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Trachoma. Trachoma, the leading infectious cause of blindness worldwide, is one of several neglected tropical diseases targeted by WHO for elimination by 2030. The disease starts in childhood with repeated episodes of conjunctival Chlamydia trachomatis infection. This infection is associated with recurrent conjunctivitis (active trachoma), which, if left untreated, leads to cicatricial trachoma characterised by scarring of the conjunctiva, and potentially in-turned eyelashes (trachomatous trichiasis) in later life. Trachoma mainly affects the poorest and most rural communities; these populations typically have limited access to water and hygiene facilities. Blinding complications are most common in women who, in many cultures, act as caregivers from a young age for infected children. To eliminate trachoma as a public health problem, programmes implement a package of interventions known as SAFE; namely, surgery to treat trachomatous trichiasis, antibiotic mass drug administration to treat infection, facial cleanliness, and environmental improvement to limit transmission. The SAFE strategy has brought considerable success in the last two decades. As of December, 2024, 21 countries have eliminated the disease, and several others are on track to eliminate it soon. However, persistent and recrudescent active trachoma in some populations might challenge the success of the 2030 global elimination target. In such settings, novel, or more intensive, approaches must be promptly developed, tested, and scaled up to accelerate elimination.

Trachoma is a neglected tropical disease, and the leading infectious cause of blindness worldwide.1,2 Precipitated by recurrent episodes of infection with ocular strains of the bacterium Chlamydia trachomatis (Ct), trachoma begins in childhood as a chronic kerato-conjunctivitis known as active trachoma. This results in immuno-pathologically mediated conjunctival scarring (TS), which causes eyelid in-turning (entropion) with eyelashes scratching the eye (trachomatous trichiasis, TT). TT can cause painful corneal abrasions and ulceration. Resolution of ulcers is accompanied by corneal opacification, leading to vision impairment. Trachoma has major personal, social and economic consequences for affected individuals, families and communities.3 TT results in significant morbidity, functional and physical impairment, social withdrawal and exclusion, and reduced ability to work and earn an income, adversely affecting vision- and health-related quality of life, even before vision impairment develops.4–7 The global productivity loss from trachoma was estimated in 2003 at US$8 billion annually.8 In the 25 years, the global effort to eliminate trachoma as a public health problem has resulted in dramatic declines in the global burden of the disease.9 However, despite sustained interventions, it still affects the poorest communities, predominantly in Africa.9–12 In this seminar, we provide a distillation of the key clinical and public health features of trachoma.

The ocular strains of Ct cause a follicular conjunctivitis in children. While the follicles can be found throughout the palpebral and bulbar conjunctiva, they typically form a characteristic pattern in the upper eyelid conjunctiva: off-white, elevated, round, evenly spaced germinal centres. This can meet the definition of the sign trachomatous inflammation—follicular (TF, Figure 1b). TF can be associated with redness (hyperaemia) and inflammation (papillary reaction), which if florid, qualifies as trachomatous inflammation—intense (TI, Figure 1c), although these features are less specific for trachoma than the follicular pattern. The presence of TF and/or TI is known as “active trachoma”. While a single infection episode can clear within months, repeated infections may lead to conjunctival scarring. Several patterns of scars, trachomatous scarring (TS, Figure 1d) can be seen, including linear scars connecting necrotic follicles in a reticular pattern. Far less commonly, a horizontal linear scar forms in the upper eyelid, between the marginal and superior blood vessels (Arlt’s line), which has been called pathognomonic for trachoma. Progressive conjunctival scarring can lead to entropion and trachomatous trichiasis (TT, Figure 1g). Corneal damage results from pannus (fibrovascular change) and secondary infectious ulcers, leading to opacity (corneal opacity, (CO), Figure 1h) and vision impairment. When they occur, the follicular conjunctivitis and cicatricial changes including entropion, TT, and CO are typically bilateral, ultimately causing blindness.13

damage results from pannus (fibrovascular change) and secondary infectious ulcers, leading to opacity (corneal opacity, (CO), Figure 1h) and vision impairment. When they occur, the follicular conjunctivitis and cicatricial changes including entropion, TT, and CO are typically bilateral, ultimately causing blindness.13 Ct is a bacterium that reproduces inside host cells. The intracellular replicative form is known as a reticulate body. It inhabits a membrane-bound vacuole called an inclusion. Towards the end of the replicative cycle (Figure 2), elementary bodies (EBs) are formed, which have a rigid cell wall to prolong survival in the intercellular milieu. EBs are non-motile, but following host cell lysis, they can attach and enter new host cells in the same or a different host, initiating a further cycle of replication. Ct is classified into different serovars based on variations in its major outer membrane protein.15,16 Serovars A, B, Ba, and C are primarily associated with trachoma. Serovars D–K are mostly associated with urogenital tract infection, and serovars L1–3 cause the more invasive sexually transmitted disease, lymphogranuloma venereum. These different Ct lineages have emerged relatively recently in human history.17 The genome of Ct includes a 1,042,519-base pair chromosome and a 7493-base pair plasmid.18 A thorough understanding of the genome and proteome of Ct may be crucial for developing effective interventions to eliminate trachoma.

Ct is classified into different serovars based on variations in its major outer membrane protein.15,16 Serovars A, B, Ba, and C are primarily associated with trachoma. Serovars D–K are mostly associated with urogenital tract infection, and serovars L1–3 cause the more invasive sexually transmitted disease, lymphogranuloma venereum. These different Ct lineages have emerged relatively recently in human history.17 The genome of Ct includes a 1,042,519-base pair chromosome and a 7493-base pair plasmid.18 A thorough understanding of the genome and proteome of Ct may be crucial for developing effective interventions to eliminate trachoma. In cross-sectional studies of trachoma-endemic populations, there is often a marked mismatch at the individual level between the presence of active trachoma and the detection of Ct by polymerase chain reaction (PCR) or nucleic acid amplification tests (NAATs).20,21 In contrast, at the population level, active trachoma and detectable Ct are less tightly correlated. The individual mismatch reflects the different time courses of infection and disease episodes. The few cohort studies on the relative time courses indicate that individual episodes of infection vary in duration from a few days to a few weeks.22 In contrast, particularly in young children, inflammatory episodes of active disease may persist for several months in the absence of reinfection and well after Ct is no longer detectable. This has important implications for trachoma control, as the presence of active trachoma in an individual is not a consistently reliable indicator of current Ct infection.

ren, inflammatory episodes of active disease may persist for several months in the absence of reinfection and well after Ct is no longer detectable. This has important implications for trachoma control, as the presence of active trachoma in an individual is not a consistently reliable indicator of current Ct infection. Following introduction of Ct to the ocular surface, an active, replicating infection can become established in the conjunctival epithelium. Active trachoma is characterised at the tissue level by a mixed inflammatory cell infiltrate (lymphocytes, neutrophils and macrophages), dotted with lymphoid follicles, composed mostly of B cells. At the molecular level, active trachoma is associated with marked upregulation in pro-inflammatory cytokines and chemokines, as well as extracellular matrix modifiers. Resolution of Ct infection is believed to involve a TH1 cell mediated immune response, involving interferon-γ.23 Additionally, active trachoma and Ct infection are associated with TH17 responses, with some indication that this may promote inflammation and scarring.

