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      Cyclospora and Cyclosporiasis: The Nepalese Perspective

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            Abstract

            Cyclosporiasis is an emerging disease that is ubiquitous in humans and other animals worldwide. Cyclospora cayetanensis, which is distributed in the tropical and subtropical regions, and endemic in several developing countries, is the only species of Cyclospora resulting in cyclosporiasis in humans. The main objective of this review was to summarize the prevalence of Cyclospora in humans, animals, and environmental samples in Nepal. The overall prevalence of Cyclospora in humans has been reported to be 10.3% (3,785/36,570), including 3.6% (60/1,640) among HIV immunocompromised cases, 2.1% (210/9,733) among children, and 13.9% (3,515/25,197) in humans of all age categories, while the prevalence was calculated to be 2.9% (29/983) and 10.5% (9/85) in domestic and wild animals, respectively. The molecular characterization data on Cyclospora as related to Nepal is limited to a very few positive isolates from humans, dogs, chickens, and monkeys. Exposure to sewage water and contaminated fresh food items, and the presence of domestic animals appear to have been associated to an outbreak of Cyclospora in humans. Considering Cyclospora spp. as the etiologic agent for diarrhoea, a comprehensive, wider scale molecular epidemiologic study in humans, animals, and environmental samples is warranted to elucidate the exact distribution loci and probable outbreak of cyclosporiasis in Nepal.

            Main article text

            INTRODUCTION

            Cyclospora spp. are important medical and veterinary zoonotic enteric protozoan parasites in humans and a wide range of animals. C. cayetanensis, an emerging food- and water-borne enteric pathogen, has a one-host fecal-oral transmission resulting from the ingestion of sporulated oocysts through contaminated food and/or water [1]. C. cayetanensis is endemic in tropical and subtropical regions [2,3], and the only human pathogenic species of the genus Cyclospora [4]. The other species within the genus, Cyclospora, result in infections in a wide array of animals from arthropods to non-human primates [57]. Based on various animal samples, including myriapodes, vipers, moles, rodents, monkeys, and humans, 22 Cyclospora spp. have been documented [8,9].

            The first publication on human cyclosporiasis dates back to 1979 [10] as a case report. C. cayetanensis has gained attention in the wake of first outbreak of Cyclospora-associated diarrhoea in the US in 1990 [11]. C. cayetanensis infection is characterized by prolonged diarrhoea, malaise, nausea, cramping, and anorexia in humans [12,13]. The typical watery diarrhea in cyclosporiasis may last for several weeks and even months, and it may manifest more severe symptoms in young children and immunocompromised persons [14]. Among the high-risk groups of people contracting Cyclospora infection are those living with severe immunocompromised state like HIV/AIDS [15]. C. cayetanensis is considered to be an opportunistic pathogen in humans [16], and it has been documented from at least 54 countries [9].

            The diagnostic stage of Cyclospora spp. is the sporulated or non-sporulated cyst. Microscopy with an emphasis on morphology or autofluorescence of oocysts is the common method to detect C. cayetanensis. However, these methods based on parasite morphology differ in diagnostic performance with respect to specificity and sensitivity, and may lead to false-positive or -negative results [9,17]. To overcome this limitation, several molecular methods, including real-time qPCR assay targeting the 70 kDa heatshock protein (HSP70) gene [18], 18S rDNA [19], SSU rRNA sequence analysis [1,20,21], multilocus sequence typing (MLST), and population genetic analysis based on several mini- and micro-satellites [22], and different molecular markers, such as single locus, mt and MLST markers [23], have been used to link and track the sources of contamination.

            Most Cyclospora-related infections have been recorded in travellers from various endemic regions [24], including Nepal, and the consequence is traveller’s diarrhoea. Several instances of cyclosporiasis among travellers to Nepal [2530] might be attributed to consumption of contaminated food and/or water while in Nepal. Nepal is one of the endemic regions for cyclosporiasis. Some studies involving Cyclospora infections in Nepal have been published in local journals, which are less accessible to the global scientific community. This review was intended to summarize the overall prevalence of Cyclospora in humans, animals, and environmental samples, and to identify the epidemiologic risk factors, research gaps, and further research prospects involving Cyclospora in Nepal.

