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Elimination of schistosomiasis in China: Current status and future prospects

  • Wei Wang,

    Affiliation Key Laboratory of National Health Commission of Parasitic Disease Prevention and Control, Jiangsu Provincial Key Laboratory of Parasites and Vector Control Technology, Jiangsu Institute of Parasitic Diseases, Wuxi, Jiangsu Province, China

  • Robert Bergquist,

    Affiliation Ingerod, Brastad, Sweden (formerly with the UNICEF/UNDP/World Bank/WHO Special Programme for Research and Training in Tropical Diseases), World Health Organization, Geneva, Switzerland

  • Charles H. King,

    Affiliation Center for Global Health and Diseases, Case Western Reserve University, Cleveland, Ohio, United States of America

  • Kun Yang

    yangkun@jipd.com

    Affiliations Key Laboratory of National Health Commission of Parasitic Disease Prevention and Control, Jiangsu Provincial Key Laboratory of Parasites and Vector Control Technology, Jiangsu Institute of Parasitic Diseases, Wuxi, Jiangsu Province, China, Center for Global Health, Nanjing Medical University, Nanjing, Jiangsu Province, China

Abstract

Elimination of schistosomiasis as a public health problem among all disease-endemic countries in 2030 is an ambitious goal. Recent achievements resulting from mass drug administration (MDA) with praziquantel is promising but may need to be complemented with also other means. Schistosomiasis was highly prevalent in China before the initiation of the national schistosomiasis control program in the mid-1950s, and, at that time, the country bore the world’s highest burden of schistosomiasis. The concerted control efforts, upheld without interruption for more than a half century, have resulted in elimination of the disease as a public health problem in China as of 2015. Here, we describe the current status of schistosomiasis in China, analyze the potential challenges affecting schistosomiasis elimination, and propose the future research needs and priorities for the country, aiming to provide more universal insights into the structures needed for a global schistosomiasis elimination encompassing also other endemic regions.

Introduction

Schistosomiasis, caused by blood flukes of the genus Schistosoma that depend on snail intermediate hosts for their life cycle, is a neglected tropical parasitic disease of great public health and socioeconomic significance [1]. This zoonotic parasitic disease is estimated to affect around 240 million people in 78 tropical and subtropical countries across the world, with up to 780 million at risk [2]. For more than 30 years, the World Health Organization (WHO) has recommended a morbidity control strategy through mass drug administration (MDA) with the drug praziquantel [3]. This approach has resulted in strong progress toward schistosomiasis elimination, as evidenced by a remarkable decline in prevalence and intensity of the disease [4,5]. This success provides hope that the agenda set for elimination of schistosomiasis in “this wormy world” has been correct [6]. However, the ambitious goal of eliminating the infection as a public health problem in all endemic countries in 2030 remains challenging [7], notably in African countries where more than 90% of global schistosomiasis patients live and where over 85% of local populations are constantly at risk [8,9]. This is partly because the current strategy for schistosomiasis control, despite the success mentioned above, fails to prevent reinfection. In addition, there are still inadequate supplies of praziquantel pills, which are primarily supplied through donations from international pharmaceutical companies [1012].

The schistosome species in China is Schistosoma japonicum, and its snail host is Oncomelania hupensis, and the description of the disease caused by schistosomiasis dates back more than 2,200 years [13]. Significant Schistosoma-associated morbidity was highly prevalent before the initiation of the national schistosomiasis control program in the mid-1950s. Indeed, China had the highest burden of schistosomiasis in the world and at that time [14,15]. Since then, the strong political will [16], an effective and flexible control strategy at different program stages, and the rigorous surveillance and monitoring of factors associated with the transmission of schistosomiasis have resulted in elimination of the disease as a public health problem in China as of 2015 (Table 1) [17].

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Table 1. Criteria for the elimination of schistosomiasis.

https://doi.org/10.1371/journal.pntd.0009578.t001

As can be seen in Table 1, the Chinese criteria regarding schistosomiasis elimination are even more stringent than those recommended by WHO [18]. The country remains currently at the “pre-elimination” stage [19], and we are aware that there are still challenges that may hinder the progress toward final disease elimination [20,21]. Here, we describe the current status of schistosomiasis in China, analyze the potential challenges affecting elimination, and propose the future research needs and priorities for the country. This discussion is also intended to provide more universal insights into the structures needed for a global schistosomiasis elimination program encompassing all endemic regions of the world.