chemokines, as well as extracellular matrix modifiers. Resolution of Ct infection is believed to involve a TH1 cell mediated immune response, involving interferon-γ.23 Additionally, active trachoma and Ct infection are associated with TH17 responses, with some indication that this may promote inflammation and scarring. The prevalence of the scarring complications of trachoma accrues with increasing age. Longitudinal studies with multiple clinical observation timepoints have consistently found a strong association between the presence of repeated episodes of conjunctival papillary inflammation (TI) and incident and/or progressive conjunctival scarring.24–28 The association between detectable episodes of Ct and scarring is weaker. It is possible that there is intrinsic variation in how individuals respond to Ct exposure, with some people developing a more marked chronic inflammatory response, leading to more extensive tissue damage and scarring on resolution. Individuals with more frequent exposure to reinfection are probably at greater risk of developing scarring.29 Inflamed conjunctiva with evolving scarring exhibits increased expression of several matrix metalloproteinases (MMP,7, MMP9 and MMP12), growth factors and pro-inflammatory genes (IL1β, IL-17A, CXCL5 and S100A7), which may promote scarring development.25

Ct is a bacterium that reproduces inside host cells. The intracellular replicative form is known as a reticulate body. It inhabits a membrane-bound vacuole called an inclusion. Towards the end of the replicative cycle (Figure 2), elementary bodies (EBs) are formed, which have a rigid cell wall to prolong survival in the intercellular milieu. EBs are non-motile, but following host cell lysis, they can attach and enter new host cells in the same or a different host, initiating a further cycle of replication. Ct is classified into different serovars based on variations in its major outer membrane protein.15,16 Serovars A, B, Ba, and C are primarily associated with trachoma. Serovars D–K are mostly associated with urogenital tract infection, and serovars L1–3 cause the more invasive sexually transmitted disease, lymphogranuloma venereum. These different Ct lineages have emerged relatively recently in human history.17 The genome of Ct includes a 1,042,519-base pair chromosome and a 7493-base pair plasmid.18 A thorough understanding of the genome and proteome of Ct may be crucial for developing effective interventions to eliminate trachoma.

In cross-sectional studies of trachoma-endemic populations, there is often a marked mismatch at the individual level between the presence of active trachoma and the detection of Ct by polymerase chain reaction (PCR) or nucleic acid amplification tests (NAATs).20,21 In contrast, at the population level, active trachoma and detectable Ct are less tightly correlated. The individual mismatch reflects the different time courses of infection and disease episodes. The few cohort studies on the relative time courses indicate that individual episodes of infection vary in duration from a few days to a few weeks.22 In contrast, particularly in young children, inflammatory episodes of active disease may persist for several months in the absence of reinfection and well after Ct is no longer detectable. This has important implications for trachoma control, as the presence of active trachoma in an individual is not a consistently reliable indicator of current Ct infection.

Following introduction of Ct to the ocular surface, an active, replicating infection can become established in the conjunctival epithelium. Active trachoma is characterised at the tissue level by a mixed inflammatory cell infiltrate (lymphocytes, neutrophils and macrophages), dotted with lymphoid follicles, composed mostly of B cells. At the molecular level, active trachoma is associated with marked upregulation in pro-inflammatory cytokines and chemokines, as well as extracellular matrix modifiers. Resolution of Ct infection is believed to involve a TH1 cell mediated immune response, involving interferon-γ.23 Additionally, active trachoma and Ct infection are associated with TH17 responses, with some indication that this may promote inflammation and scarring. The prevalence of the scarring complications of trachoma accrues with increasing age. Longitudinal studies with multiple clinical observation timepoints have consistently found a strong association between the presence of repeated episodes of conjunctival papillary inflammation (TI) and incident and/or progressive conjunctival scarring.24–28 The association between detectable episodes of Ct and scarring is weaker. It is possible that there is intrinsic variation in how individuals respond to Ct exposure, with some people developing a more marked chronic inflammatory response, leading to more extensive tissue damage and scarring on resolution. Individuals with more frequent exposure to reinfection are probably at greater risk of developing scarring.29

ere is intrinsic variation in how individuals respond to Ct exposure, with some people developing a more marked chronic inflammatory response, leading to more extensive tissue damage and scarring on resolution. Individuals with more frequent exposure to reinfection are probably at greater risk of developing scarring.29 Inflamed conjunctiva with evolving scarring exhibits increased expression of several matrix metalloproteinases (MMP,7, MMP9 and MMP12), growth factors and pro-inflammatory genes (IL1β, IL-17A, CXCL5 and S100A7), which may promote scarring development.25

In April 2024, trachoma was known to be a public health problem in 39 countries in Africa, Asia, Central and South America, Australia, and the Middle East, with 103·2 million people at risk of developing blindness due to trachoma unless interventions are successfully implemented, Figure 3.30 About 90% (93·1 million) of the global burden of trachoma is found in WHO’s African Region.30 Ethiopia is the most affected country, accounting for about 59% of the global burden, with ~61·4 million people living in trachoma-endemic districts in April 2024.30 The global burden of TT was estimated at 1·5 million people in 1,726 districts.30 Ct likely leaves the ocular surface in tear fluid and nasal secretions.31 Evidence then points to direct onward transmission of Ct via multiple routes, including on skin, fomites and eye-seeking flies. Studies mapping the presence of Ct using PCR tests of surface swabs in an endemic environment found detectable Ct DNA on faces, hands, fabrics and flies.32 Active trachoma and conjunctival Ct infection consistently exhibit marked geospatial clustering,33,34 suggesting localised transmission is dominant, within households and parts of communities. Crowded living conditions are associated with trachoma, perhaps indicating increased opportunities for transmission events.35 Other markers of poverty, such as limited access to water and sanitation, are also strongly associated with trachoma.9,36,37

transmission is dominant, within households and parts of communities. Crowded living conditions are associated with trachoma, perhaps indicating increased opportunities for transmission events.35 Other markers of poverty, such as limited access to water and sanitation, are also strongly associated with trachoma.9,36,37 Unclean faces, particularly characterised by peri-ocular secretions, are frequently associated with the individual-level presence of active trachoma and Ct and may be an important part of the transmission pathway.38–40 Limited access to water for washing faces, hands and clothes makes it harder to keep these surfaces clean, in order to limit transmission. The primary eye-seeking fly reported in many trachoma-endemic environments is Musca sorbens.41 This preferentially breeds in human faeces. Environments with limited access to sanitation and greater faecal contamination have more breeding sites to support a larger fly population.42 Female M. sorbens are particularly attracted to the eyes of children with active trachoma and ocular discharge.10,39,42,43 The signs of active trachoma and ocular Ct infection are most prevalent in pre-school age children. At this age, boys and girls tend to be equally affected.20 In contrast, the scarring sequelae of trachoma, which appear in older age groups, invariably affect women more frequently than men. This gender difference is usually attributed to a greater lifetime exposure to ocular Ct infections among women, who are often the primary caregivers of young children, and therefore likely to be more frequently exposed.44