            METHODS

            Search strategy

            Relevant papers reporting the prevalence of Cyclospora infections in Nepal published in the English language until 31 July 2023 were searched using various databases (PubMed, Web of Science, ResearchGate, ScienceDirect, and Google Scholar) with the following search terms: “Cyclospora”; “cyclosporiasis”; “epidemiology”; “diagnosis”; “Nepal”; and combinations of the preceding terms. We extensively searched Nepal Journals Online (NepJOL) [https://www.nepjol.info] to identify articles published in local journals. In addition to the online databases, the reference lists of the published papers were manually searched for appropriate references. Information, including first author, year of publication, study location, study design, number of samples, human participant gender ratio, types of animals studied, environment samples, diagnostic methods, and prevalence of Cyclospora, were independently extracted by two authors.

            Inclusion and exclusion criteria

            Considering the lack of exclusive molecular prevalence studies involving Cyclospora in Nepal, full-length papers, short communications, abstracts based on cross-sectional studies, and clinical and cohort studies with explicit mention of the sampling location, sample size, detection methods, and positive results in humans, animals, or environment samples were included in the analysis (Fig 1). Review papers were not included in the analysis.

            FIGURE 1 |

            Flowchart of the publication screening.

            RESULTS AND DISCUSSION

            Study characteristics

            Of the 39 papers included in this review, the highest number of studies on Cyclospora was conducted in humans (32 papers), especially in hospital-seeking patients and were case-control, seasonal prevalence, or cross-sectional studies. Thirteen studies were conducted exclusively among children < 15 years age, 12 studies involved humans of all ages, one study each was conducted exclusively on domestic (goats) and wild animals (Himalayan goral [Naemorhedus goral]), while the remaining studies were conducted in combination with human and environmental samples (soil, water, and fresh vegetables) and/or domestic or wild animals. Notably, no Cyclospora-related studies involving fresh fruit samples in Nepal have been reported. Moreover, an extensive study conducted exclusively with a large sample size on domestic or wild animals or environmental samples is not available. Nevertheless, it is clear that at least some attempts have been made to explore the general prevalence of Cyclospora among humans and their environments. Therefore, specific emphasis on a particular group of samples or a comprehensive study involving humans, domestic animals, wild animals, and the environmental interface need to be conducted to determine the prevalence, burden, and molecular epidemiology of Cyclospora spp. in Nepal.

            Prevalence of Cyclospora infections in humans

            Of the 36,570 human fecal samples analysed based on direct light microscopy of modified acid fast-stained preparations, phase contrast microscopy, differential interference contrast microscopy, UV-epifluorescence microscopy after concentration of oocysts by formalin ether or the Sheather’s sucrose floatation method, and enzyme immunoassay, 3,785 had Cyclospora oocysts (10.3%). The prevalence of C. cayetanensis in humans has been reported to be 3.6% (60/1,640) among HIV-immunocompromised patients, 2.1% (210/9,733) among children < 15 years of age, and 13.9% (3,515/25,197) among humans of all age groups (Table 1, Fig 2). C. cayetanensis is an opportunistic pathogen in humans [16,62] and is common in immunocompromised and immunocompetent individuals; however, C. cayetanensis is more severe in immunocompromised individuals, especially in HIV-infected patients [63]. Cyclospora outbreaks in expatriates residing in developing countries, like Nepal, have been documented. Cyclosporiasis caused by C. cayetanensis, the so-called alga-like organism, has been diagnosed among 55 British expatriates with prolonged diarrhoea in Nepal between June and November 1989 [64]. With respect to the cause of diarrheal illnesses, coccidian-like organisms (CLOs) have been detected among travellers and foreign residents in Nepal [65]. Scaglia et al. [25] reported co-infection with Cyclospora spp. and Cryptosporidium parvum in a 33-year-old AIDS patient with diarrhea who lived in Nepal between 1987 and 1989. Based on a cohort study conducted among expatriate adults with diarrhea who resided in Nepal for < 2 years, Cyclospora was identified as one of the causes [26]. Cyclospora oocysts were isolated from British travellers who became ill in Nepal in 1989, and other travellers and foreign nationals who resided in Nepal in 1993 [27]. C. cayetanensis was detected in a 39-year-old man who travelled from Tibet to Nepal with prolonged diarrhoea, abdominal discomfort, and significant weight loss [28]. In a case-control study conducted in Nepal among visitors or residents from high socioeconomic countries, Cyclospora was detected in 8.1% (31/381) of the cases, especially during the monsoon season [29]. Cyclospora was also detected in a female traveller who had been travelling around Nepal for approximately 4 months [66]. In another study, 3 of 8 South Korean travellers (46–61 years of age) who returned from Nepal were diagnosed with C. cayetanensis infections based on nested PCR, followed by sequencing of an 18S rRNA gene [30]. Such examples of Cyclospora infections among travellers associated with Nepal might be linked to the consumption of contaminated food and/or water, indicating that Nepal is one of the endemic regions for Cyclospora infection outbreaks.

