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Review

Prevalence of Human Intestinal Entamoeba spp. in the Americas: A Systematic Review and Meta-Analysis, 1990–2022

1
Centro de Estudios Parasitológicos y de Vectores (CEPAVE-CONICET-UNLP), Boulevard 120, La Plata 1900, Buenos Aires, Argentina
2
Facultad de Ciencias Veterinarias, Universidad Nacional de La Plata, 60 y 118, La Plata 1900, Buenos Aires, Argentina
3
Laboratorio de Inmunoparasitología (LAINPA), Facultad de Ciencias Veterinarias, Universidad Nacional de La Plata (FCV-UNLP), La Plata 1900, Buenos Aires, Argentina
4
Centro de Investigaciones Regionales “Dr. Hideyo Noguchi”, Universidad Autónoma de Yucatán, Avenida Itzáes, No. 490 x Calle 59, Centro, Merida C.P. 97000, Yucatan, Mexico
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Pathogens 2022, 11(11), 1365; https://doi.org/10.3390/pathogens11111365
Submission received: 13 October 2022 / Revised: 14 November 2022 / Accepted: 15 November 2022 / Published: 16 November 2022
(This article belongs to the Special Issue Intestinal Parasites Infection)

Abstract

:
Among the seven species of Entamoeba known to infect humans, E. histolytica is widely recognized as a pathogen. It is reported that Entamoeba infections are common in the developing world, but rare in developed countries. The best way to diagnose these protozoan parasites is to detect antigens or DNA in the stool. This study aimed to review the prevalence, distribution, and diagnosis methods of Entamoeba spp. infecting humans in the Americas between 1990 and 2022. A systematic review and meta-analysis were performed, including 227 studies on Entamoeba infections from 30 out of 35 American countries. The pooled prevalence of each species of Entamoeba was calculated using the random-effects model. The assignment of Entamoeba species was mainly performed by microscopy. The most widely distributed and prevalent species was E. coli (21.0%). Of the studies, 49% could not differentiate the species of the Entamoeba complex. The pathogenic species E. histolytica was distributed among 22 out of 30 American countries studied, with a pooled prevalence of 9%. Molecular data on Entamoeba species are still scarce. This is the first study that reviewed and summarized data on the prevalence of this protozoan genera among American countries.

