulin sequence genes of 38 Sporothrix isolates from patients, we identified S. brasiliensis as the only etiologic agent (38/38 cases) of CTS during the study period (Figure 4).

In 98% (212) of the 216 total CTS cases, infection was associated with zoonotic transmission; in those cases, the patient had direct or indirect contact with a cat with diagnosed sporotrichosis. In 4 (2%) sporadic cases, occurring in 2016, 2017, 2019, and 2021, infection was associated with saprozoic exposure with traumatic implantation from an environmental source. The first observed substantial increase in cases was from 1 in 2015 (0.3 cases/100,000 OPVY) to 12 in 2016 (3.5 cases/100,000 OPVY) (Figure 5), and incidence rates continued to increase thereafter. There were 34 cases (8.3 cases/100,000 OPVY) in 2018, almost 3 times as many as in 2016, and 61 cases (21.4 cases/100,000 OPVY) in 2021 (Figure 5). During January–May 2022, we identified 20 cases from 142,873 outpatient visits (14 cases/100,000 OPVY) (Figure 5).

CTS cases were reported in 15 of the 399 municipalities in the state of Paraná (Figure 6, panels A, B) and in 11 of the 29 municipalities comprising the metropolitan region of Curitiba (Figure 6, panel C). Among the 216 CTS cases identified in the state of Paraná, the metropolitan region of Curitiba accounted for 205 (95%), the city of Curitiba alone for 170 (79%) (Figure 6, panel D). We also tracked triennial distribution of cases in the city of Curitiba during 2011–2013, 2014–2016, 2017–2019, and 2020–May 2022. The first case of CTS in Paraná was identified in 2011 in Campina Grande do Sul, a municipality located in the metropolitan region of Curitiba. The first case of CTS in the city of Curitiba was identified in 2012 in the Mercês neighborhood, located in the north-central part of the city (Figure 6, panel E). Since 2016, cases have spread across the city of Curitiba and been reported in 41 of 75 districts; most cases have been identified in the northwest region of the city, but during 2020–May 2022, incidence spread throughout the city (Figure 6, panels F, G, H). We also observed clusters of CTS cases involving members of the same household. Since 2011, a total of 10 clusters involving 21 cases were identified; 7/10 CTS clusters (15 cases) occurred after the COVID-19 pandemic began in 2020.

Kernel density maps identified hotspots for sporotrichosis in the city of Curitiba (Figure 7). The most critical hotspots were identified in the western part, mainly the Cidade Industrial de Curitiba (CIC) neighborhood, and north-central (city center) areas of Curitiba. CIC has an area of 44,588 km² and a population of 172,909 inhabitants (density 3.9 habitants/km²); it is largely residential, and most residents live in houses. CIC is economically characterized as a lower middle–income area, with an average daily income of USD $4.7 (27). The second hotspot, in downtown Curitiba, is a combination of commercial and residential areas, composed mostly of apartment buildings. Curitiba city center comprises 3,310 km² and is the most densely populated (37,234 inhabitants; density 11.2 inhabitants/km²) part of the city. Average daily income among residents is USD $20 (27). The kernel density maps of Curitiba show additional medium-density hotspots for CTS throughout other parts of the city, especially in the south, southeast, and northeast parts.

During the 10-year study period, sporotrichosis incidence increased substantially, suggesting uncontrolled spread in the city of Curitiba. Brazil is facing the largest reported current zoonotic outbreak of CTS globally (9,11,13,28). CTS is a public health issue exacerbated by insufficient public health activities, such as case surveillance, animal control, and diagnostic capacity, and by lack of disease awareness among health professionals and the general population (9,13,25,29). Our study adds relevant epidemiologic information to promote better understanding of CTS in the state of Paraná, Brazil.

We found a higher prevalence of CTS among female patients, especially in adult women involved in domestic activities. This finding is similar to those of other previous reports and is likely related to close contact with infected domestic cats (30–33). In this study, we observed an increased proportion of pediatric CTS cases; 29 cases (13%) occurred in patients <18 years of age, likely reflecting the close nature of interactions between children and domestic pets, especially cats (23). In addition, we found that >10% of cases occurred in persons working in professional animal care disciplines (2,11,22), who are at increased risk for CTS because of close contact with and exposure to contaminated body fluids from infected animals. Those professionals would benefit from increased awareness that infection in humans can occur through direct contact with body fluids from cats contaminated with S. brasiliensis yeast (26).

Lymphocutaneous and fixed cutaneous forms were the most frequently identified clinical manifestations of sporotrichosis, consistent with findings in previous literature (1,22). However, since the sporotrichosis epidemic in Brazil began, reports of unusual clinical manifestations have been increasing (1,6,34). It should be highlighted that cutaneous disseminated sporotrichosis is a rare manifestation that mostly occurs in immunocompromised persons; it differs from cutaneous manifestations caused by multiple traumatic implantations, as also happens in CTS cases (35–37). We also found a relatively high frequency of ocular sporotrichosis, which occurred in 10% of cases. Ocular sporotrichosis occurs mainly because of direct contact of the ocular mucosa of a person with secretions from an infected cat, usually because of cutaneous exudates or respiratory droplets expelled during cat sneezing (5,12,26). Ocular sporotrichosis is characterized by acute or chronic conjunctivitis, including Parinaud ocular syndrome and dacryocystitis (2,12,38–41). We also observed that unusual clinical manifestations of CTS increased from 2018 onward, coinciding with the epidemic increase in the number of cases of the disease. On the basis of those findings, the current guidelines in Brazil recommend use of personal protective equipment, including glasses or a face shield, during contact with sick cats (24).