            FIGURE 2 |

            An epidemiologic map showing the Cyclospora-prevalent districts in humans in Nepal. The original sample map was obtained from the Survey Department of the Government of Nepal and Ministry of Land Management (https://dos.gov.np).

            TABLE 1 |

            Cyclospora detected in different categories of humans (HIV immunocompromised cases, children, and common humans).

            Target groupsLocationSample numberGender ratioAgeDiagnostic methods(%) PrevalenceReferences
            HIV casesSRTIDH, Kathmandu8616-55YModified AF stain19.7%; 17/86[31]
            TUTH, Kathmandu200M:108; F:72NAZN stain (Kinyoun’s method)4.0%; 8/200[32]
            Kathmandu146M:61; F:8520-45YModified ZN stain4.1%; 6/146[33]
            NPHL, Kathmandu745NA30 (median age)Wet mount, formalin ether sedimentation, AF stain1.8%; 14/745[34]
            TUTH, Kathmandu112M:65; F:4715-64YFormalin ether concentration, Sheather’s sucrose floatation, modified AF stain (Kinyoun’s)7.1%; 8/112[35]
            NPHL, Kathmandu202NANAFormal-ether concentration, Sheather’s sucrose floatation, modified AF stain (Kinyoun’s)0.9%; 2/202[36]
            Morang, Sunsari149M:86; F:631-60YModified AF stain3.3%; 5/149[37]
            HIV cases total prevalence3.6%; 60/1,640
            ChildrenKathmandu124M:82; F:42<5YDirect microscopy, modified AF stain, formal-ether concentration5.0%; 6/124[38]
            Kathmandu103M:67; F:36<5Y2.0%; 2/103
            KCH, Kathmandu195<15YWet mount, modified ZN stain0.0%; 0/0[39]
            KCH, Kathmandu195<15Y19.0%; 37/195
            MTH, Pokhara1,790M:1047; F: 743<15YWet mound, iodine stain, Kinyoun’s stain1.0%; 18/1,790[40]
            MTH, Pokhara253M:147; F:106<5YZN stain0.7%; 2/253[41]
            Hospitals, Kathmandu440<11YModified ZN stain, sucrose floatation7.2%; 32/440[42]
            BPKIHS, Dharan863<15YModified ZN stain0.2%; 2/863[43]
            Slum areas Kathmandu302<15YSheather’s sucrose, Kinyoun’s modified AF stain7.9%; 24/302[44]
            Lalitpur1,392M:732; F:660<15YDirect microscopy, Sheather’s sucrose floatation, formalin ether concentration1.6%; 23/1,392[45]
            Kathmandu5073-14YDirect smear, formalin ether concentration, Kinyoun’s AF stain3.9%; 20/507[46]
            Public school, slum areas and TUTH, Kathmanadu600M:346; F:254<15YSaline mount, iodine mount, formalin ether concentration, Shearher’s floatation, modified AF stain1.0%; 6/600[47]
            NMCTH, Biratnagar588M:347; F:241<15YNormal saline, iodine mount2.0%; 12/588[48]
            KCH, Kathmandu196M:112; F:84≤15YFormalin ether concentration, modified ZN stain4.8%; 8/196[49]
            BH, Bharatpur598 <5YMicroscopy0.2%; 1/598[50]
            597 0.2%; 1/597
            KCH, Kathmandu591 2.0%; 9/591
            594 1.1%; 7/594
            Children total prevalence2.1%; 210/9,733
            Common human
            Pokhara8NANADirect microscopy, formalin ether concentration75.0%; 6/8[51]
            Health care facilities at Kathmandu, Dhanusha2,123M:1386; F:7372M-49YModified AF stain29.8%; 632/2,123)[52]
            Kathmandu6,5622M-70YModified AF stain24.6%; 1,619/6,592[53]
            Kathmandu, Kavre, Rupendehi2,1382-70YDirect light microscopy, modified AF stain, UV epifluorescence6.4%; 137/2,138[54]
            176& NA10.2%; 18/176
            Kathmandu500NA2M-70YDirect light microscopy7.0%; 35/500[55]
            Kathmandu9,000NA>15YModified AF stain8.2%; 739/9,000[56]
            Kathmandu1,397M:883; F:5140-81YDIC microscopy9.2%; 128/1,397[57]
            Sindhupalchok58# NA13-86YDirect microscopy, formalin ether concentration8.6%; 5/58[58]
            Ramechhap78# 2.5%; 2/78
            Various parts of Nepal (not specified)1,842M:846; F:9962-70YFormalin ether concentration, sucrose floatation, phase contrast microscopy7.9%; 146/1,842[59]
            Kathmandu381*>18YMicroscopy, enzyme immunoassay (EIA)8.0%; 31/381[29]
            Kathmandu262M:117; F:145NAFormalin ether concentration, modified AF stain3.8%; 10/262[60]
            Kathmandu433* >18YFormalin ether concentration, microscopy1.0%; 6/433[61]
            209* >18Y0.5%; 1/209
            Common human total13.9%; 3,515/25,197
            Grand total (HIV cases, children, and common humans)10.3%; 3,785/36,570