1. Introduction

The genus Entamoeba includes unicellular, anaerobic, and parasitic organisms, which infect humans, nonhuman primates, and other vertebrate and invertebrate species worldwide [1]. To date, this genus includes at least seven species that infect the human intestinal lumen: E. histolytica, E. dispar, E. moshkovskii, E. bangladeshi, E. coli, E. hartmanni, and E. polecki. The first four species have morphologically identical cysts and trophozoites. Although only E. histolytica has been well recognized as a causative agent of intestinal and extraintestinal amoebiasis [2], E. moshkovskii has been described as a potential pathogen by the latest studies [3,4]. Moreover, some strains of E. dispar were able to produce liver and intestinal lesions and E. bangladeshi has been discovered in cyst-containing diarrheal samples [5,6]. On the other hand, infections with E. polecki and E. hartmanni, whose cysts may be confused with immature states of E. histolytica, are rare and/or not associated with any disease [7]. In addition to these species known to infect people, E. nuttalli, which is prevalent in nonhuman primates, was detected in a caretaker at a zoo [8].
Entamoeba histolytica is the pathogenic species responsible for amoebiasis throughout the world [9]. The Global Burden of Disease 2010 Study estimates that amoebiasis accounts for 2.2 million disability-adjusted life years and around 55,500 annual deaths [10,11]. In addition, amoebiasis is common in developing countries and affects predominantly individuals with poor socioeconomic conditions, unhygienic practices, and/or malnutrition [12].
Entamoeba parasites are cosmopolitan, except for E. moshkovskii, which is endemic in Bangladesh, North America, and South Africa, and E. bangladeshi, which has also been found in the last two regions mentioned [5,13,14]. In general, Entamoeba infection is mostly seen in people living or traveling to tropical and subtropical areas (Asia, Africa, India, Indonesia, Mexico, South America, or South Africa) [13,15,16]. Taking into account that some species are indistinguishable by microscopy, a specific and accurate method of diagnosis is required. The identification, diagnosis, and characterization of Entamoeba have been based mainly on the microscopy method [17], which cannot differentiate true infections caused by E. histolytica from nonpathogenic Entamoeba spp. [11]. Among the features for the differentiation of Entamoeba species, the main ones are the cyst size, the number of nuclei, and the appearance of the peripheral chromatin; however, some of these may not always be discernible by light microscopy of fecal concentrates. In addition, the existence of mature as well as immature cysts and morphologically identical Entamoeba species can confuse the diagnostic criteria [7,18]. In fact, light microscopy is considered less reliable to identify the species of Entamoeba than either culture, antigen detection tests, and antibody-based stool ELISA [19,20].
Lately, molecular tools, including conventional PCR, nested PCR, real-time PCR, multiplex PCR, and loop-mediated isothermal amplification assay (LAMP) [21], have been developed and are increasingly used for the detection and differentiation of Entamoeba species in fecal samples. Since 1990, these methods have been implemented and contributed to reevaluating the taxonomy, epidemiology, and clinical significance of Entamoeba isolates found in human fecal samples [20,22]. However, molecular techniques require specific equipment and trained technical staff. In resource-poor regions, the high cost of these methods precludes their use. Thus, PCR- based methods have only been performed in reference and research laboratories of wealthy countries and are not available to the most exposed population [23].
Despite many American countries, mainly those characterized by poor sanitation and socioeconomic conditions, having been reported as endemic for amoebiasis [12], the prevalence of infection, discriminated by species of Entamoeba, is scarcely known. Particularly, amoebiasis is one of the 20 main causes of disease in Mexico; however, some isolated epidemiological studies have been made using molecular tools to characterize E. histolytica and E. dispar [24,25,26,27]. In South America, several studies performed microscopic diagnosis of Entamoeba species, but discriminatory studies between species are relatively scarce. In the United States, California and Texas have shown a higher rate of amebiasis-related mortality [28]. Although there are data on the frequency of human Entamoeba infections in the Americas, there is no global analysis of the prevalence and distribution of this protozoan by geographic area, age group, and method performed for its diagnosis. Therefore, this investigation aimed to review the prevalence, distribution, and diagnosis methods of Entamoeba spp. Infecting humans in the Americas between 1990 and 2022.

2. Material and Methods

2.1. The Review Question

What are the prevalence, geographical distribution, and diagnosis methods of intestinal Entamoeba species in humans from different American countries?

2.2. Literature Research

A literature review of published articles on human infections with Entamoeba species was conducted using electronic databases (BioOne, Google Scholar, JSTOR, PAHO IRIS, PubMed, Scopus and WHO IRIS). Search terms included but were not limited to “Entamoeba”, “amoebiasis”, “human infections”, “GenBank”, “prevalence”, and “America”.
The search was conducted between November 2021 and July 2022. The review included studies on human infections with Entamoeba without restrictions on language. From each study, the following data were extracted: number of samples, prevalence, and technique performed for diagnosis, country, year, type of study, and references.
Articles were included if they described human infections with intestinal Entamoeba species from American countries published from 1990 to 2022. However, they were excluded if they did not describe human infections, did not provide the geographic location, the number of infected subjects, and/or the diagnosis technique. Case reports, letters, editorials, subject reviews, meta-analyses, special theme papers, and symposium proceedings were excluded. This review only included descriptive epidemiological studies evaluating the prevalence of species of Entamoeba in humans.

2.3. Data Summary

The random-effects meta-analysis model was used to analyze the prevalence of the Entamoeba species. The heterogeneity among studies was evaluated using the package meta implemented in R software version 4.2.1 [29,30]. The I2 is expressed as a proportion of the total variance and ranges from 0 to 100%, with values of 25%, 50%, and 75% suggested to represent low, moderate, and high levels of heterogeneity, respectively [31]. Stratified meta-analyses were performed according to regions and techniques.
Maps were performed using QGIS version 3.12 [32].

2.4. GenBank Sequences

We summarize the GenBank nucleotide sequences of intestinal Entamoeba isolates obtained, available on the website: https://www.ncbi.nlm.nih.gov/nuccore (accessed on 1 September 2022).

