Abstract
Cryptosporidiosis caused by Cryptosporidium spp. is an important parasitic disease that can be life-threatening for children and immunocompromised patients. This systematic review and meta-analysis was designed to determine the prevalence rate of Cryptosporidium infection and related risk factors among the Iranian general population. We searched electronic databases including Google Scholar, PubMed, Science Direct, Scopus and Proquest for articles in English and SID, Magiran, IranMedex, and IranDoc for articles in Persian. Out of 4816 studies identified in the electronic search, 94 articles were eligible for inclusion in the systematic review and meta-analysis. The prevalence rate of cryptosporidiosis by using the random effect model among children, healthy people, and gastroenteritis and immunocompromised patients in Iran was estimated as 3.65, 2.94, 1.29, and 4.54%, respectively. Findings of a phylogenetic analysis inferred by gp60 and 18S ribosomal RNA markers indicated that most of the infection rate belonged to C. parvum (particularly subtype IIaA15G2R1) and C. hominis among understudied groups. The present study is the first systematic review and meta-analysis providing a comprehensive view of the prevalence of human cryptosporidiosis and its related risk factors in Iran. It seems that the awareness of Cryptosporidium prevalence, risk factors, and disease complications may be required for developing effective strategies to prevent infection.
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Introduction
Cryptosporidiosis is caused by an obligate intracellular parasite, which was first known as an opportunistic pathogen in 1907 (Tyzzer 1907). Cryptosporidium infection raises public health concerns in both developed and developing countries. On a global scale, its prevalence seems to be focused on the USA, Canada, Australia, Europe, particularly the UK, Germany, and Ireland (Cacciò et al. 2005; Gallas-Lindemann et al. 2013; Harp 2003; Putignani and Menichella 2010). In 1976, cryptosporidiosis first reported in a rural child and an immunocompromised man (Meisel et al. 1976; Nime et al. 1976). Now, it has been reported in over 90 countries from all continents (Fayer et al. 2000). There are various methods for transmission of this parasite including person to person, animal to animal, animal to human, water-borne, food-borne, air-borne, and sexual transmission (Fayer 2010; Fayer et al. 2000; Karanis et al. 2007; Tzipori and Ward 2002). Initial infection naturally occurs by ingestion of food or water contaminated with oocysts. Consequently, Cryptosporidium is identified as a main cause of food-borne and water-borne outbreaks (Chalmers and Davies 2010; Karanis 2006; Putignani and Menichella 2010). This protozoan parasite has several species that infect different hosts, but some of them are zoonotic (Xiao 2010). Cryptosporidiosis mainly occurs in people at risk including children, malnourished persons, elderly people, and a vast range of immunocompromised patients such as those suffering from AIDS and malignancies as well as transplant recipients (Aldeyarbi et al. 2016; Fayer et al. 2000; Shirley et al. 2012). This infection usually causes self-limiting diarrhoea in healthy people, although it could be life-threatening with a serious gastroenteritis-like syndrome in children (under 2 years of age), elderly people, and immunocompromised patients (Plutzer and Karanis 2009; Rossle and Latif 2013; Skotarczak 2010). This parasite is the main cause of acute gastroenteritis and abdominal pain with a duration of several days to weeks (Chalmers et al. 2011; Hunter and Nichols 2002; Insulander et al. 2005). Non-gastrointestinal symptoms including cholecystitis, hepatitis, and respiratory diseases also occur in immunocompromised patients (Hunter and Nichols 2002; Shirley et al. 2012). Cryptosporidium infection causes more economic losses to animal husbandry and livestock production. In addition, contact with animals seems to be a significant source of the infection, mainly in rural areas (Ghenghesh et al. 2012; Mahami Oskouei et al. 2014; Snelling et al. 2007). Several methods are available for laboratory diagnosis of cryptosporidiosis; they include staining and serological techniques such as the complement fixation test (CF), indirect haemagglutination test (IHA), indirect immunofluorescence assay (IFA), and the enzyme-linked immunosorbent assay (ELISA). It should be noted that recently advanced methods, such as polymerase chain reaction (PCR), loop-mediated isothermal amplification (LAMP), and western blot have also been used (Fayer et al. 2000; Mahmoudi et al. 2013; Skotarczak 2010; Tavares et al. 2011). Given the importance of cryptosporidiosis among human population, a summary and an analysis of the information on infection rates in a region can be helpful to understand its epidemiological aspects. In the present systematic review, we have studied papers on Cryptosporidium infection to more accurately estimate the prevalence rate of human cryptosporidiosis in Iran.