            &Cohort study among vegetable farmers; #Subjects undergoing cataract surgery; *Study among travellers; Case-control study (diarrhoea cases); Case-control study (non-diarrhoea control); SRTIDH: Sukra Raj Tropical and Infectious Disease Hospital, Teku, Kathmandu; TUTH: Tribhuvan University Teaching Hospital, Maharajgunj, Kathmandu; NPHL: Nepal Public Health Laboratory, Kathmandu; KCH: Kanti Children’s Hospital, Maharajgunj, Kathmanadu; MTH: Manipal Teaching Hospital, Pokhara, Kaski; BPKIHS: BP Koirala Institute of Health Sciences, Dharan; NMCTH: Nepal Medical College Teaching Hospital, Kathmandu; BH: Bharatpur Hospital, Chitwan; NA: Information not available.

            Cyclospora were identified in HIV-infected patients (1.8% [14/745]) [34]; however, Cyclospora was only detected among the HIV patients with CD4 T-cell counts < 200/μL. Combined colonization of Cyclospora and Cryptosporidium is also a common occurrence [46,67]. Co-infections of Cyclospora with other enteric protozoan and helminth parasites have been reported in HIV immunocompromised patients in Nepal [32,35,36]. Cyclospora infections have been reported in all types of populations, regardless the age [68]. In endemic regions, like Nepal, young children are more frequently infected with Cyclospora [38,45,46,59]. In Nepal, several instances have been recorded with C. cayetanensis being more prevalent among children < 15 years of age, however, at varying proportions [48,49,52,54,56,57,59,60]. Gender has not been shown to have a significant influence on the prevalence of Cyclospora infections in various regions [20,69]. Based on this review, there was not a significant difference in the prevalence of C. cayetanensis infections between males (16.42% [1,108/6,747]) and females (16.26% [965/5,932]).

            Cyclospora spp. in domestic animals

            Molecular tools have detected Cyclospora oocysts in the faeces of animals, such as dairy cattle [70], dogs, chickens, and rhesus monkeys [71]. Studies have confirmed that living in the proximity of domestic animals or sharing a similar habitat may pose a risk of sporadic cyclosporiasis in endemic regions [69,72], as evidenced by the contiguity with chickens [31,55,59,72], other birds, guinea pigs, rabbits [73], and livestock [46]. A human-animal nexus in the transmission of Cyclospora oocysts has been reported in Nepal (Fig 3). Because Cyclospora has been detected in some animals, the Cyclospora spp. identified in many domestic animals remains controversial owing to the lack of a sophisticated molecular approach for identification.