3. Results

Our systematic literature search retrieved 1935 manuscripts for further evaluation. The screening according to our selection criteria left 227 articles for detailed review (Supplementary Table S1). Brazil was the country better characterized by the high number (N = 60) of studies distributed throughout almost its entire territory. Other countries better represented were Argentina (N = 34), Mexico (N = 23), and Colombia (N = 20) (Supplementary Table S1). The least represented countries were Paraguay (N = 4), Costa Rica (N = 2), and Canada (N = 1), among others. No prevalence data were found for any species of Entamoeba in Uruguay, Suriname, the Dominican Republic, Bahamas, Barbados, and Trinidad and Tobago.
The results of this search strategy are presented according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyzes (PRISMA) flowchart (Supplementary Figure S1). Data were extracted according to the PRISMA Statement [33].
Of the 227 studies included, 70.5% (160/227) identified intestinal amoeba by conventional microscopic diagnosis, 8.8% (20/227) by molecular characterization, 4.8% (11/227) by serology, and 0.4% (1/227) by zymodeme analysis. Some studies performed multiple techniques to confirm the diagnosis: 6.2% (14/227) by microscopic and serology, 8.8% (20/227) by microscopy and molecular diagnosis, 0.4% (1/227) by molecular and serology tests, and 0.9% (2/227) by serology, molecular, and microscopic diagnosis. Of the total of studies that performed conventional microscopic-based techniques (N = 196), 73.0% employed sedimentation methods (formalin-ether concentration technique, spontaneous sedimentation, Ritchie modified, Faust method, and flotation techniques), 7.1% sedimentation and trichrome staining, and 14.8% performed direct smear observations. These conventional techniques were carried out in most American countries, while molecular diagnoses were restricted to some of them, mainly in Brazil, Colombia, and Ecuador (Figure 1).
Of the 227 studies analyzed, 198 (86.8%) distributed samples by age group. Among them, 59.1% (117/198) were performed in children, 29.8% (59/198) in both children and adults, and 11.1% (22/198) exclusively in adults. Concerning the latter, these studies were performed on specific populations, such as immunocompromised individuals (chronic renal and HIV patients), pregnant women, migrants, food handlers, and blood donors, among others. In addition, these studies were mainly carried out in Brazil, and there were some records in Venezuela, Peru, and Central American countries (Figure 1).
Forty-nine percent of the studies (112/227) were unable to differentiate the species E. histolytica, E. dispar, and E. moshkovskii and determined the diagnosis as Entamoeba complex. On the other hand, a small number of studies (3.1%; 7/227) were unable to determine any species and defined the diagnosis as Entamoeba spp.
Half of the studies (114/227) found only one species of the Entamoeba genus, and two (0.9%; 2/227) described five different ones (E. histolytica, E. dispar, E. coli, E. hartmanni, Entamoeba complex/ Entamoeba spp.) (Figure 2). Around sixty percent of the studies (61.7%; 140/227) detected E. coli, 49.3% (112/227) E. complex and 36.1% (82/227) E. histolytica. Few studies found E. dispar (13.2%; 30/227), E. polecki (0.9%; 2/227), and E. moshkovskii (1.3%; 3/227). Entamoeba coli was recorded in all American countries where studies were carried out (except in Canada). A similar geographical distribution was determined for the Entamoeba complex and E. histolytica, with few records in Argentina. In contrast, E. dispar was recorded in a lower number of countries, E. polecki was only detected in Ecuador and Argentina, and Entamoeba moshkovskii was diagnosed in Colombia and Venezuela. The distribution of E. hartmanni was limited to a few records in Venezuela, Colombia, Ecuador, Bolivia, Brazil, Argentina, French Guiana, Mexico, Nicaragua, Belize, and the United States (Figure 2).
Regarding the prevalence estimated for each species, different ranged values were reported among American countries. Globally, the infection with the Entamoeba complex in the analyzed studies ranged from 0.29% (2/595) to 100% (106/106). Particularly, the Entamoeba complex was reported in high prevalence in Mexico, Ecuador, Venezuela, Colombia, Bolivia, and Brazil (Figure 3A). The prevalence of E. histolytica in the analyzed studies ranged from 0.08% (5/6289) to 82.6% (57/69), being more frequent in Venezuela, Colombia, and Mexico (Figure 3B). On the other hand, the prevalence of E. dispar in the analyzed studies was between 0.44% (4/903) and 88% (106/120) by specific methods (molecular and serology), and the only study performed by microscopy determined a prevalence of 14.6% (16/110) (Supplementary Table S1). In particular, high prevalence values of E. dispar were determined in Ecuador and Mexico (Figure 3C and Supplementary Table S1). The prevalence of E. moshkovskii was detected by molecular analysis and ranged from 1 to 25.4% (Figure 3D). The prevalence of E. coli reported in the analyzed studies was between 1.1% and 78%.
The prevalence of the nonpathogenic E. coli ranged from 1.1 (29/2604) to 78.0% (71/91) (Figure 4A). Entamoeba hartmanni prevalence ranged from 0.04% (1/2694) to 45.5% (139/306) (Figure 4B). The determination as Entamoeba spp. ranged from 3.04% (9/296) to 57.9% (89/154) (Figure 4C). Meanwhile, E. polecki was detected in two studies with very low frequency (0.3 and 0.5%) (Figure 4D).