In programmatic and epidemiological investigations, trachoma is typically diagnosed through signs detected by trained clinical observers using a torch and a magnification loupe.45 The upper eyelid is examined for entropion and TT, including evidence of epilation. Active trachoma (TF, TI) and conjunctival scarring are assessed by everting the upper eyelid. Population-based surveys typically report the prevalence of TF in children aged 1–9 years, while the prevalence of TT is reported in people aged 15 years and older. WHO has two grading systems for trachoma: the more detailed Follicles-Papillae-Cicatricae (FPC) grading and the simplified trachoma grading.14,46–48 The FPC system was developed to grade severity of (1) trachomatous follicles, (2) papillary inflammation, (3) conjunctival scarring, (4) TT and/or entropion and (5) corneal scarring, Table 1. This grading system has been useful for assessing variation in disease severity, particularly in research studies. However, it is more complex than needed for programmatic decision-making, for which examinations are usually performed by non-specialists in field settings. As a result, the simplified grading system was developed for programmatic use. This defines the presence or absence of key clinical features, (see Figure 1 footnote).14 The gradable sections in FPC and the simplified grading system are shown in Figure 4. The numbered zones refer to those in the FPC Grading System. Zones 3 and 2 are examined for trachomatous inflammation---follicular when using the WHO simplified system.47

WHO has two grading systems for trachoma: the more detailed Follicles-Papillae-Cicatricae (FPC) grading and the simplified trachoma grading.14,46–48 The FPC system was developed to grade severity of (1) trachomatous follicles, (2) papillary inflammation, (3) conjunctival scarring, (4) TT and/or entropion and (5) corneal scarring, Table 1. This grading system has been useful for assessing variation in disease severity, particularly in research studies. However, it is more complex than needed for programmatic decision-making, for which examinations are usually performed by non-specialists in field settings. As a result, the simplified grading system was developed for programmatic use. This defines the presence or absence of key clinical features, (see Figure 1 footnote).14 The gradable sections in FPC and the simplified grading system are shown in Figure 4. The numbered zones refer to those in the FPC Grading System. Zones 3 and 2 are examined for trachomatous inflammation---follicular when using the WHO simplified system.47 Trachoma is a disease caused by an infection; not the infection itself. However, laboratory diagnosis of current or past ocular Ct infection is increasingly finding programmatic application in global trachoma elimination efforts.49–51

The numbered zones refer to those in the FPC Grading System. Zones 3 and 2 are examined for trachomatous inflammation---follicular when using the WHO simplified system.47 Trachoma is a disease caused by an infection; not the infection itself. However, laboratory diagnosis of current or past ocular Ct infection is increasingly finding programmatic application in global trachoma elimination efforts.49–51 The gold standard assays for current Ct infection are NAATs.45 These detect the presence of Ct DNA or RNA with high sensitivity and specificity. NAATs are performed on conjunctival swabs, which can be collected in a standardised way to obtain approximately consistent volumes of cellular and extracellular material.52 Non-commercial (“home-brew”) quantitative PCR assays are also available.52–54 Viability PCR, which uses propidium monoazide to prevent amplification of DNA from membrane-impaired bacteria, has recently been used to investigate ocular Ct transmission routes.55 Beyond NAATs, there are a variety of older techniques to detect current infection, including microscopy-based tests, enzyme-linked immunosorbent assays (ELISA) to detect antigen, and chlamydial culture.45 They are now rarely used. Culture is highly specific and has the singular advantage of facilitating the assessment of antimicrobial susceptibility,56 but is labour-intensive, requires specialised cell lines and incubation conditions, and is poorly reproducible. Ct antibiotic resistance evaluation is increasingly undertaken genotypically.57

sed. Culture is highly specific and has the singular advantage of facilitating the assessment of antimicrobial susceptibility,56 but is labour-intensive, requires specialised cell lines and incubation conditions, and is poorly reproducible. Ct antibiotic resistance evaluation is increasingly undertaken genotypically.57 There is a growing appreciation of the shortcomings of using TF prevalence alone to guide decision-making on antibiotic mass drug administration (MDA), a cornerstone of trachoma elimination programmes. Seroprevalence (or seroconversion rate) in young children, based on antibodies to the Ct antigen Pgp3, is emerging as a useful complementary index.58,59

Trachoma is a disease caused by an infection; not the infection itself. However, laboratory diagnosis of current or past ocular Ct infection is increasingly finding programmatic application in global trachoma elimination efforts.49–51 The gold standard assays for current Ct infection are NAATs.45 These detect the presence of Ct DNA or RNA with high sensitivity and specificity. NAATs are performed on conjunctival swabs, which can be collected in a standardised way to obtain approximately consistent volumes of cellular and extracellular material.52 Non-commercial (“home-brew”) quantitative PCR assays are also available.52–54 Viability PCR, which uses propidium monoazide to prevent amplification of DNA from membrane-impaired bacteria, has recently been used to investigate ocular Ct transmission routes.55 Beyond NAATs, there are a variety of older techniques to detect current infection, including microscopy-based tests, enzyme-linked immunosorbent assays (ELISA) to detect antigen, and chlamydial culture.45 They are now rarely used. Culture is highly specific and has the singular advantage of facilitating the assessment of antimicrobial susceptibility,56 but is labour-intensive, requires specialised cell lines and incubation conditions, and is poorly reproducible. Ct antibiotic resistance evaluation is increasingly undertaken genotypically.57

The SAFE strategy, introduced in 1993, is a comprehensive approach to trachoma control, focusing on Surgery for TT, Antibiotics to clear Ct infection, and Facial cleanliness and Environmental improvement (water and sanitation) to limit chlamydial transmission.60 Current prevention efforts align with this strategy, aiming to limit Ct transmission and prevent blindness. Although no chlamydia vaccine is commercially available, a vaccine based on the recombinant protein subunit CTH522 has now completed two Phase I trials.61,62 These trials assessed the safety and immunogenicity with different adjuvants. CTH522 adjuvanted with CAF01 liposomes induced stronger T-cell and antibody responses than when combined with aluminium hydroxide.61 Various regimens of CTH522 with CAF01 or CAF09b adjuvants were safe across intramuscular, intradermal, and ocular administration routes, with the latter two enhancing mucosal immunity.62