Proven cases of CTS in this study made up slightly more than one third (39%) of all cases, compared with 65.3% in other case-series studies of sporotrichosis (22,23). This difference may have resulted from using a case definition not based solely on culture and microscopy results, which are suboptimal assays for detecting sporotrichosis in humans. Cultures from pus or secretion from lesions could be a feasible alternative; that type of test shows good performance and generates results in half the time compared with testing specimens obtained by biopsy. In addition, that type of sample is noninvasive, simple, and inexpensive. HC/UFPR has a medical institute with extensive experience in the diagnosis of sporotrichosis, and its medical professionals consequently have a high index of suspicion for this disease, increasing the chances of early detection of cases in which culture and microscopy are generally negative. On the basis of this experience, we highlight the importance of the probable case classification, because recognizing probable CTS enables rapid initiation of treatment, resulting in a positive effect on the quality of life of patient with sporotrichosis (23,25).

Molecular typing identified a single species, S. brasiliensis, in all proven cases in our study. The isolates were related to the species that caused the CTS outbreak in the state of Rio de Janeiro in the early 2000s and is primarily causing outbreaks throughout Brazil (5,11,13,17,42–44). Those isolates were identified by phylogenetic analysis of the near-complete calmodulin gene sequencing, showing a high degree of similarity with previously sequenced isolates from Rio de Janeiro. Additional analyses, such as microsatellite typing, multilocus sequence typing, and amplified fragment-length polymorphic fingerprinting, can improve understanding of the expansion of cases in Paraná and the city of Curitiba (13,45). Moreover, analysis of whole-genome sequencing results is a tool relevant for elucidating central concerns about the differences in infectious potential between closely related species. Comparative genomic analysis of data on tissue invasion and transmission of pathogenic sibling species has been applied to highlight genes involved in fungal adaptation to an animal-associated lifestyle (11,46,47).

We observed an exponential increase in the incidence rate of sporotrichosis, from 0.3 OPVY in 2011 to 21.4 OPVY in 2021, a trend similar to that for data reported recently in a review of the burden of sporotrichosis in Brazil (9,15,22,29,30,48). In Brazil, the largest number of CTS cases is concentrated in the southwest and south of Brazil, including the states of Rio de Janeiro, Rio Grande do Sul, São Paulo, Espírito Santo, and Minas Gerais. However, cases of CTS have also been described in the Midwest, Federal District, and Northeast regions and in Pernambuco and Rio Grande do Norte states, clearly showing the spread of the disease throughout Brazil (22,32,49).

Most cases in this study occurred in the city of Curitiba. The first case identified at HC/UFPR was in the center-north part of the city in 2012, but the first substantial increase in the number of cases, a trend that continued, was observed in 2016. After the World Health Organization declared COVID-19 a pandemic in March 2020 and lockdowns started, we observed a 37% increase in cases and also an increase in CTS clusters. The increase may have been related to higher rates of pet adoption aimed at reducing anxiety and depression because of the lockdowns (23). We identified 2 areas of the city of Curitiba as CTS hotspots, one area characterized by high population density and the other by social inequalities. In addition, the kernel density estimate showed low or medium CTS expanded practically throughout the city, especially during 2020–2022; areas of medium density were located in the south, southeast, and northeast parts of the city.

The main limitation of our study was that data came from a single center; however, the data covered a decade of experience, and our findings add information based on actual case numbers rather than estimates. Since March 7, 2022, the State Department of Health of Paraná, has provided guidelines (resolution no. 093/2022) for mandatory notification of human and animal sporotrichosis cases in the state.

Because of the zoonotic transmission of this disease, a One Health approach is necessary to control the public health effects of CTS. Integrating human, animal, and environmental health approaches through coordinated actions among microbiologists, veterinarians, physicians, epidemiologists, and surveillance authorities could benefit control efforts. Potential actions include owners restricting cats from going outside homes and having contact with street cats, providing no-cost neutering of cats in regions where S. brasiliensis is endemic to prevent expansion of feral cat populations, widely establishing compulsory notification of CTS cases, increasing awareness of the disease among clinicians and the public, providing easy access to treatment in human and animal cases, and cremating cat remains (12,36,50). Additional interventions to control CTS outbreaks could include providing access to rapid, accurate diagnostic assays and antifungal drugs, developing vaccines specifically for cats, and evaluating novel treatment strategies, particularly for treating feline sporotrichosis. Enacting those and other prevention and control measures in a timely manner is urgently needed to repress the increased incidence and spread of this serious health condition.