3.1. Pooled Prevalence of Entamoeba Infection

Included studies were highly and significantly heterogeneous according to I2 statistics (>75%; p < 0.05), and therefore, random-effects models were used for the meta-analysis to synthesize pooled estimates of the prevalence of Entamoeba species.
Due to the variability in the number of studies for each country, stratified meta-analyses were performed on data divided into three subgroups according to geographical regions: (i) North and Central American countries (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), (ii) Brazil, and (iii) the other South American countries (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela).
A total of 140 studies were evaluated for determining the prevalence of E. coli. Random-effects meta-analysis showed a pooled prevalence of 21.0% with an I2 value (99%) indicating high heterogeneity (Figure 5 and Supplementary Figure S2). The pooled prevalence detected by molecular analysis (40.0%) was significantly higher than conventional and serology ones (χ2 = 7.95; p = 0.02) (Figure 5A). Regarding regions, the pooled prevalence was similar between them, and no statistical differences were found (p > 0.05) (Figure 5B).
A total of 110 studies were evaluated for determining the frequency of infection of Entamoeba complex. The random-effects pooled prevalence was 13.0% and the I2 was about 95% (Figure 6 and Supplementary Figure S3). The prevalence of this parasite was mainly determined by conventional methods and the meta-analyses revealed values ranging from 1 to 100% with an overall prevalence of 13%; the I2 value was 96.7%, indicating extremely high heterogeneity. Similar values of pooled prevalence were determined by DNA or serology based-detection methods, without statistical differences (Figure 6A). The pooled prevalence was higher in the group of South American countries (Figure 6B).
A sum of 80 studies were evaluated for determining the prevalence of E. histolytica. The random-effects pooled prevalence was 9.0% with a considerably high value of I2 (99%) (Figure 7). A higher pooled prevalence was determined by ELISA serology methods, followed by conventional ones (χ2 = 17.30, p < 0.01) (Figure 7A). The pooled prevalence of E. histolytica was higher in Brazil, without statistical differences among regions (p > 0.05) (Figure 7B).
Thirty studies were evaluated for determining the prevalence of E. dispar. Random-effects meta-analysis showed a pooled prevalence of 10.0% in American regions (Figure 8). The prevalence of this protozoan was mainly determined by molecular methods and the meta-analyses revealed values ranging from 1 to 70% with an overall prevalence of 8.0% (Figure 8A). However, this pooled prevalence was lower than that determined by microscopy or serology-based methods. Among regions, this prevalence was higher in North and Central American countries (Figure 8B).
Twenty-two studies were evaluated for determining the prevalence of E. hartmanni. The random-effects pooled prevalence was 6.0% and the I2 value was 98.0% indicating extremely high heterogeneity. The pooled prevalence was similar among techniques and regions, without statistical differences (Figure 9A,B).
Three studies were evaluated for determining the prevalence of E. moshkovskii. Random-effects meta-analysis showed a general pooled prevalence of 7.0% (Figure 9C).
Two studies were evaluated for determining the prevalence of E. polecki. Random-effects meta-analysis showed a general pooled prevalence of 0% (Figure 9D).

3.2. GenBank Sequences

The GenBank database contained scarce nucleotide sequence data about human Entamoeba species from American countries in the GenBank database. Only nucleotide sequences of SSU rRNA and tRNA genes were submitted (Table 1). Mexico and Brazil reported a higher number of sequences.