CTH522 adjuvanted with CAF01 liposomes induced stronger T-cell and antibody responses than when combined with aluminium hydroxide.61 Various regimens of CTH522 with CAF01 or CAF09b adjuvants were safe across intramuscular, intradermal, and ocular administration routes, with the latter two enhancing mucosal immunity.62 Surgery is provided to people with TT to reduce their risk of sight loss. The aim of surgery is to reposition the eyelashes, limiting the damage they cause from abrading the cornea. Patients also benefit from a marked reduction in pain and may experience some improvement in vision.63 The current WHO recommendation is that surgical management should be offered to all patients having TT with eyelid entropion.64 Many different surgical procedures have been described to correct TT.65–68 These range from eyelid margin splinting to excision of the tarsus. Some surgical procedures address the eyelid margin and the anterior lamella, while others lengthen or rotate the tarsal conjunctiva.65 The two most commonly used surgical procedures are the Bilamellar Tarsal Rotation (BLTR) and Posterior Lamellar Tarsal Rotation (PLTR) procedures.64 WHO currently recommends new surgeons are trained in the PLTR procedure69 following the results of a clinical trial that found PLTR to be superior to BLTR in reducing postoperative TT (PTT), the presence of TT after surgery.70,71

amellar Tarsal Rotation (BLTR) and Posterior Lamellar Tarsal Rotation (PLTR) procedures.64 WHO currently recommends new surgeons are trained in the PLTR procedure69 following the results of a clinical trial that found PLTR to be superior to BLTR in reducing postoperative TT (PTT), the presence of TT after surgery.70,71 Not all TT requires surgery. WHO recommends that patients with non-entropic TT, TT in which eyelashes do not touch the cornea in the primary position of gaze, and those declining surgery after appropriate counselling can be offered high-quality eyelash epilation. Epilation is commonly practised in many trachoma-endemic countries.65,72–74 Studies indicate that epilation can be used as an alternative to surgery in people with minor (≤5 eyelashes touching the eye or evidence of epilation in <1/3rd of eyelid margin) unoperated and postoperative TT.74–76

h-quality eyelash epilation. Epilation is commonly practised in many trachoma-endemic countries.65,72–74 Studies indicate that epilation can be used as an alternative to surgery in people with minor (≤5 eyelashes touching the eye or evidence of epilation in <1/3rd of eyelid margin) unoperated and postoperative TT.74–76 Ct is susceptible to several antimicrobial classes, including tetracyclines, sulfonamides, beta-lactams, and macrolides.77 Oral azithromycin has particular advantages in its safety profile and long tissue half-life. Following studies indicating that a single dose of oral azithromycin (20 mg/kg up to 1 gram) was comparable to 6 weeks of topical tetracycline in eliminating ocular Ct infection from individuals,78–80 and that three doses of oral azithromycin MDA to those aged ≥1 year were at least as effective as the longer course of topical tetracycline,81 WHO recommended single-dose annual azithromycin MDA.82 The number of MDA rounds planned depends on the prevalence of TF in 1–9-year-olds: ≥30% warrants 5 annual MDA rounds before re-survey; ≥10–29·9% warrants 3 annual rounds before re-survey; and ≥5–9·9% warrants one round before re-survey.82,83 Single-dose annual azithromycin MDA was proven to dramatically reduce infection.84,85

ber of MDA rounds planned depends on the prevalence of TF in 1–9-year-olds: ≥30% warrants 5 annual MDA rounds before re-survey; ≥10–29·9% warrants 3 annual rounds before re-survey; and ≥5–9·9% warrants one round before re-survey.82,83 Single-dose annual azithromycin MDA was proven to dramatically reduce infection.84,85 Mathematical models predict that more severely affected communities might require more-frequent-than-annual distributions to achieve success.86,87 Biannual and quarterly MDA have reduced infection rapidly, and in some cases completely eliminated infection from even the most hyper-endemic populations.88–93 Distributing antibiotics to entire communities has raised concern over selection of antibiotic-resistant bacteria. While azithromycin resistance has not been detected in conjunctival Ct itself, selection for resistance has been found in other bacterial pathogens, such as Streptococcus pneumoniae, in populations post-MDA.94,95 Strategies to mitigate selection of resistance and overall antibiotic exposure may include restricting distribution to the younger age-groups thought to be key for Ct transmission.96,97

selection for resistance has been found in other bacterial pathogens, such as Streptococcus pneumoniae, in populations post-MDA.94,95 Strategies to mitigate selection of resistance and overall antibiotic exposure may include restricting distribution to the younger age-groups thought to be key for Ct transmission.96,97 Facial cleanliness (‘F’) interventions aim to reduce transmission of Ct by removing ocular and nasal discharge from faces. This can be achieved through promotion of regular face washing with soap and complementary practices, such as handwashing and bathing with soap, all of which are facilitated by consistent access to water. Environmental improvement (‘E’) strategies target (i) access to clean water to facilitate “F”, and (ii) control of M. sorbens populations directly through insecticidal, trapping or repellent measures,98,99 and indirectly by reducing fly breeding sites through sanitation interventions that promote access to and exclusive use of latrines.

ovement (‘E’) strategies target (i) access to clean water to facilitate “F”, and (ii) control of M. sorbens populations directly through insecticidal, trapping or repellent measures,98,99 and indirectly by reducing fly breeding sites through sanitation interventions that promote access to and exclusive use of latrines. Associations between active trachoma, Ct infection, water and sanitation access, and periocular fly density have been established.36,37,41 Moreover, it is biologically plausible that face washing helps to suppress onward transmission by reducing the presence of infectious oculo-nasal discharge on the face. However, definitively isolating the impact of individual F and E interventions remains challenging due to methodological limitations, heterogeneity in intervention design and implementation, and variations in water access, sanitation coverage, and outcome measurement.100–107 Modelling of cross-sectional data suggests that improved access to water is associated with lower active trachoma prevalence at lower coverage levels than those required for sanitation.107 This highlights the importance of shifting households onto the ‘water use plateau’ to increase water availability for face washing.108 Integrating hygiene promotion into water and sanitation systems strengthening could maximise resource utilisation. Estimating with greater precision the effectiveness of separate F and E interventions would be helpful, particularly for long-term control of trachoma in districts affected by persistent or recrudescent active trachoma. This will require careful consideration of appropriate metrics to measure effectiveness outcomes.109

Estimating with greater precision the effectiveness of separate F and E interventions would be helpful, particularly for long-term control of trachoma in districts affected by persistent or recrudescent active trachoma. This will require careful consideration of appropriate metrics to measure effectiveness outcomes.109 Irrespective of their effect on trachoma transmission, equitable climate-resilient water and sanitation systems along with promotions to encourage sustained uptake of hygiene behaviours through locally tailored, theory- and evidence-based interventions are essential.110 Continued investment in and monitoring of these efforts will contribute to health and equity goals that extend beyond trachoma elimination.111

sanitation systems along with promotions to encourage sustained uptake of hygiene behaviours through locally tailored, theory- and evidence-based interventions are essential.110 Continued investment in and monitoring of these efforts will contribute to health and equity goals that extend beyond trachoma elimination.111 To determine where SAFE interventions are needed and for how long, data are needed at the EU (evaluation unit) level. WHO defines an EU, for trachoma elimination purposes, as “the normal administrative unit for health care management, consisting of a population unit between 100,000–250,000 persons”.82 Baseline surveys are conducted to determine whether trachoma is a public health problem and if interventions are needed. If TF <5%, no trachoma-specific AFE interventions are needed. If the prevalence of TT unknown to the health system (excluding individuals with post-surgical TT, individuals with TT who have refused surgery for it, and individuals with TT who have a surgical date set in the future) is ≥0·2%, public health level-actions such as active case finding and outreach services are recommended, whereas if the prevalence is <0·2%, remaining and incident TT cases should be managed within routine eyecare services.83,112