Materials and methods
Search strategy
We searched electronic databases including Google Scholar, PubMed, Science Direct, Scopus and Proquest for articles in English and SID, Magiran, IranMedex, and IranDoc for articles in Persian. Both English and Persian language articles were included in this study. After searching databases, another round of manual searching was conducted. The selection was made from articles written from 1990 to 2015. Our search strategy applied the following key words: cryptosporidiosis, Cryptosporidium, Cryptosporidium spp., Cryptosporidium parvum, Cryptosporidium hominis, C. parvum, C. hominis, Iran, Islamic Republic of Iran, human, cancer, transplant recipient, HIV, AIDS, immunocompromised patients, healthy people, gastroenteritis patients, intestinal parasite infections, epidemiology, and prevalence. We also used the proposed synonymous terms for our search.
Study selection
Inclusion criteria: publication of articles in 1990 to 2015, descriptive, cross-sectional, case-control, and epidemiology studies and articles published in English and Persian. We chose those studies that described the total prevalence rates for Cryptosporidium and cryptosporidiosis.
Exclusion criteria: articles with had different diagnostic methods, unavailable full text, and written in a language other than English or Persian. Congress articles that were not published in valuable journals were also excluded.
All searched studies from the databases were considered for suitability by three different authors. Disagreements were resolved through discussion and consensus.
Data extraction and analysis
After precise extraction of information, the extracted results were classified in a table constituted of province, year of publication, participation, gender of positive cases (male/female), diagnostic methods (serology/PCR/staining), and age. Actual estimates of prevalence were evaluated with 95% confidence intervals (CI). Entire prevalence and group-specific prevalence were considered with the help of age groups (<15, 16–30, >30 years), gender (male/female), and geographical region. A forest plot was used to indicate the heterogeneity among the studies. The statistical methods I2 and Cochran’s Q tests (P value < 0.05) were used to quantity the differences. The meta-analysis was done by using the trial version of StatsDirect statistical software and the random effects model with the assumption that the included studies were a random sample from a population of studies. In order to illustrate the taxonomic status of Cryptosporidium spp., sequences of glycoprotein 60 (gp60) and 18S ribosomal RNA (rRNA) markers of Iran were directly retrieved from the GenBank database (FASTA format). MEGA 5.05 software based on the maximum likelihood algorithm with the Kimura 2-parameter model was used to construct the phylogenetic tree. The accuracy of the phylogenetic tree was evaluated by 1000 bootstrap resamplings.
Results
Among the 4816 studies identified in the electronic search, 94 articles were eligible for inclusion in the systematic review and meta-analysis. A flowchart shows the study design process (Fig. 1). Table 1 shows the results of the literature search. A wide variation was observed in the prevalence estimates among the various studies, and the Q statistic was (Q statistic = 465.496, df = 37, P < 0.0001; I2 = 92.1%), (Q statistic = 414.990, df = 23, P < 0.0001; I2 = 94.5%), (Q statistic = 206.468, df = 13, P < 0.0001; I2 = 93.7%), and (Q statistic = 215.106, df = 23, P < 0.0001; I2 = 89.3%) in children, healthy people, and gastroenteritis and immunocompromised patients, respectively. The prevalence rate of cryptosporidiosis by using the random effect model among children, healthy people, and gastroenteritis and immunocompromised patients in Iran over the 24-year period was estimated to be 3.65% (95% CI = 2.72–4.71%), 2.94% (95% CI = 1.45–4.93%), 1.29% (95% CI = 0.58–2.29%), and 4.54% (95% CI = 2.89–6.53%), respectively. The forest plot diagrams of the current study are shown in Figs. 2, 3, 4, and 5. In this study, we could not estimate the overall prevalence rate in the other groups because there were not enough related articles to analyse and it has not been widely studied in Iran. Among the studies, three different diagnostic methods were utilized to evaluate Cryptosporidium infection in general population. They were staining (mZN and auramine phenol), serology (ELISA, IFA, and direct immunofluorescence), and PCR. The most commonly used diagnostic methods for cryptosporidiosis in the general population of Iran were mZN (89 studies), followed by PCR (17 studies), and serology (nine studies). Results of the meta-analysis showed a significant difference between groups of stool appearance (P < 0.001) and also season (P = 0.001). The prevalence of Cryptosporidium infection was significantly higher in autumn and patients with diarrhoea (Table 2). Results of the heterogeneity of the meta-analysis for other factors (gender, age, residency, and contact with animals) revealed that they were homogeneous (P > 0.05). The prevalence rate of cryptosporidiosis in the general population of several provinces of Iran is shown in Fig. 6. The prevalence range of human cryptosporidiosis in various regions of Iran was between 0.83 and 24% in Guilan and Yazd provinces, respectively. The phylogenetic analysis inferred by gp60 and 18S rRNA markers indicated that the majority infection rate belonged to C. parvum (especially subtype IIaA15G2R1) and C. hominis among understudied groups (Fig. 7).
