Translational actions and opportunities identified in the workshop

All thematic discussions generated a range of potential actions and solutions to address FGS at a global, national, regional and community level. Under each theme, the following is presented and summarized in Table 2:

1. (1) The problem to be solved: these were highlighted during the discussions.

   Table 2. Summary of translational actions from across the themes discussed

   

2. (2) The endpoint objective being worked towards: these were identified after the discussions.

3. (3) The translational actions and recommendations and context surrounding them that could help to deliver these endpoint objectives.

4. (4) Key points from the workshop discussion that provide context to support these actions.

It is hoped that these translational actions will be taken up and implemented by communities and collaborators, ensuring the delivery of projects that allow the integration of FGS healthcare into existing services (see examples in Table 1). With limited funding, this implementation may be challenging, but if supported by governments in affected countries, private healthcare systems and non-governmental organizations (NGOs), then the delivery of specific shared endpoint objectives remains achievable.

Problem

The signs and symptoms of FGS are similar to those associated with STIs, making diagnosis challenging for both community health workers, those within primary care and women living with FGS. Moreover, as FGS awareness at the clinical and community level is poor, the index of suspicion for FGS among healthcare professionals is low, and the disease is often incorrectly diagnosed. STI-like symptoms are associated with stigma and discrimination, and women living with FGS may experience delays in seeking and accessing care. Health systems are not primed to provide FGS-related care, limiting community-health worker efforts to access a functional FGS care cascade. This is exacerbated by limited information at the community level on the burden of FGS. Further, outside MDA programmes, which primarily focus on school-aged children, access to PZQ in the health system remains inadequate. The economic impact of FGS is also not quantified, hindering the adequate allocation of direct healthcare resources towards effectively preventing, diagnosing and treating the disease at the earliest opportunity.

Endpoint objective

There is greater awareness of FGS in endemic areas across all levels of clinical practice and throughout affected communities. Women can access FGS-related healthcare, including diagnosis, personalized information and treatment, through established health programmes that prioritize affordable and cost-effective prevention and control strategies.

Translational actions

1. (1) Engage with the Ministries of Health and Education, and those providing care for women and girls with FGS in affected countries, to agree on a strategic approach to:

   1. (a) Create standardized school and clinical curricula to improve FGS awareness among affected communities and within the medical profession for its prevention, diagnosis and treatment.

There have been multiple small-scale projects focusing on FGS training for healthcare workers (Table 1). Despite these efforts, awareness of FGS remains low, and it remains necessary to engage further with Ministries of Health and Education in affected countries. Existing training curricula, which may include SRHR, STI and HIV policies and guidelines, need to be adapted to incorporate content on FGS for the education of medical students so that health workers conducting visual exams can differentiate between STIs, cervical (pre-)cancer and FGS. The training curricula should also address FGS management, allowing health workers in endemic areas to recognize disease symptoms so that women and girls can be diagnosed, referred and treated. This would also serve to break down misconceptions and myths surrounding FGS, such as the belief that it is an STI (Wambui et al., Reference Wambui, Madinga, Ashepet, Anyolitho, Mitashi and Huyse2024).

1. (b) In collaboration with local communities in endemic areas, create public health messaging on FGS and disseminate it through multiple platforms to improve awareness across multiple ages and groups.

Awareness-building activities should include highly targeted messaging to key community subgroups, recognizing that schoolgirls, women of reproductive age and older women may engage in different activities. These activities may be facilitated by community health workers, for example, as piloted in Liberia and Nigeria through the Calling Time for Neglected Tropical Diseases (COUNTDOWN) research programme (Table 1). Here, case management intervention tools that included operational manuals and a signs and symptoms FGS scorecard were codeveloped and assessed at the primary health care level (Nganda et al., Reference Nganda, Bettee, Kollie, Nallo, Juabeh, Wright, Thomson and Dean2023). Similarly, workshop participants reported that drama groups in Malawi, Tanzania and Zambia have been employed to engage communities through culturally appropriate dissemination events. Other methods include the use of different social media tools that may be utilized to educate and inform the public with verified and accurate information on FGS. It is necessary to ensure that men are included to address the discrimination and stigma associated with FGS, as well as to inform them that they may also be affected by male genital schistosomiasis (Bustinduy et al., Reference Bustinduy, Randriansolo, Sturt, Kayuni, Leustcher, Webster, Van Lieshout, Stothard, Feldmeier and Gyapong2022). For example, a pilot study in Tanzania has involved men in promoting care for FGS after surveys identified the important role of men in ensuring women with FGS seek medical advice (Lambert et al., Reference Lambert, Samson, Matungwa, Kosia, Ndubani, Hussein, Kalua, Bustinduy, Webster, Bond and Mazigo2024). Lessons can also be learned from the HIV field, where communities led health literacy efforts and emphasized the importance of pre-exposure prophylaxis (Young and Valiotis, Reference Young and Valiotis2020).