efused surgery for it, and individuals with TT who have a surgical date set in the future) is ≥0·2%, public health level-actions such as active case finding and outreach services are recommended, whereas if the prevalence is <0·2%, remaining and incident TT cases should be managed within routine eyecare services.83,112 From 2012–2016, the Global Trachoma Mapping Project (GTMP) conducted baseline surveys in all 1,546 accessible suspected trachoma-endemic districts worldwide (905 EUs), across 29 countries, examining over 2·6 million people, using a standardised survey methodology that conformed to WHO recommendations, and ensuring quality assurance and quality control at every step of the process.113,114 Following the GTMP, Tropical Data (TD) was established to support baseline surveys in newly accessible or suspected trachoma-endemic districts, as well as to assist health ministries to conduct impact and surveillance surveys, building on the methods used by the GTMP.115,116 WHO recommends that impact surveys be conducted 6–12 months after the last planned MDA round to determine if the TF elimination prevalence threshold has been met or if further interventions are needed, and that surveillance surveys be conducted at least 2 years after an impact survey has returned a TF prevalence <5% to determine whether TF prevalence has remained below 5% in the absence of ongoing MDA.117 TD also supports health ministries to conduct TT-only surveys in certain epidemiological contexts.118 As of October 2024, TD had supported surveys in over 3800 EUs across 52 countries, covering the examination of over 12·4 million people.

Surgery is provided to people with TT to reduce their risk of sight loss. The aim of surgery is to reposition the eyelashes, limiting the damage they cause from abrading the cornea. Patients also benefit from a marked reduction in pain and may experience some improvement in vision.63 The current WHO recommendation is that surgical management should be offered to all patients having TT with eyelid entropion.64 Many different surgical procedures have been described to correct TT.65–68 These range from eyelid margin splinting to excision of the tarsus. Some surgical procedures address the eyelid margin and the anterior lamella, while others lengthen or rotate the tarsal conjunctiva.65 The two most commonly used surgical procedures are the Bilamellar Tarsal Rotation (BLTR) and Posterior Lamellar Tarsal Rotation (PLTR) procedures.64 WHO currently recommends new surgeons are trained in the PLTR procedure69 following the results of a clinical trial that found PLTR to be superior to BLTR in reducing postoperative TT (PTT), the presence of TT after surgery.70,71

Ct is susceptible to several antimicrobial classes, including tetracyclines, sulfonamides, beta-lactams, and macrolides.77 Oral azithromycin has particular advantages in its safety profile and long tissue half-life. Following studies indicating that a single dose of oral azithromycin (20 mg/kg up to 1 gram) was comparable to 6 weeks of topical tetracycline in eliminating ocular Ct infection from individuals,78–80 and that three doses of oral azithromycin MDA to those aged ≥1 year were at least as effective as the longer course of topical tetracycline,81 WHO recommended single-dose annual azithromycin MDA.82 The number of MDA rounds planned depends on the prevalence of TF in 1–9-year-olds: ≥30% warrants 5 annual MDA rounds before re-survey; ≥10–29·9% warrants 3 annual rounds before re-survey; and ≥5–9·9% warrants one round before re-survey.82,83 Single-dose annual azithromycin MDA was proven to dramatically reduce infection.84,85

Facial cleanliness (‘F’) interventions aim to reduce transmission of Ct by removing ocular and nasal discharge from faces. This can be achieved through promotion of regular face washing with soap and complementary practices, such as handwashing and bathing with soap, all of which are facilitated by consistent access to water. Environmental improvement (‘E’) strategies target (i) access to clean water to facilitate “F”, and (ii) control of M. sorbens populations directly through insecticidal, trapping or repellent measures,98,99 and indirectly by reducing fly breeding sites through sanitation interventions that promote access to and exclusive use of latrines.

To determine where SAFE interventions are needed and for how long, data are needed at the EU (evaluation unit) level. WHO defines an EU, for trachoma elimination purposes, as “the normal administrative unit for health care management, consisting of a population unit between 100,000–250,000 persons”.82 Baseline surveys are conducted to determine whether trachoma is a public health problem and if interventions are needed. If TF <5%, no trachoma-specific AFE interventions are needed. If the prevalence of TT unknown to the health system (excluding individuals with post-surgical TT, individuals with TT who have refused surgery for it, and individuals with TT who have a surgical date set in the future) is ≥0·2%, public health level-actions such as active case finding and outreach services are recommended, whereas if the prevalence is <0·2%, remaining and incident TT cases should be managed within routine eyecare services.83,112

There are three criteria for elimination of trachoma as a public health problem: (1) a prevalence of TT “unknown to the health system” <0·2% in those aged ≥15 years, and (2) a prevalence of TF <5% in 1–9-year-olds sustained for at least two years in the absence of ongoing antibiotic MDA, in each formerly-endemic district; plus (3) a system to identify and manage incident cases of TT.119 WHO has established a process for validating a Member State’s claim that it meets these three criteria.119 A dossier should be prepared and submitted to WHO, which convenes an ad-hoc, independent dossier review group to assess the presented evidence. In the event that the dossier review group recommends that the claim be validated, WHO reports the Member State’s achievement in the next annual trachoma-specific article published in the Weekly Epidemiological Record,30 and changes the trachoma endemicity status of the Member State in the Global Health Observatory120 to “validated as having eliminated trachoma as a public health problem”.30

lidated, WHO reports the Member State’s achievement in the next annual trachoma-specific article published in the Weekly Epidemiological Record,30 and changes the trachoma endemicity status of the Member State in the Global Health Observatory120 to “validated as having eliminated trachoma as a public health problem”.30 The number of people at risk of trachoma has fallen by 93%, from 1.5 billion in 2002 to 103.2 million in April 2024, and the number of people with TT has fallen by 80% in the same time-period, from 7·6 million to 1·5 million.30 As of March 2025, 21 countries have been validated by WHO as having eliminated trachoma as a public health problem: Benin, Cambodia, China, Gambia, Ghana, India, Iraq, Islamic Republic of Iran, Lao People’s Democratic Republic, Malawi, Mali, Mexico, Morocco, Myanmar, Nepal, Oman, Pakistan, Saudi Arabia, Togo and Vanuatu and Viet Nam.121 Seven more countries claim to have met the prevalence criteria for elimination: Botswana, Burundi, Guatemala, Mauritania, Namibia, Papua New Guinea, and Tunisia.30 Although models predict that the majority of EUs will meet the elimination targets by 2030, a small proportion may require additional efforts if the 2030 target is to be met.122,123

m to have met the prevalence criteria for elimination: Botswana, Burundi, Guatemala, Mauritania, Namibia, Papua New Guinea, and Tunisia.30 Although models predict that the majority of EUs will meet the elimination targets by 2030, a small proportion may require additional efforts if the 2030 target is to be met.122,123 In the 2021–2030 NTD road map, the NTD community committed to a shift from siloed disease-specific programmes to holistic, cross-cutting approaches, including integration across NTDs and beyond, and mainstreaming into the national health system.1 Integration and mainstreaming are crucial to a successful and sustainable trachoma elimination programme. In trachoma elimination, integration could include the joint delivery of TT surgical activities with other health care activities, azithromycin MDA with other NTDs’ MDA, F & E interventions co-delivered with other sectors, and integrated monitoring, evaluation and reporting to maximise efficiency. Mainstreaming trachoma initiatives ensures trachoma control and surveillance are embedded in national policies, frameworks, and systems for sustainable, efficient prevention and control.1 It enables patients to access all treatment, care and support that they need, even in the post-elimination era.