Discussion
Cryptosporidium is one of the important causes of diarrhoea occurring mostly in developing countries (El Kader et al. 2012; Leav et al. 2003; Shirley et al. 2012). Different epidemiological studies on the prevalence of cryptosporidiosis are available nowadays. The present systematic review and meta-analysis is the most comprehensive and first estimate of human cryptosporidiosis in Iran. On the other hand, previous studies done on this subject were more limited to specific groups and restricted areas. These data can be used to evaluate prevalence of cryptosporidium in various parts of Iran and target groups. This study is designed by using nine databases and 94 records published between 1991 and 2015. The prevalence of human cryptosporidiosis varies in different population groups of Iran. However, the rate of infection is higher among immunocompromised patients (95% CI = 2–6%). Therefore, immunocompromised patients are a particularly susceptible group with high prevalence rates of infection and should be placed under surveillance. Many reports from different parts of the world have investigated the prevalence of Cryptosporidium infection. Compared to various regions throughout the world, particularly in developing countries, cryptosporidium prevalence in Iran is moderate. African countries, Central and South American countries, Asian countries, and others in the Pacific and Caribbean areas have the highest prevalence rate of this infection (1.3–31.5%), while North America and Europe report low prevalence rates of cryptosporidiosis (0.1–14.1%) (Cardona et al. 2011; Davies et al. 2009; Fayer 2004; Gatei et al. 2006). The prevalence rate of cryptosporidiosis among immunocompetent individuals was reported to be 0.6–20% and 4–20% in Western and developing countries, respectively (Chacin-Bonilla et al. 1991; Davies et al. 2009; Snelling et al. 2007). In contrast, Cryptosporidium spp. infection among AIDS patients is 3 and 50% in developed and developing countries, respectively (Kumurya and Gwarzo 2013). The results showed that C. hominis is more prevalent in North and South America, Australia, and Africa, while C. parvum is common in Europe, especially in the UK (Aldeyarbi et al. 2016; Putignani and Menichella 2010). The prevalence rate of cryptosporidiosis in the Middle East countries were as follows: in Iraq, the recorded prevalence of Cryptosporidium infection among children with severe diarrhoea and dehydration ranged within 8.6–9.7% (Latif and Rossle 2015). However, a similar investigation using both direct wet mount and modified Ziehl-Neelsen staining has indicated that the highest and lowest rates were found in Baghdad (14.6%) and Babylon (2.2%), respectively (Latif and Rossle 2015). In another study at Erbil City, Kurdistan region, Iraq, 14% of all samples were detected positive by direct wet mount and modified Ziehl-Neelsen methods (Koyee and Faraj 2015). A study on children with diarrhoea, which uses modified safranin-methylene blue staining, in Kuwait indicated that 10% of cases were positive for Cryptosporidium spp. (Iqbal et al. 2001). In addition, Iqbal et al. showed that 3.4% of children with diarrhoea aged between 6 months and 16 years in Kuwait were found to be infected by C. parvum (Iqbal et al. 2011). It should be noted that owing to common borders, similar climatic and demographic conditions, and proximity of Iraq and Kuwait, the infection rate of Cryptosporidium was almost the same. The prevalence rate of cryptosporidiosis among diarrhoeal patients in Saudi Arabia was determined to be 9.4% by using wet mount stained with the modified mZN method (Hawash et al. 2014). In another study from Saudi Arabia, Cryptosporidium infection has been reported in 4.7 and 32% of asymptomatic and symptomatic children under 5 years old, respectively (Al Braiken et al. 2003). Although the overall prevalence of Cryptosporidium infection in Iraq, Kuwait, and Saudi Arabia is almost the same with Iran, but it seems that the infection rate is lower in the Iranian children. In Yemen, during 2006–2007, among a total of 712 faecal samples of children with different ages, 34.7% were found positive for this parasite (Al-Shamiri et al. 2010). In another study from Yemen, the prevalence of Cryptosporidium infection was reported to be 1–50% (Alyousefi et al. 2013). In contrast to the results of studies in Iran, cryptosporidiosis is higher in Yemen. The infection rate among children under 5 years in Peshawar, Northwest Pakistan, was reported to be 9% (Mumtaz et al. 2010). In addition, the infection rate