            FIGURE 3 |

            Life cycle of Cyclospora and associated risk factors in transmission. The green cycle represents the transmission of C. cayetanensis in humans and the blue cycle indicates the circulation of Cyclospora spp. in animals. It is widely accepted that C. cayetanensis only infects humans [4]. These animals and environmental agents, as mentioned in published papers incorporated in this review, and represented in this picture were investigated for Cyclospora oocysts. The presence of Cyclospora oocysts in the animal faeces does not indicate infection and cannot be considered the reservoir of C. cayetanensis; however, Cyclospora oocysts might act as paratenic hosts [14] to disseminate this pathogen to the surroundings where humans can be infected. A biopsy is the only means by which whether the animals are actually infected can be ascertained.

            This review has summarized the overall prevalence of Cyclospora infections in 2.9% (29/983) different domestic animals investigated in Nepal (Table 2). Among the domestic animals, chickens (2.7% [3/110]), dogs (2.2% [2/90]), and house rats/mice (4.0% [2/50]) shed Cyclospora oocysts [53]. In another study, a varying proportion of chickens (1.7% [1/58]) and dogs (3.8% [2/53]) were shown to have Cyclospora infections [59]. Various species of Cyclospora are capable of infecting different animals. A microscopic examination is considered crucial for the diagnosis of most pathogenic enteric protozoa, including Cyclospora; however, microscopic examinations are labor-intensive and require trained and skilled human resources [75].

            TABLE 2 |

            Cyclospora detection in domestic animals in Nepal.

            LocationAnimalsSample numberDiagnostic methods(%) PrevalenceReferences
            Kathmandu, Dhanusha Chicken35Modified AF stain5.7%; 2/35[52]
            Kathmandu, Lalitpur (Patan), Bhaktapur Chicken75Modified AF stain4.0%; 3/75[53]
            Dogs623.2%; 2/62
            Rat/house mice277.4%; 2/27
            KathmanduChickens23Direct microscopy, sedimentation, floatation techniques4.3%; 1/23[55]
            Kathmandu, Kavre, Rupendehi Chickens72Direct light microscopy, modified AF stain, UV epifluorescence4.2%; 3/72[54]
            Dogs785.1%; 4/78
            Rats682.9%; 2/68
            KathmanduChickens19Modified AF stain10.5%; 2/19[31]
            Dogs137.6%; 1/13
            Various parts of Nepal (not specified)Chickens58Formalin ether concentration, Sheather’s sucrose floatation, phase contrast microscopy1.7%; 1/58[59]
            Dogs533.8%; 2/53
            KathmanduGoats400Direct wet mount, saturated salt floatation, modified AF stain1.0%; 4/400[74]
            Total prevalence2.9%; 29/983

            The specific number of samples from each district not mentioned.

            Cyclospora spp. in wild animals

            Cyclospora oocysts have been identified in monkeys [54,59] and Himalayan goral [76] (Table 3) in Nepal. According to one review [14], some attempts have been successful in infecting oysters, Asian fresh water clams, Swiss albino mice, and guinea pigs through artificial inoculation of C. cayetanensis oocysts. Based on the appearance of oocysts in the faeces, it cannot be concluded that the animals are infected by Cyclospora. This finding simply implies that the parasite must have colonized the gut [77] and is released outside the animal without resulting in an infection. However, it should not be overlooked that animals can potentially contribute as paratenic hosts for dissemination of C. cayetanensis oocysts by mechanical spread, which results in contamination of water resources and food, leading to possible infection of humans [14].

            TABLE 3 |

            Cyclospora detection in wild animals of Nepal.

            LocationStudy animalsSample numberDiagnostic methods(%) PrevalenceReferences
            Kathmandu, Kavre, Rupendehi Monkeys35Direct light microscopy, modified AF stain, UV epifluorescence5.7%; 2/35[54]
            Various parts of Nepal (not specified)Monkeys31Formalin ether concentration, sucrose floatation, phase contrast microscopy6.5%; 2/31[59]
            TanahuHimalayan goral19Modified AF stain26.3%; 5/19[76]
            Total prevalence10.5%; 9/85

            The specific number of samples from each district not mentioned.