maximise efficiency. Mainstreaming trachoma initiatives ensures trachoma control and surveillance are embedded in national policies, frameworks, and systems for sustainable, efficient prevention and control.1 It enables patients to access all treatment, care and support that they need, even in the post-elimination era. Weak health systems and inadequate capacity pose challenges to successful transition and sustainability of interventions and surveillance.124 Countries are expected to strengthen all critical components of their health system supported by context-specific evidence prior to embarking into mainstreaming efforts.1,124 The F & E components of the SAFE strategy depend on the education, water resources and environmental sectors. However, these sectors often operate independently from health, necessitating a coordinated approach to planning, budgeting and implementation. The WHO WASH-NTD guide and toolkit offers guidance on how to effectively engage and work collaboratively with these adjacent sectors.125

er resources and environmental sectors. However, these sectors often operate independently from health, necessitating a coordinated approach to planning, budgeting and implementation. The WHO WASH-NTD guide and toolkit offers guidance on how to effectively engage and work collaboratively with these adjacent sectors.125 Persistent and recrudescent active trachoma coupled with insecurity to operate in several trachoma-endemic settings presently challenge the success of the entire 2030 global elimination target.126 There is growing evidence that in some hyperendemic populations, the elimination threshold of <5% TF prevalence in children aged 1–9 years (TF1-9) is not met despite years of implementation of recommended interventions.127,128 In some hyperendemic areas, the currently recommended single annual community wide antibiotic schedule appears insufficient to reliably achieve long-term control, with re-emergence of disease being typical.129,130 As of June 2024, 253 EUs (16·8% of all ever-endemic districts worldwide) had persistent trachoma, defined as undergoing two or more trachoma impact surveys with TF1-9 never being below 5%. Another 174 districts (10·4% of all ever-endemic districts) had recrudescent trachoma, defined by at least one trachoma surveillance survey having returned a TF1-9 ≥5% (with current prevalence remaining ≥5%).

persistent trachoma, defined as undergoing two or more trachoma impact surveys with TF1-9 never being below 5%. Another 174 districts (10·4% of all ever-endemic districts) had recrudescent trachoma, defined by at least one trachoma surveillance survey having returned a TF1-9 ≥5% (with current prevalence remaining ≥5%). The biological or methodological reasons for persistence and recrudescence are not clearly understood. The most consistent predictor has been high prevalence of TF at baseline. Addressing persistent and recrudescent trachoma requires a context specific, multifaceted, innovative approach supported by evidence. In WHO’s 2021 informal consultation on end-game challenges for trachoma elimination, it was recognised that the evidence base for optimal management of persistent and recrudescent trachoma is weak, and that, as a consequence, tailored management guided by expert opinion is likely to be the most appropriate current course of action.126 Among the suggested tailored management options that could be adopted by national programmes are: a) more MDA rounds and extended periods of F and E intervention before re-survey; b) more frequent than annual MDA rounds, with the possibility of additional MDA rounds only to demographic subgroups likely to have the highest prevalence of conjunctival Ct infection; and c) more intensive F and E interventions.126

are: a) more MDA rounds and extended periods of F and E intervention before re-survey; b) more frequent than annual MDA rounds, with the possibility of additional MDA rounds only to demographic subgroups likely to have the highest prevalence of conjunctival Ct infection; and c) more intensive F and E interventions.126 PTT is the most important and most frequently observed measure of undesirable surgical outcomes. PTT incidence varies by the type of surgical procedure and follow-up time. Studies have reported a PTT cumulative incidence of 2% at 6 weeks and 60% at 3 years after surgery, with an average of around 20% by 1 year.65,68,131–133 There is a consistent pattern to PTT: an initially high rate during the first six months, followed by a slower rate after six months. A study in Ethiopia reported a PTT rate of 3·5% per month during the first six months, dropping to 0·8% per month between six and 24 months (RR 0·24, p=0·0001).134 PTT is a significant challenge in preventing blindness from trachoma in several ways. First, PTT sustains eye pain and increases the risk of CO and vision loss, negatively impacting quality of life and mental health. Second, PTT deters other patients from seeking out or accepting TT surgery, hampering surgical uptake. Third, management of PTT requires a higher level of expertise than the initial operation, absorbing significant resources within trachoma programmes that are often already overstretched.

ity of life and mental health. Second, PTT deters other patients from seeking out or accepting TT surgery, hampering surgical uptake. Third, management of PTT requires a higher level of expertise than the initial operation, absorbing significant resources within trachoma programmes that are often already overstretched. There is a need to collect data on the proportion of TT patients who are effectively managed and not requiring further active management after their primary operations. WHO recommends that programmes should aim to reduce cumulative PTT incidence to below 10% at 6 months for cases with minor preoperative TT (≤5 eyelashes) and below 20% for cases with major postoperative TT (>5 eyelashes).133 Use of updated resources and tools, including surgical training manuals, and surgical simulators such as Head Start,135 to standardise and improve surgeon performance, and periodic review of surgeons’ skill through analysis of surgical outcomes, could help to enhance our collective ability to improve surgical quality.64

se of updated resources and tools, including surgical training manuals, and surgical simulators such as Head Start,135 to standardise and improve surgeon performance, and periodic review of surgeons’ skill through analysis of surgical outcomes, could help to enhance our collective ability to improve surgical quality.64 Part of the trachoma elimination validation dossier is outlining national plans for post-validation surveillance, including provision of surgical services for incident TT cases, and continued health ministry engagement with other government ministries for the provision of WASH services. Countries must also demonstrate that they are committed to continued surveillance, so that any recrudescent disease can be detected, which should then be reported to WHO’s Global NTD Programme and noted in the Global Health Observatory and WHO’s Weekly Epidemiological Record.136 WHO does not specify how countries should conduct post-validation surveillance, as the appropriate methodology will be country- and context-specific.

isease can be detected, which should then be reported to WHO’s Global NTD Programme and noted in the Global Health Observatory and WHO’s Weekly Epidemiological Record.136 WHO does not specify how countries should conduct post-validation surveillance, as the appropriate methodology will be country- and context-specific. As such, different countries have employed different approaches.137,138 Most countries are employing passive surveillance approaches, with TF and TT identification and reporting integrated into national integrated surveillance systems,139,140 with training to ensure accurate detection of cases, and referral systems for the appropriate management of individuals with TT. Some countries are also using active surveillance strategies, such as prevalence surveys and sentinel site monitoring. Furthermore, the use of complementary indicators to detect evidence of current and past C. trachomatis infection is being used, for example in Ghana and Morocco.140,141 Through these efforts, countries are able to detect indications of disease recrudescence, identify the target areas and population groups involved, plan effective delivery of the necessary interventions, and continue to advocate for resources. Nepal and Ethiopia have had contrasting experiences in trying to eliminate trachoma. Here, we describe some of their successes and challenges to provide locally-grounded examples of overall global progress.