Elimination of schistosomiasis in China: Current status

Following China’s concerted effort to control and eliminate schistosomiasis that has been ongoing for nearly 70 years [1], the endemic status is currently characterized by an extremely low prevalence and intensity of S. japonicum infections [22]. In 2019, only 30,000 individuals were estimated to have the disease across the country, with only 5 new infections detected that year [23]. This indicates a more than 99% reduction in the number of cases as compared to the situation in the 1950s (Fig 1) [2327]. In addition, in 2019, the transmission of schistosomiasis had been controlled, or interrupted in approximately 95% of the 450 counties that were once considered endemic for S. japonicum, including 67 that have now achieved elimination (Figs 2 and 3). These data demonstrate that we are steadily approaching to final demise of the “God of Plague” [17]. It has been well known that experiences from the great success in schistosomiasis control in China include high-level political sustained commitment [28], persistent and adequate financial support [29], and integrated control mobilizing multi-sectoral resources [30,31]. Nevertheless, the following approaches have also contributed to this success: (1) government-led containment: In China, the national schistosomiasis control program is included in the annual governmental work plan at national, provincial, municipal, county, and township levels, and all schistosomiasis control approaches are implemented under governmental leadership, ensuring the smooth implementation of all activities [16]; (2) nationwide participation: All residents living in schistosomiasis-endemic foci are encouraged to participate in the schistosomiasis control program [30]; (3) a unique control strategy: Although there have been 3 major shifts in the national schistosomiasis control strategy, a unique strategy is employed across the whole country [28]; and (4) a powerful surveillance-response system: The strong monitoring capability and rapid response mechanism allows effective management of schistosomiasis epidemics, making eradication of the transmission risk possible [28].

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Fig 1. Changes in the estimated number of schistosomiasis cases in China from 1950s to 2019.

https://doi.org/10.1371/journal.pntd.0009578.g001

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Fig 2.

The changing proportions of infection control categories among schistosomiasis-endemic counties in different periods of schistosomiasis control in China from 1999 to 2019: (A) 1999, (B) 2009, and (C) 2019.

https://doi.org/10.1371/journal.pntd.0009578.g002

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Fig 3. Overall progress of schistosomiasis elimination in the country.

https://doi.org/10.1371/journal.pntd.0009578.g003

Challenges

Although China is moving steadily toward complete elimination of schistosomiasis across the country, many challenges remain in order to eliminate this disease by 2030 (Table 2) [32]. Among them is financial support, the most urgent issue that must always be addressed. Indeed, one of the important lessons learned from the World Bank Loan Project (WBLP) for Chinese Schistosomiasis Control Program (1992 to 2001) is that sustained financial support is needed for effective program performance. The absence of adequate support after the end of the WBLP resulted in rebound of schistosomiasis transmission [29]. Since all interventions included in the national schistosomiasis elimination program are fully paid by the government and that reduced funding would fail to support the integrated control interventions and capability improvements agreed, it is essential that strong political support continues along with provision of commensurate financial support to maintain China’s elimination initiative.

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Table 2. Potential challenges for elimination of schistosomiasis in China.

https://doi.org/10.1371/journal.pntd.0009578.t002

Snail control has proven to be one of the most effective tools for interruption of schistosomiasis [3335], particularly with regard to S. japonicum, as its snail host is amphibious, and, therefore, more vulnerable than its African counterparts. This approach has been an important part of the Chinese national schistosomiasis control strategy since the 1950s (Fig 4) [36]. Although no S. japonicum infections have been identified in O. hupensis snails since 2014 [37], 1.74 billion m2 snail habitats were detected across China in 2019, including 642,000 m2 emerging snail-infested settings and 8.51 million m2 reemerging settings [23]. These widespread host snails are an important unknown factor during the stage when we move toward elimination of schistosomiasis.

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Fig 4. Changes in the area of O. hupensis snail habitats in China from 1950s to 2019.

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An unfortunate duality with respect to the need for snail control has arisen from the government’s call for environmental protection, which restricts the use of chemical treatment as part of snail control, while the development of China’s Yangtze River Economic Belt prohibits the use of environmental change, such as dams for snail control, along the Yangtze River basin—the main schistosomiasis-endemic focus of China. Meanwhile, the construction of large-scale wetlands has led to the introduction of O. hupensis snails into urban areas [38]. Agricultural developments, water conservancy, and deforestation programs have shown feasible for the improving snail-infested settings; however, these programs require costly investments [31,39]. To add fuel to the fire, the termination of financial support given to agriculture, water conservancy, and forestry sectors for schistosomiasis control programs since 2016 has resulted in ineffective multi-sectoral collaborations and cessation of environmental improvements for snail control. In addition, frequent floods along the Yangtze River basin [4042] and earthquakes in the mountainous schistosomiasis-endemic areas may now lead to the spread of O. hupensis snails and expansion of schistosomiasis transmission as a result [4345].