            Seasonality of cyclosporiasis

            Cyclosporiasis caused by C. cayetanensis has a marked seasonality [20,78,79]; however, the seasonality effect is deferred in various regions, owing to anthropogenic habits, chances of environmental contamination, and optimal circumstances required for sporulation [80]. The prevalence of Cyclospora in Nepal also has a seasonal pattern. A marked higher prevalence of Cyclospora infections has been observed in summer months (rainy season, 12.6%) with a sharp decline in the spring (dry season, 1.8%) and closely related to the amount of precipitation [57]. Cyclospora contamination has been recorded in June and July in water samples of ponds and irrigation canals [59]. In a study conducted among Nepali children (1 month to 15 years of age) to determine the seasonality of Cyclospora prevalence, oocysts were only detected during the monsoon season (July and August) with a prevalence of 19.0% (37/195); however the prevalence was zero in the pre-monsoon season (April and May) [39]. In another study, of 2,138 human faecal samples, a higher prevalence of Cyclospora (26.3%) was recorded in June and < 1.0% in winter months (December, January, and February) [54]. The monthly prevalence of Cyclospora was noted to be higher from May (3.6%) to July (12.09%) with a decline in October (3.8%) [55]. Similarly, Ghimire et al. [56] noticed a rise in Cyclospora prevalence from May to July, followed by gradual decline until November 2002. The highest prevalence of Cyclospora was recorded in June 2003 and 2004. The summer/rainy season (June and July) had the highest infection rate [59], which had an increasing trend from May to July and a gradual fall [56]. The prevalence of Cyclospora infections peaked in June and July [53], June to August [57], and August [49].

            Environmental risk factors

            Surveillance studies in endemic areas have reported C. cayetanensis contamination in fresh produce [80]. Both food-producing and -importing countries have experienced an increased occurrence of cyclosporiasis due to the globalized human food supply [69,81]. A review indicated that different types of human pathogenic enteric protozoan parasites (amoebae, microsporidia, and coccidia), including C. cayetanensis, have been isolated from various types of raw vegetables and fruits worldwide [82]. Cyclospora oocysts have been identified in sewage water and some vegetable items, such as cabbage, lettuce, and mustard leaves collected from various areas in Kathmandu valley [53]. In several other parts involving Nepal, raddishes, cauliflower, cabbage, lettuce, spinach, mustard, and basil leaves were shown to contain Cyclospora oocysts [52,56,59] (Table 4).

            TABLE 4 |

            Evidence of Cyclospora contamination in various environmental samples in Nepal.

            LocationSample sourceSample numberDetection method(%) PrevalenceReferences
            PokharaChlorinated waterNADirect microscopy, formalin ether concentrationNA[51]
            Kathmandu and other endemic partsDrinking water, sewage water, cabbage, lettuce, mustard leavesNANA[52]
            Kathmandu, Lalitpur (Patan), BhaktapurSewage water, cabbage, lettuce, mustard leavesNANA[53]
            Kathmandu, Kavre, RupendehiCabbage47Direct light microscopy, modified AF stain, UV epifluorescence4.2%; 2/47[54]
            Lettuce674.5%; 3/67
            Spinach387.9%; 3/38
            Mustard leaves563.6%; 2/56
            Sewage water2619.2%; 5/26
            Irrigation canal119.0%; 1/11
            KathmanduWater500Modified AF stain1.4%; 7/500[56]
            Radish, cauliflower, cabbage, mustard leavesNANA
            Kathmandu valleySoil45Modified AF stain8.8%; 4/45[31]
            River water128.3%; 1/12
            Sewage922.2%; 2/9
            Street faeces946.3%; 6/94
            Various parts of Nepal (not specified)Irrigation canal8Direct microscopy, formalin ether concentration

            		25.0%; 2/8[59]
            Pond water128.3%; 1/12
            Lettuce, spinach, basil leaves, mustard leavesNANA

            NA: Sample number and prevalence not provided; only presence of Cyclospora was mentioned.