As such, different countries have employed different approaches.137,138 Most countries are employing passive surveillance approaches, with TF and TT identification and reporting integrated into national integrated surveillance systems,139,140 with training to ensure accurate detection of cases, and referral systems for the appropriate management of individuals with TT. Some countries are also using active surveillance strategies, such as prevalence surveys and sentinel site monitoring. Furthermore, the use of complementary indicators to detect evidence of current and past C. trachomatis infection is being used, for example in Ghana and Morocco.140,141 Through these efforts, countries are able to detect indications of disease recrudescence, identify the target areas and population groups involved, plan effective delivery of the necessary interventions, and continue to advocate for resources. Nepal and Ethiopia have had contrasting experiences in trying to eliminate trachoma. Here, we describe some of their successes and challenges to provide locally-grounded examples of overall global progress. In 1981, trachoma was the second commonest cause of preventable blindness nationally, and highly endemic in many parts of the country, with prevalence estimates of active trachoma as high as 23% in several districts. The National Trachoma Program (NTP) was launched in 2002 and conducted population-based trachoma prevalence surveys throughout the country. These surveys identified trachoma as a public health problem in 20 of 75 districts. The NTP adopted an integrated approach to trachoma elimination, with Nepal Netra Jyoti Sangh (NNJS), a national NGO leading the surgical component, the Ministry of Health and Population (MoHP) overseeing antibiotic MDA, and water, sanitation and education partners delivering the “F” and “E” components of SAFE. On 22 November 2018, WHO congratulated Nepal, the first country in WHO’s South-East Asia Region, for eliminating trachoma as a public health problem.

onent, the Ministry of Health and Population (MoHP) overseeing antibiotic MDA, and water, sanitation and education partners delivering the “F” and “E” components of SAFE. On 22 November 2018, WHO congratulated Nepal, the first country in WHO’s South-East Asia Region, for eliminating trachoma as a public health problem. Elimination of trachoma in Nepal had many challenges, including difficult geography, severely limited financial resources and political upheaval. However, the country overcame each issue by applying an integrated and holistic approach, efficient administrative coordination between stakeholders, strong political support, social mobilisation and ownership of the programme by NNJS. Nepal has demonstrated that carefully planned strategies, implemented with the involvement of all technical and social stakeholders, can lead to successful elimination of trachoma.

ent administrative coordination between stakeholders, strong political support, social mobilisation and ownership of the programme by NNJS. Nepal has demonstrated that carefully planned strategies, implemented with the involvement of all technical and social stakeholders, can lead to successful elimination of trachoma. In Ethiopia, the SAFE strategy has been implemented as a national programme since 2003. More than 1·7 million TT operations have been performed, ~500 million doses of azithromycin have been distributed, and millions of pit latrines built. Thanks to these interventions, significant progress has been made. The mean EU-level TF prevalence fell from 26·2% in 2015 to 9·3% in 2023, a 64·5% reduction. The mean EU-level prevalence of TT fell from 2·07% in 2003 to 0·80% in 2023, a 61% reduction. As of 2023, among 850 districts known to have had a TT prevalence above the elimination threshold at baseline, 132 (15·5%) were below the elimination threshold. Similarly, among 886 districts with a baseline TF prevalence above the elimination threshold at baseline, 320 (36·1%) were below the elimination threshold, Figure 5.

2023, among 850 districts known to have had a TT prevalence above the elimination threshold at baseline, 132 (15·5%) were below the elimination threshold. Similarly, among 886 districts with a baseline TF prevalence above the elimination threshold at baseline, 320 (36·1%) were below the elimination threshold, Figure 5. Despite this encouraging progress, after two decades of SAFE strategy implementation, including up to 15 rounds of azithromycin MDA for some populations, trachoma persists in some districts, with a prevalence far above the WHO elimination threshold.142 As of June 2024, Ethiopia has about 84% and 62% of all districts worldwide known to have persistent and recrudescent active trachoma, respectively. There is consensus among stakeholders in Ethiopia that continuing the same pattern of SAFE strategy implementation (“business as usual”) is unlikely to lead to elimination by 2030, and novel, potentially more effective approaches need to be developed, tested, and rolled out. The Ethiopian Ministry of Health, in addition to strengthening the F & E interventions, is embarking on a trial of doubling the frequency of azithromycin MDA in children, to accelerate trachoma elimination in districts with persistent disease. These efforts need to be supported by high MDA coverage across communities, and behavioural change interventions that promote consistent personal and environmental hygiene practices, along with a monitoring system.

The number of people at risk of trachoma has fallen by 93%, from 1.5 billion in 2002 to 103.2 million in April 2024, and the number of people with TT has fallen by 80% in the same time-period, from 7·6 million to 1·5 million.30 As of March 2025, 21 countries have been validated by WHO as having eliminated trachoma as a public health problem: Benin, Cambodia, China, Gambia, Ghana, India, Iraq, Islamic Republic of Iran, Lao People’s Democratic Republic, Malawi, Mali, Mexico, Morocco, Myanmar, Nepal, Oman, Pakistan, Saudi Arabia, Togo and Vanuatu and Viet Nam.121 Seven more countries claim to have met the prevalence criteria for elimination: Botswana, Burundi, Guatemala, Mauritania, Namibia, Papua New Guinea, and Tunisia.30 Although models predict that the majority of EUs will meet the elimination targets by 2030, a small proportion may require additional efforts if the 2030 target is to be met.122,123

In the 2021–2030 NTD road map, the NTD community committed to a shift from siloed disease-specific programmes to holistic, cross-cutting approaches, including integration across NTDs and beyond, and mainstreaming into the national health system.1 Integration and mainstreaming are crucial to a successful and sustainable trachoma elimination programme. In trachoma elimination, integration could include the joint delivery of TT surgical activities with other health care activities, azithromycin MDA with other NTDs’ MDA, F & E interventions co-delivered with other sectors, and integrated monitoring, evaluation and reporting to maximise efficiency. Mainstreaming trachoma initiatives ensures trachoma control and surveillance are embedded in national policies, frameworks, and systems for sustainable, efficient prevention and control.1 It enables patients to access all treatment, care and support that they need, even in the post-elimination era.