Unlike the other 2 main species of the genus Schistosoma infective to humans, S. japonicum is a zoonotic parasite with over 40 different mammalian species serving as reservoir hosts [46]. Although bovines are included in the Chinese National Schistosomiasis Control Program and given high priority for control interventions as a major source of infection [47], goats, dogs, and wild mice, which are also reservoirs for S. japonicum, are generally not targeted [48]. Previous studies have shown that these animals also play an increasingly important role in the transmission of schistosomiasis [20,49]. A recent meta-analysis showed 3.9% overall pooled prevalence of S. japonicum infections in 8,795 wild rodents based on 37 eligible publications, involving 61 field studies across mainland China from 1980 to 2020 [20]. No comparable overall change of the infection prevalence was detected in rodents with great reductions in the numbers of schistosomiasis cases in humans and bovines; however, importantly, there appeared to be an increase in S. japonicum prevalence in rodents over time within the hilly and mountainous endemic regions [20]. Since rodents were projected to become the dominant wildlife in human-driven environments and the main reservoir of zoonotic diseases in general within tropical zones, intensified monitoring and evaluation of potential S. japonicum infections within rodents is strongly recommended, particularly in hilly and mountainous regions [20]. A very recent, preprint publication also reports high prevalence of Schistosoma infections in rodents, highlighting the important role of rodents in schistosomiasis transmission across the world during the current stage of disease elimination [50]. Moreover, Elaphurus davidianus, a type of deer native to the river valleys of China, is a Grade 1 state-protected animal in China that can be seen grazing in marshlands around Poyang Lake and Dongting Lake areas, which are places where O. hupensis snails infected by S. japonicum have previously been found with high prevalence and intensity of infection [5153]. In 2004, a field investigation detected 29.2% (38/130) of the wild-captured E. davidianus fecal samples positive for S. japonicum in Gudao section of the Yangtze River in Shishou City, central China [53]. In 2016, 16% (4/25) of the wild E. davidianus fecal samples captured from the Tian’e marshland of Shishou City were identified as infected by S. japonicum [52]. A recent study shows a 4.4% (2/46) detection of S. japonicum eggs in stool samples of E. davidianus captured from the grassland of Poyang Lake with a high intensity of infection based on the miracidial hatching test (+++) found [51]. This abundance of these deer poses a high risk of them becoming an emerging reservoir of S. japonicum infections, in particular since it is prohibited to investigate this animal or provide any kind of chemotherapy if needed. What makes matters worse is that fencing is also not allowed, while free grazing in the grasslands is encouraged [54]. Thus, the presence of this type of deer in areas still endemic for schistosomiasis is a big threat with respect to consolidation of the achievements gained from current concerted control efforts, and it endangers the progress toward elimination of schistosomiasis in China.

Schistosomiasis elimination in China: Future requirements

The experience of many global schistosomiasis control programs has shown that MDA with praziquantel alone is unlikely to eliminate schistosomiasis [55], and an integrated strategy mobilizing resources from health, agriculture, water conservancy, forestry, and education sectors is required [56]. To tackle the challenges mentioned above, the complete eradication of potential risks for resurgence of the disease is of great and urgent need. During the stage of moving toward elimination of schistosomiasis, a more fine-grained precision control is recommended as the choice for managing interventions as part of the national schistosomiasis elimination program (Table 3) [57].

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Table 3. Future research priorities for the elimination of schistosomiasis in China.

https://doi.org/10.1371/journal.pntd.0009578.t003

Discussion and conclusions

Rapid social and economic development during the past decades has brought with it striking achievements in the Chinese National Schistosomiasis Control Program. Remarkably, in 2019, only 5 individuals tested positive for S. japonicum throughout the country [23]. Currently, the transmission of schistosomiasis is almost interrupted, and the country is steadily moving toward schistosomiasis elimination. In addition to the integrated strategy [58], Chinese experience and tools are now being transferred overseas and have been applied in countries affected by schistosomiasis in Africa and Southeast Asia [5962]. It is clear that the experience gained and lessons learned over the past 7 decades of schistosomiasis control in China can provide valuable insights useful for the ongoing global schistosomiasis elimination program, as outlined in the new WHO Roadmap for Neglected Tropical Diseases [7].

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