1. (2) Develop reporting processes to collect routine FGS diagnostic data that may be used to estimate disease burden and prevalence, allowing sufficient and proportional PZQ allocation and distribution.

There are currently no standardized methods for population-based FGS screening and diagnosis. The MAP-FGS project is aiming to address this by generating data on FGS prevalence across 6 countries, particularly among girls and women aged 10–60 years (Table 1). The collection and centralized reporting of routine diagnostic data would help improve understanding of FGS morbidity and prevalence. This would, in turn, allow improved PZQ allocation and distribution to primary healthcare facilities and potentially help estimate the FGS burden using DALYs. Furthermore, the knowledge gained from MAP-FGS may inform further data collection processes and research studies that will help support integrating FGS care into broader SRHR services.

1. (3) Pilot the integration of FGS screening and management into CC and SRHR services. Create cost and cost–effectiveness analysis data packages to aid with the scalability of FGS screening programmes.

As mentioned, the Zipime-Weka-Schista study (Shanaube et al., Reference Shanaube, Ndubani, Kelly, Webb, Mayaud, Lamberti, Fitzpatrick, Kasese, Sturt, Van Lieshout, Van Dam, Corstjens, Kosloff, Bond, Hayes, Terris-Prestholt, Webster, Vwalika, Hansingo, Ayles and Bustinduy2024) has pioneered the integration of multi-pathogen screening in Zambia and includes an economic analysis providing data on the cost-effectiveness of home-based compared with clinic-based procedures (Table 1). However, to be generalizable to routine care in all endemic areas, other countries should contribute similar data, captured via standardized reporting tools to ensure information can be reported for all diseases on a single platform. To inform health policy, cost–effectiveness and economic analyses to compare the costs and benefits of FGS control strategies are essential when allocating resources. This would allow the estimation of the affordability of different control strategies to support priority setting in resource-scarce environments. Given that integration of FGS into existing health services would require further management and resources, it must be determined if the health services are ready to accommodate integration. To facilitate this work and to develop pilot studies, it will be beneficial to develop a framework and health decision analytical model to evaluate the cost-effectiveness of FGS screening strategies (Lamberti et al., Reference Lamberti, Terris-Prestholt, Bustinduy and Bozzani2024b). Data packages drawn from pilot projects to integrate FGS with CC and SRHR services may capture data from different integration models, including costs to patients such as travel costs and direct medical expenses. These data may further help estimate the FGS burden using DALYs.

Problem

There is no specific treatment for FGS. Currently, in schistosomiasis-endemic areas, PZQ is distributed to allow the preventive treatment of school-aged children and high-risk groups with PZQ through MDA programmes (World Health Organization, 2022). Outside of these programmes, women and girls with suspected FGS may be treated with a single dose of PZQ (World Health, 2015). However, PZQ targets and kills the adult S. haematobium worms, but there is limited evidence assessing its effectiveness in resolving characteristic cervicovaginal lesions or reducing FGS-associated morbidity (Kjetland et al., Reference Kjetland, Ndhlovu, Gomo, Mduluza, Midzi, Gwanzura, Mason, Sandvik, Friis and Gundersen2006b; Downs et al., Reference Downs, Kabangila, Verweij, Jaka, Peck, Kalluvya, Changalucha, Johnson, Van Lieshout and Fitzgerald2013; Bustinduy et al., Reference Bustinduy, Randriansolo, Sturt, Kayuni, Leustcher, Webster, Van Lieshout, Stothard, Feldmeier and Gyapong2022; Arenholt et al., Reference Arenholt, Randrianasolo, Rabozakandraina, Ramarokoto, Jøker, Aarøe, Brønnum, Bundgaard Nielsen, Sørensen, Lumholdt, Jensen, Lundbye-christensen, Jensen, Corstjens, Hoekstra, Van Dam, Kobayashi, Hamano and Leutscher2024; Kabengele et al., Reference Kabengele, Mwangelwa, Kilembe, Vwalika, Inambao, Moonga, Himukumbwa, Secor, Parker, Tichacek, Bustinduy, Allen and Wall2024). Additionally, as PZQ demonstrates a lack of activity against juvenile worms, such as the schistosomulum stage, and there are few alternative treatments, there is an urgent need to identify novel evidence-based treatments for FGS that can effectively kill the parasite in all life stages or reduce FGS-associated morbidity. However, the development of new treatments is hindered by a lack of commercial return of investment, objective efficacy endpoints, animal model data and identification of sensitive and specific FGS biomarkers to monitor treatment efficacy. Furthermore, PZQ does not prevent reinfection if there is at-risk water contact following administration of treatment.