Persistent and recrudescent active trachoma coupled with insecurity to operate in several trachoma-endemic settings presently challenge the success of the entire 2030 global elimination target.126 There is growing evidence that in some hyperendemic populations, the elimination threshold of <5% TF prevalence in children aged 1–9 years (TF1-9) is not met despite years of implementation of recommended interventions.127,128 In some hyperendemic areas, the currently recommended single annual community wide antibiotic schedule appears insufficient to reliably achieve long-term control, with re-emergence of disease being typical.129,130 As of June 2024, 253 EUs (16·8% of all ever-endemic districts worldwide) had persistent trachoma, defined as undergoing two or more trachoma impact surveys with TF1-9 never being below 5%. Another 174 districts (10·4% of all ever-endemic districts) had recrudescent trachoma, defined by at least one trachoma surveillance survey having returned a TF1-9 ≥5% (with current prevalence remaining ≥5%).

isease can be detected, which should then be reported to WHO’s Global NTD Programme and noted in the Global Health Observatory and WHO’s Weekly Epidemiological Record.136 WHO does not specify how countries should conduct post-validation surveillance, as the appropriate methodology will be country- and context-specific. As such, different countries have employed different approaches.137,138 Most countries are employing passive surveillance approaches, with TF and TT identification and reporting integrated into national integrated surveillance systems,139,140 with training to ensure accurate detection of cases, and referral systems for the appropriate management of individuals with TT. Some countries are also using active surveillance strategies, such as prevalence surveys and sentinel site monitoring. Furthermore, the use of complementary indicators to detect evidence of current and past C. trachomatis infection is being used, for example in Ghana and Morocco.140,141 Through these efforts, countries are able to detect indications of disease recrudescence, identify the target areas and population groups involved, plan effective delivery of the necessary interventions, and continue to advocate for resources.

PTT is the most important and most frequently observed measure of undesirable surgical outcomes. PTT incidence varies by the type of surgical procedure and follow-up time. Studies have reported a PTT cumulative incidence of 2% at 6 weeks and 60% at 3 years after surgery, with an average of around 20% by 1 year.65,68,131–133 There is a consistent pattern to PTT: an initially high rate during the first six months, followed by a slower rate after six months. A study in Ethiopia reported a PTT rate of 3·5% per month during the first six months, dropping to 0·8% per month between six and 24 months (RR 0·24, p=0·0001).134 PTT is a significant challenge in preventing blindness from trachoma in several ways. First, PTT sustains eye pain and increases the risk of CO and vision loss, negatively impacting quality of life and mental health. Second, PTT deters other patients from seeking out or accepting TT surgery, hampering surgical uptake. Third, management of PTT requires a higher level of expertise than the initial operation, absorbing significant resources within trachoma programmes that are often already overstretched.

Part of the trachoma elimination validation dossier is outlining national plans for post-validation surveillance, including provision of surgical services for incident TT cases, and continued health ministry engagement with other government ministries for the provision of WASH services. Countries must also demonstrate that they are committed to continued surveillance, so that any recrudescent disease can be detected, which should then be reported to WHO’s Global NTD Programme and noted in the Global Health Observatory and WHO’s Weekly Epidemiological Record.136 WHO does not specify how countries should conduct post-validation surveillance, as the appropriate methodology will be country- and context-specific.

Nepal and Ethiopia have had contrasting experiences in trying to eliminate trachoma. Here, we describe some of their successes and challenges to provide locally-grounded examples of overall global progress. In 1981, trachoma was the second commonest cause of preventable blindness nationally, and highly endemic in many parts of the country, with prevalence estimates of active trachoma as high as 23% in several districts. The National Trachoma Program (NTP) was launched in 2002 and conducted population-based trachoma prevalence surveys throughout the country. These surveys identified trachoma as a public health problem in 20 of 75 districts. The NTP adopted an integrated approach to trachoma elimination, with Nepal Netra Jyoti Sangh (NNJS), a national NGO leading the surgical component, the Ministry of Health and Population (MoHP) overseeing antibiotic MDA, and water, sanitation and education partners delivering the “F” and “E” components of SAFE. On 22 November 2018, WHO congratulated Nepal, the first country in WHO’s South-East Asia Region, for eliminating trachoma as a public health problem.

In 1981, trachoma was the second commonest cause of preventable blindness nationally, and highly endemic in many parts of the country, with prevalence estimates of active trachoma as high as 23% in several districts. The National Trachoma Program (NTP) was launched in 2002 and conducted population-based trachoma prevalence surveys throughout the country. These surveys identified trachoma as a public health problem in 20 of 75 districts. The NTP adopted an integrated approach to trachoma elimination, with Nepal Netra Jyoti Sangh (NNJS), a national NGO leading the surgical component, the Ministry of Health and Population (MoHP) overseeing antibiotic MDA, and water, sanitation and education partners delivering the “F” and “E” components of SAFE. On 22 November 2018, WHO congratulated Nepal, the first country in WHO’s South-East Asia Region, for eliminating trachoma as a public health problem. Elimination of trachoma in Nepal had many challenges, including difficult geography, severely limited financial resources and political upheaval. However, the country overcame each issue by applying an integrated and holistic approach, efficient administrative coordination between stakeholders, strong political support, social mobilisation and ownership of the programme by NNJS. Nepal has demonstrated that carefully planned strategies, implemented with the involvement of all technical and social stakeholders, can lead to successful elimination of trachoma.

In Ethiopia, the SAFE strategy has been implemented as a national programme since 2003. More than 1·7 million TT operations have been performed, ~500 million doses of azithromycin have been distributed, and millions of pit latrines built. Thanks to these interventions, significant progress has been made. The mean EU-level TF prevalence fell from 26·2% in 2015 to 9·3% in 2023, a 64·5% reduction. The mean EU-level prevalence of TT fell from 2·07% in 2003 to 0·80% in 2023, a 61% reduction. As of 2023, among 850 districts known to have had a TT prevalence above the elimination threshold at baseline, 132 (15·5%) were below the elimination threshold. Similarly, among 886 districts with a baseline TF prevalence above the elimination threshold at baseline, 320 (36·1%) were below the elimination threshold, Figure 5.

The SAFE strategy has proven effective in eliminating trachoma as a public health problem in several settings. Many countries are expected to be validated as having eliminated trachoma as a public health problem by 2030. However, some countries with hyperendemic trachoma may struggle to achieve elimination by 2030 due to persistent and recrudescent active trachoma and insecurity. Although there is no certainty as to why trachoma persists or recrudesces, in hyperendemic areas, single annual community-wide antibiotic MDA schedules appear insufficient to reliably achieve sustained elimination. In such settings, understanding the context-specific reasons for persistent and recrudescent trachoma should be a key area of research to develop tailored interventions. The use of alternative indicators, such as prevalence of Ct infection and antibodies in children at the community level, may help inform programmatic decisions, particularly in settings with persistent or recurrent active trachoma. The role of other factors, such as Ct strain variability, antibiotic resistance, different host immune responses, suboptimal MDA coverage, micronutrient deficiency or abundance, and inconsistent personal and environmental hygiene need to be studied as potential contributors. The added benefits of additional rounds of MDA, more frequent than annual MDA, and more intensive delivery of F and E interventions should be tested in implementation research. The strong immune responses observed in the Phase I chlamydia vaccine trials are promising, highlighting the need for further research to optimize dosage and delivery methods. Mainstreaming interventions into the primary health care system, maximising efficiency through integrated approaches, and collaboration with other sectors to implement F & E interventions should be considered. Further work is needed on strategies to maximise not only the proportion of TT cases managed and known to the health system but also effectively managed and not requiring further investment in the post-elimination era.