            Cyclospora spp., along with C. cayetanensis, have been detected in different types of wastewater treatment plants [83], as well as influent and effluent wastewater samples [84] in some developed countries. Therefore, drinking or irrigation water is potentially contaminated by the oocysts carried along with wastewater. Cyclosporiasis can even be attributed to exposure to recreational water contaminated with C. cayetanensis oocysts [85]. In Nepal, water samples from irrigation canals and ponds have also been shown to contain Cyclospora oocysts, mainly in June and July [59]. This finding indicates a health threat of contracting cyclosporiasis in the community by contaminated foods. A study was conducted involving the Cyclospora prevalence among HIV patients in relation to the probable environmental risk factors in and around their residences [31]. Ghimire et al. [31] identified Cyclospora oocysts from sewage, river water, soil samples, and human faecal samples collected from the streets and some domestic animals, like chicken and dogs. In a study conducted in rural settings in various parts of Nepal, the highest risk groups for Cyclospora infection were children and students [59]. Similarly, the higher prevalence in children 3-5 years of age (10.15% [13/128]) with a peak in August have been attributed to the presence of livestock and consuming fresh produce without proper washing [46]. Exposure to the soil is another important means of transmission of C. cayetanensis, and thereby contributes to food contamination [8688] because disposal of faeces is considered to be evidence of soil contamination. Therefore, sewage drainage, presence of domestic animals (mainly chickens) in the household, and contact with the soil, irrigation water, and some wild animals, like monkeys, could potentially be potential risk factors for transmission of cyclosporiasis (Fig 2). Indeed, studies tracking the sources and possible routes of transmission of Cyclospora to humans and animals need to be conducted in various endemic locations within the country.

            Molecular characterization of Cyclospora spp.

            A molecular analysis of Cyclosporia-positive faecal specimens of humans, dogs, chickens, and monkeys obtained from Nepal has been carried out in international laboratories (Table 5). Even though C. cayetanensis was confirmed in two dogs, and one each in chicken and monkey faecal samples, these animals cannot be designated as the natural reservoir hosts without evidence of biopsy analysis [71]. In a sequence analysis of the HSP70 gene to characterize six human C. cayetanensis isolates supplied from Nepal, genetic polymorphisms were not demonstrated among the isolates at the target locus [89]. Considering the 18S rRNA locus in the follow-up study of Sulaiman et al. [89], evidence supported the lack of geographic separation and existence of genetically homogenous population of C. cayetanensis [18]. Cinar et al. [90] performed an apicoplast genome sequence analysis for the C. cayetanensis-positive specimens provided by the Tribhuvan University Teaching Hospital in Kathmandu. Only three C. cayetanensis-positive specimens obtained from Nepal were included in the population genetic characterization, two of which had complete multi-locus sequence typing (MLST) and were found to be genetically more aligned to the specimens under investigation from Peru and the United States [91]. The number of human and animal faecal specimens and the diversity of animals included in the molecular characterization of Cyclospora spp. are very low in context to Nepal. It is worthwhile to get a broader consensus between the responsible authorities to elucidate the geographic distribution and molecular epidemiologic investigation of C. cayetanensis in humans and Cyclospora spp. in a wide array of domestic and wild animals.

            TABLE 5 |

            Molecular studies on Cyclospora positive samples/isolates.

            HostSample numberSampling locationIsolate IDMethod(%) PrevalenceIdentificationGenBank reference no.References
            Dog14Kathmandu, Kavre (Panchkhal), Dhading (Trishuli)NAFormalin ethyl acetate concentration, DIC microscopy, UV epifluorescence microscopy, multiplex PCR, RFLP14.2%; 2/14 C. cayetanensis NA[71]
            Chicken333.3%;; 1/3 C. cayetanensis
            Monkey333.3%; 1/3 C. cayetanensis
            Human5Nepal HMCCNP1PCR and sequencing of HSP70 fragment- C. cayetanensis AY240875[89]
            HMCCNP2
            HMCCNP3
            HMCCNP4
            HMCCNP5
            Human6Nepal▲◊ HMCCNP1Nested PCR, 18S rRNA locus- C. cayetanensis AF111183[18]
            HMCCNP2
            HMCCNP3
            HMCCNP4
            HMCCNP5
            HMCCNP6
            Human3TUTH# Nepal-C5 Nepal-C8 Nepal-C10Apicoplast genome sequence analysis- C. cayetanensis NA[90]
            Human3 Nepal NAPopulation genetic analysis- C. cayetanensis NA[91]

            Specific location within Nepal not specified; A follow-up study for Sulaiman et al. [89] in which the 18S RNA locus of C. cayetanensis was characterized; #Analysis of stool samples supplied by the Microbiology and Public Health Research Laboratory, Tribhuvan University Teaching Hospital, Kathmandu, Nepal; Multilocus sequencing typing (MLST) data obtained in the previous study [22] were analysed.