Endpoint objective

Clinical recommendations for the use of FGS treatments are available based on standardized data sets with specific therapeutic endpoints. Targets for alternative parasite-directed and/or host-directed treatments for FGS have been identified and assessed.

Translational actions

1. (1) Create a working group to standardize FGS case definition(s) (molecular, visual and symptomatic), clinically relevant endpoints and outcome measures.

It is necessary to standardize FGS case definitions, focusing on whether FGS is defined by specific FGS pathology (e.g. cervicovaginal lesions), the detection of Schistosoma DNA or eggs in the genital tract and/or the occurrence of clinical symptoms. Circulating anodic antigen (CAA), urine microscopy and urine Schistosoma polymerase chain reaction (PCR) are tools used to diagnose active Schistosoma infection, but they do not evaluate FGS status. Thus, resolution of urinary S. haematobium infection, confirmed by negative urine microscopy, the absence of CAA or Schistosoma DNA in the urine and/or stool, should not be the clinical endpoint for FGS treatment. Instead, negative genital Schistosoma PCR, resolution of FGS cervicovaginal lesions and/or sustained reduction of symptoms would be prioritized as endpoints. This is especially important if lesions cause morbidity (e.g. abnormal bleeding and pain) or render a patient vulnerable either to HIV or HPV. Different stages and clinical manifestations of FGS which may require different treatment and confounders such as STIs should be considered to ensure lesions are not caused or aggravated by a coinfection.

1. (2) Create data packages from existing MDA programmes to assess their impact on population-level FGS prevalence and pathology, along with correlations to additional medical treatments.

Published research has emphasized the need for sustained treatment with PZQ from early life through to adolescence to prevent FGS lesions from establishing (Arenholt et al., Reference Arenholt, Randrianasolo, Rabozakandraina, Ramarokoto, Jøker, Aarøe, Brønnum, Bundgaard Nielsen, Sørensen, Lumholdt, Jensen, Lundbye-christensen, Jensen, Corstjens, Hoekstra, Van Dam, Kobayashi, Hamano and Leutscher2024). For example, a prospective study in Zimbabwe found that women who had undergone PZQ treatment in their childhood years had 50% less contact bleeding and lesion sizes compared to those who had never received treatment (Kjetland et al., Reference Kjetland, Ndhlovu, Kurewa, Midzi, Gomo, Mduluza, Friis and Gundersen2008). In Kenya, girls and women who had received PZQ through MDA before the age of 21 were less likely to develop sub-fertility in later years (Miller-Fellows et al., Reference Miller-Fellows, Howard, Kramer, Hildebrand, Furin, Mutuku, Mukoko, Ivy and King2017).

PZQ MDA to school-aged children has been in place in most countries since 2001, meaning that many women who are now in their mid-20s and 30s have received preventative chemotherapy (Rossi et al., Reference Rossi, Previtali, Salvi, Gerami, Tomasoni and Quiros-Roldan2024). As such, there may be a wealth of data available from patient records in endemic areas that may be reviewed to better understand FGS prevalence and associated symptoms. Additionally, this may allow researchers to identify correlations and ascertain key information relating to the use of other medications for co-morbidities (e.g. antibiotic therapy). Developing this understanding may help improve the treatment of FGS lesions using existing medications.

1. (3) Conduct a sufficiently powered, longitudinal study to assess the effectiveness of PZQ treatment regimens on FGS, including the assessment of novel targets for therapeutic development.