in immunocompetent adults with acute diarrhoea was determined as 55% in Karachi, Pakistan, by using the modified acid fast-staining method (Ali et al. 2014). In Turkey, out of 707 faecal samples obtained from elementary school students, four (0.6%) were tested positive for Cryptosporidium spp. (Otağ et al. 2007). In the another study in Turkey, Cryptosporidium oocysts were found in 7.1% (161 of 2281) from patients who were admitted with the gastrointestinal complaints (Karaman et al. 2015). Although the prevalence rate of human cryptosporidiosis among the Iranian population is low compared to neighbouring countries, it seems that the epidemiology of this parasitic infection in Iran is somewhat similar to its western neighbours, which may be due to the similarities in socio-economic status, health policy, and the climate conditions.
The phylogenetic analysis demonstrates that C. parvum (especially subtype IIaA15G2R1) and C. hominis are unequivocally circulating among children and immunocompromised populations in Iran. Moreover, the prevalence of C. parvum compared to C. hominis has been reported to a large extent. Furthermore, findings showed that gp60 has more potential than 18S rRNA for identification of subtypes of Cryptosporidium spp. The results of a study conducted in Kuwait showed that C. parvum is the most commonly identified species in children. Furthermore, the majority of the C. parvum isolates belonged to subtypes IIa in that study (Iqbal et al. 2011), and its results are consistent with our results. Also, similar results have been reported by Mahgoub et al. from Jordan and Mahdi et al. from Iraq. In these studies, C. parvum is the most common zoonotic species among humans (Mahdi and Ali 1999; Mahgoub et al. 2004). Other studies have been conducted with similar findings in other areas of the developing and developed world such as South Africa, India, Netherlands, the UK, and the USA (Feltus et al. 2006; Gatei et al. 2007; Leav et al. 2002; Leoni et al. 2006; Wielinga et al. 2008).
There are many various risk factors that could play a role in the development of cryptosporidiosis among different populations. These include foreign travel, especially from endemic countries, season, geographic location, contact with infected individual or animals (particularly calves), and accidental ingestion of contaminated water during swimming (Cacciò and Putignani 2014). It is also noteworthy that there is a relationship between risk factors and Cryptosporidium species. For instance, the most known risk factor for C. parvum is to be in contact with animals, while the major risk factor for C. hominis is diaper changing in diaper-aged children (even those with no diarrhoea) that spreads the parasite to others (Bouzid et al. 2013; Cacciò and Pozio 2006). Given these risk factors, a substantial number of individuals are exposed to the risk of being infected with Cryptosporidium. These groups include members of the medical staff at children’s medical centres, childcare workers, parents of infected children, farmers, and people travelling abroad to endemic countries. On the other hand, in most cases, immunocompromised patients and children are more at risk than other groups. Results of the present systematic review indicate that the prevalence rate of Cryptosporidium infection is different among various populations. Data analysis disclosed that immunocompromised patients and children are two groups with the highest prevalence rate of cryptosporidiosis in Iran. In this regard, our findings are consistent with most studies conducted around the world, which indicates a high prevalence in these high-risk groups. In line with the study conducted in Iraq (Rahi et al. 2013), our results indicate that the infection rate is a slightly higher in men (4.6%) than women (3.9%), but this difference is not statistically significant. This difference is probably the result of greater exposure to risk factors, such as occupational reasons in the Iranian males. Although the infection rate is relatively high in the young age group (16–30 years old) than the age groups of >30 and <15 years, we did not find any statistically significant relationship between age and the rate of infection. Similarly, in Nicaragua, no reported correlation between age groups and the prevalence rate of cryptosporidiosis. (Muñoz-Antoli et al. 2011). In contrast, results of an epidemiological study in Ireland showed that younger age groups (82%) had significantly higher prevalence than older age groups (18%) (Garvey and McKeown 2009). Residency is