            PERSPECTIVES AND CONCLUSIONS

            Nepal is facing a dearth of authentic data on the epidemiology and transmission dynamics of Cyclospora spp. owing to the lack of sufficient molecular characterization studies among humans, animals, and environmental samples. Extensive studies on clinical, epidemiologic, and molecular aspects of Cyclospora need to be carried out at the national level to configure the exact status on the basis of which effective prophylactic measures can be implemented against this ubiquitous enteric parasite.

            This review has synthesized and provided a glimpse of Cyclospora and its prevalence in humans, domestic animals, wild animals, and environmental samples in Nepal. The prevalence of Cyclospora infections could be much higher if specific and sensitive molecular techniques were used to carry out the diagnostic procedure. Contaminated sewage water, fresh produce (especially vegetables), exposure to contaminated soil, and the presence of domestic animals could be attributed to be the causes of cyclosporiasis outbreaks in humans. Consideration of Cyclospora as the cause of childhood diarrhea and implementation of routine diagnosis of this parasite for diarrheal stool samples in the hospitals and further molecular characterization could determine the epidemic loci of outbreaks and probable risk management. Comprehensive studies using molecular techniques under the support of public health authorities are necessary to provide significant information regarding the probable circulation of Cyclospora in humans, animals, and environmental samples.

            LIMITATIONS

            Because the molecular prevalence reports on Cyclospora in Nepal are limited, the data incorporated in this review were mainly obtained from studies carried out using microscopic methods.

            CONFLICT OF INTEREST

            The authors declare that they have no competing interests.

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            Author and article information

            Journal
            Journal ID (publisher-id): Zoonoses
            Title: Zoonoses
            Abbreviated Title: Zoonoses
            Publisher: Compuscript (Shannon, Ireland )
            ISSN (Print): 2737-7466
            ISSN (Electronic): 2737-7474
            Publication date (Electronic): 23 February 2024
            Volume: 4
            Issue: 1
            Electronic Location Identifier: e989
            Affiliations
            [1 ]College of Veterinary Medicine, Henan Agricultural University, Zhengzhou 450046, China
            [2 ]International Joint Research Laboratory for Zoonotic Diseases of Henan, Zhengzhou 450046, China
            [3 ]Central Department of Zoology, Tribhuvan University, Kathmandu 44600, Nepal
            [4 ]Department of Biotechnology, Kathmandu University, Dhulikhel 45700, Nepal
            Author notes
            *Corresponding authors: E-mail: lijunqiangcool@ 123456126.com (JL); zhanglx8999@ 123456henau.edu.cn , Tel: 86-371-56990163, Fax: 86-371-56990163 (LZ)
            Article
            DOI: 10.15212/ZOONOSES-2023-0051
            SO-VID: 41df1be0-9e4d-43f8-aa3f-cde4a7260f41
            Copyright © Copyright © 2024 The Authors.
            License:

            This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY) 4.0, which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.

            History
            Date received : 19 November 2023
            Date revision received : 10 January 2024
            Date accepted : 25 January 2024
            Page count
            Figures: 3, Tables: 5, References: 91, Pages: 12
            Funding
            Funded by: Henan Province Scientific and Technological Project
            Award ID: 232102110088
            Funded by: National Key Research and Development Plan Project
            Award ID: 2022YFD1800200
            Funded by: Leading Talents of Thousand Talents Program of Central China
            Award ID: 19CZ0122
            This study was supported by the Henan Province Scientific and Technological Project (232102110088), the National Key Research and Development Plan Project (2022YFD1800200), and the Leading Talents of Thousand Talents Program of Central China (19CZ0122).
            Categories
            Subject: Review Article

            ScienceOpen disciplines: Parasitology,Animal science & Zoology,Molecular biology,Public health,Microbiology & Virology,Infectious disease & Microbiology
            Keywords: environmental samples,animals,humans, Cyclospora

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