Some studies have highlighted that PZQ can lead to a marginal improvement for women who have FGS, with treatment decreasing lesion severity. Women who presented with less severe baseline disease were associated with FGS lesion resolution post-treatment (Kabengele et al., Reference Kabengele, Mwangelwa, Kilembe, Vwalika, Inambao, Moonga, Himukumbwa, Secor, Parker, Tichacek, Bustinduy, Allen and Wall2024). A randomized controlled trial aiming to assess the efficacy and safety of a repeated PZQ-dosing regimen was recently conducted, comparing single-dose treatment of PZQ to 5 doses over 10 weeks. This study found an insignificant reduction in abnormal blood vessels only following treatment with PZQ, although treatments did result in reductions in worm populations, pelvic exam abnormalities and urogenital complaints. The repeated regimen seemed more effective at eliminating the dwelling worm population than the single-dose regimen (Arenholt et al., Reference Arenholt, Randrianasolo, Rabozakandraina, Ramarokoto, Jøker, Aarøe, Brønnum, Bundgaard Nielsen, Sørensen, Lumholdt, Jensen, Lundbye-christensen, Jensen, Corstjens, Hoekstra, Van Dam, Kobayashi, Hamano and Leutscher2024). Some important limitations of the trial included a very small number of adequate images reviewed and a lack of age stratification of results, potentially overlooking the differences in the natural history of FGS through time. The lack of adjustment on age-related morbidity differences limits its generalizability to all girls and women with FGS across settings.

Research has shown that inflammation occurs around eggs situated in the genital mucosa where fibrotic or chronic inflammatory lesions form, and treatments must be able to target this later stage of disease (Jourdan et al., Reference Jourdan, Roald, Poggensee, Gundersen and Kjetland2011; Randrianasolo et al., Reference Randrianasolo, Jourdan, Ravoniarimbinina, Ramarokoto, Rakotomanana, Ravaoalimalala, Gundersen, Feldmeier, Vennervald, Van Lieshout, Roald, Leutscher and Kjetland2015). Further studies should be undertaken to determine the effectiveness of using PZQ for FGS treatment, considering age, confounding variables and the assessment of alternative treatments that may resolve chronic cervical lesions with established abnormal blood vessels. Longitudinal studies may include genomics/transcriptomics analysis of women with molecular and visual FGS, before and after treatment, to identify novel therapeutic targets at different time points/stages.

1. (4) Conduct drug repurposing studies to assess the efficacy of existing drugs for FGS.

Repurposing of existing approved drugs may offer a safe, rapid and cost-effective alternative to early-stage drug discovery. Potential candidates for drug repurposing include non-steroidal anti-inflammatories, corticosteroids and anti-fibrotics. Used in combination with PZQ, these drugs may help alleviate FGS symptoms. Additionally, treatment with a combination of the anti-malarial drugs artesunate and mefloquine was as effective against urinary S. haematobium infection as PZQ (Bottieau et al., Reference Bottieau, Mbow, Brosius, Roucher, Gueye, Mbodj, Faye, DE Hondt, Smekens, Arango, Burm, Tsoumanis, Paredis, Van Herrewege, Potters, Richter, Rosanas-urgell, Cissé, Mboup and Polman2024). However, while repurposing drug studies may be advantageous, careful consideration must be given to any medication that may interact with PZQ’s pharmacokinetic and pharmacodynamic performance (e.g. corticosteroids or tuberculostatics) (Ridtitid et al., Reference Ridtitid, Wongnawa, Mahatthanatrakul, Punyo and Sunbhanich2002; Jauréguiberry et al., Reference Jauréguiberry, PARIS and Caumes2010).

Problem

Conventional FGS diagnosis involves visual inspection of the cervicovaginal mucosa, typically with the aid of a colposcope, to visually detect lower genital tract lesions suggestive of FGS (Søfteland et al., Reference Søfteland, Sebitloane, Taylor, Roald, Holmen, Galappaththi-arachchige, Gundersen and Kjetland2021; Bustinduy et al., Reference Bustinduy, Randriansolo, Sturt, Kayuni, Leustcher, Webster, Van Lieshout, Stothard, Feldmeier and Gyapong2022). While biopsy of these lesions to detect parasite eggs is considered the gold standard for FGS diagnosis, it is not widely used as the approach is invasive, and there are theoretical concerns regarding HIV transmission among sexually active women (Poggensee et al., Reference Poggensee, Sahebali, Van Marck, Swai, Krantz and Feldmeier2001; Wright et al., Reference Wright, Subbarao, Ellerbrock, Lennox, Evans-Strickfaden, Smith and Hart2001; Kjetland et al., Reference Kjetland, Hove, Gomo, Midzi, Gwanzura, Mason, Friis, Verweij, Gundersen, Ndhlovu, Mduluza and Van Lieshout2009).