another factor related with cryptosporidiosis, which should be taken into consideration. Our results show that Cryptosporidium prevalence in urbanites was higher than those who live in rural areas. It should be noted that Iran is a tropical country with a long summer, and thus the swimming season increases in recreational centres such as swimming pools, beaches, lakes, and rivers. Of course, migration of villagers to cities and keeping pets, such as dogs and cats, may also contribute to the high prevalence of cryptosporidiosis in urban areas. Similar results have been reported in Tunisia (Rym et al. 2007). Based on the results of a study in North Cumbria, England, no relationship was found between the prevalence of cryptosporidiosis and contact with animals (Goh et al. 2004). An analysis of the present review also indicates the lack of such relationship. Studies conducted in Iran showed that diarrhoea is the most common clinical sign of cryptosporidiosis in both healthy people and immunocompromised patients. They are similar to the study done in Turkey and are different from the ones conducted in Nicaragua (Muñoz-Antoli et al. 2011; Yilmaz et al. 2008) although it should be noted that diarrhoea is self limited in most immunocompetent individuals. Previous investigations reported a correlation between seasons and cryptosporidiosis (Jagai et al. 2009; Lake et al. 2005). According to our analysis, there was such a relationship and so the high prevalence of infection was observed in autumn (10%) and summer (6%). Climate change is a significant challenge to global health in this century (Lal et al. 2013). Concurrent with rainfall and the subsequent water flow, Cryptosporidium oocysts in animal manures can easily get transferred to surface water (Lake et al. 2005). On the other hand, warm temperature is one of the most critical parameters to increase the prevalence of cryptosporidiosis. Temperature can be one of the most important triggers of excystation (Cacciò and Putignani 2014). Our results revealed that the rate of Cryptosporidium infection in Iran have a wide range between 0.83–24%. This could be due to climatic variation in different geographical areas of Iran. Based on our analysis in Iran, the maximum prevalence of Cryptosporidium infection has been observed in Razavi Khorasan, Yazd, Bushehr, and Kurdistan provinces. The high prevalence rate of cryptosporidiosis in the southern provinces, particularly Bushehr, is probably related to several factors such as the hot and humid climate. But the high infection rate in Kurdistan and Razavi Khorasan provinces may be due to population density and commuting of infected people from neighbouring countries. However, other factors, such as public health level and access to safe drinking water, should also be considered.
It should be noted that this systematic review has a few limitations. Some of these limitations include: (1) heterogeneous epidemiological findings, (2) not paying attention to some of the related risk factors by most studies, and (3) the lack of similar studies in some provinces. These limitations may affect the overall prevalence rate in the Iranian general population.
Conclusions
The present study is the first systematic review and meta-analysis providing a comprehensive view of the prevalence of human cryptosporidiosis and related risk factors in Iran. More than two thirds of Iran’s provinces have experienced relatively high prevalence (>4%) of this infection among the general population. In addition, infection in high-risk groups, such as immunocompromised patients and children, is highly prevalent. It seems that awareness of Cryptosporidium prevalence, risk factors, and disease complications may be required for developing effective strategies to prevent such infection.
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This study was financially supported by Pediatric Health Research Center, Tabriz University of Medical Sciences, Iran. This is a report of a database from the thesis of Reza Berahmat registered in Tabriz University of Medical Sciences (Thesis number 93/2–4/19).
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Reza Berahmat and Adel Spotin contributed equally to this work.
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Berahmat, R., Spotin, A., Ahmadpour, E. et al. Human cryptosporidiosis in Iran: a systematic review and meta-analysis. Parasitol Res 116, 1111–1128 (2017). https://doi.org/10.1007/s00436-017-5376-3
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DOI: https://doi.org/10.1007/s00436-017-5376-3