To facilitate clinical diagnosis of FGS, the WHO developed a visual pocket atlas for providers performing colposcopy (World Health Organisation, 2015). There are 4 classic lesions associated with FGS that correspond to Schistosoma egg deposition in the mucosa. These identified lesions (homogeneous yellow sandy patches, grainy sandy patches, abnormal vessels and rubbery papules) can be accompanied by surface bleeding and/or other signs of inflammation or scarring. Lesions may be large or small on all cervicovaginal surfaces, including vaginal walls, but are most often discovered on the cervix due to current clinical training, CC screening programmes and colposcope design (Søfteland et al., Reference Søfteland, Sebitloane, Taylor, Roald, Holmen, Galappaththi-arachchige, Gundersen and Kjetland2021). Most FGS studies have naturally been conducted in endemic areas. Therefore, S. haematobium ova may have been deposited continuously from childhood until the investigation date, presenting a range of recently established lesions and chronic manifestations. Furthermore, depending on the localization of the egg deposition, lesions may not be visible if eggs are deposited in the upper genital tract (Bustinduy et al., Reference Bustinduy, Randriansolo, Sturt, Kayuni, Leustcher, Webster, Van Lieshout, Stothard, Feldmeier and Gyapong2022).

It is important to note that there is no standardized training method to correctly identify FGS-associated cervicovaginal lesions. This is compounded by the expense and limited availability of colposcopes (standard and handheld), which means that visual FGS diagnosis tends to be limited to research settings (Søfteland et al., Reference Søfteland, Sebitloane, Taylor, Roald, Holmen, Galappaththi-arachchige, Gundersen and Kjetland2021). Where colposcopy is used, there is evidence of high inter-user variability, and there may be issues with sensitivity where eggs embedded in inaccessible parts of the genital mucosa are missed (Sturt et al., Reference Sturt, Bristowe, Webb, Hansingo, Phiri, Mudenda, Mapani, Mweene, Levecke, Cools, Van Dam, Corstjens, Ayles, Hayes, Francis, Van Lieshout, Vwalika, Kjetland and Bustinduy2023). In addition, there are confounding gynaecological diseases with similar visual presentations to FGS, and heterogeneity within a healthy cervix, limiting the accuracy of visual readings in correctly identifying each condition.

Alternative laboratory diagnostic approaches suitable for use in low-resource settings should be considered to aid the clinical diagnosis of FGS and determine the severity of infection. Diagnostics for detecting S. haematobium eggs/antigens in urine/serum as a measure of active infection can act as a proxy marker for FGS (e.g. CAA; Corstjens et al., Reference Corstjens, De Dood, Kornelis, Fat, Wilson, Kariuki, Nyakundi, Loverde, Abrams, Tanke, Van Lieshout, Deelder and VAN Dam2014) or DNA in urine and/or stool by PCR (Pillay et al., Reference Pillay, Downs, Changalucha, Brienen, Ramarokoto, Leutscher, Vennervald, Taylor, Kjetland and Van Lieshout2020). However, approximately 40% of females with genital schistosomiasis do not have eggs detected in urine (Poggensee et al., Reference Poggensee, Sahebali, Van Marck, Swai, Krantz and Feldmeier2001; Kjetland et al., Reference Kjetland, Ndhlovu, Mduluza, Gomo, Gwanzura, Mason, Kurewa, Midzi, Friis and Gundersen2005; Hegertun et al., Reference Hegertun, Sulheim Gundersen, Kleppa, Zulu, Gundersen, Taylor, Kvalsvig and Kjetland2013). In addition, these methods suffer from an inability to detect dead parasite eggs embedded within genital tissue so women may be found to have FGS lesions based on a visual examination, but test negative using urine microscopy (or other molecular tests). An affordable point-of-care (POC) molecular test demonstrating high sensitivity and specificity, or a diagnostic method that can specifically detect visual FGS, has yet to be developed.

No single diagnostic tool will provide an accurate and scalable solution to allow the identification of FGS. Instead, a combination of visual and laboratory tools, together with algorithms to support healthcare professionals’ decision-making, will be necessary for the specific diagnosis of FGS across all endemic regions. A WHO target product profile for FGS diagnostics is being developed but has yet to be finalized.

Endpoint objective

Alternative or improved diagnostic tools for FGS have been developed and properly validated.

Translational actions