4. Discussion

Globally, this review provides an up-to-date overview of the prevalence and distribution of Entamoeba species in 30 out of 35 American countries. Our results reflect a wide sampling of the different countries, but the southeastern areas, such as Brazil, are better represented since these regions present higher scientific production. High heterogeneity existed in the main meta-analysis for each Entamoeba species and persisted in the stratified analyses.
According to our meta-analysis, E. coli was the most prevalent species (21.0%) and based on molecular methods the highest prevalence was obtained for this parasite (40%). However, more studies based on molecular tools are needed to corroborate if conventional methods overestimate the prevalence. In addition, its prevalence was higher in Brazil compared to the other American regions.
An accurate diagnosis of E. histolytica infection is important for patients with amoebic dysentery and asymptomatic infected individuals because it may easily be transmitted from person to person, especially in developing countries that have poor hygienic conditions and inadequate water treatment. In this review, the Entamoeba complex was the second most prevalent diagnosis recorded, being highly frequent in South American areas. Particularly, the higher prevalence rates of the Entamoeba complex were determined by conventional methods, while lower values were determined by serology or molecular analyses. This is probably a consequence of trophozoites of several other nonpathogenic intestinal amoebas or fecal macrophages, being misdiagnosed as E. histolytica/E. dispar/E. moshkovskii by morphological diagnosis [41,42]. Currently, molecular methods are recommended for distinguishing pathogenic Entamoeba species. However, most developing countries cannot afford to use PCR as a part of their diagnostic tool because it is technically complex and expensive, hence, microscopic examinations based on Wheatley trichrome staining have been the most commonly used method [43]. This systematic review showed that conventional methods have been the most widely used for the identification and assignment of Entamoeba organisms in American countries, but trichrome staining was only performed in 7.1% of the studies.
It has been reported that E. histolytica and E. dispar infect around 10% of the world population [44]. However, Cui et al. [45] showed that the overall molecular prevalence of Entamoeba spp. was 3.5% in humans worldwide. They also showed that E. histolityca and E. dispar were responsible for 81.7% of this global prevalence, the latter being much more common than E. histolytica worldwide. Similarly, many studies reported that E. dispar infections were more frequent than E. histolytica [20,39,46,47]. This study showed that the diagnosis of E. histolytica, E. dispar, and E. moshkovskii was mainly based on molecular and serology methods. These techniques detected lower prevalence rates of these parasites compared to conventional methods. It is likely the frequency detected by microscopy overestimated the number of people infected with E. histolytica. Several studies have shown that the coproscopic diagnosis of this enteric protozoan is neither specific nor sensitive [46,47,48]. On the other hand, PCR based-assays avoid not only misdiagnosis but also overtreatment [49]. It is known that infections caused by E. dispar are much more common than E. histolytica worldwide [39]. Consistently, this review revealed that the pooled prevalence of E. dispar was higher than that of E. histolytica. However, a wider distribution of E. histolytica was determined compared to E. dispar and E. moshkovskii. The distribution of E. moshkovskii was limited to Venezuela and Colombia studies, which performed molecular methods.
On the other hand, the distribution and number of studies that detected E. hartmanni were like E. dispar. The nonpathogenic species E. hartmanni can be distinguished from E. histolytica, E. dispar, and E. moshkovskii by optical microscopy. However, this distinction needs detailed observation of nuclear structures, which requires permanent smear staining, an ocular micrometer, and trained parasitologists. Therefore, the possibility of E. hartmanni infection should also be considered in people who excrete indistinguishable E. histolytica/E. dispar/E. moshkovskii complex and E. hartmanni cysts [17]. In this review, we observed that the identification of this nonpathogenic protozoan was mostly performed by microscopic diagnosis.
There are several methods for the diagnosis of amoebiasis, each with different levels of sensitivity and specificity. Although many experts now consider microscopic diagnosis obsolete due to its low sensitivity, it is still employed in developing countries because of the lack of facilities to use other advanced methods [50]. Regarding ELISA tests, antigen-based methods have given good sensitivity and specificity, but serology includes limitations such as false negatives in early infections [51]. PCR is the most reliable diagnostic tool for the detection of Entamoeba species, and it is particularly useful for distinguishing pathogenic versus nonpathogenic ones [52]. Although these methods have been implemented since 1990, this review showed that their use is not yet frequent in the Americas. In addition, in the majority of studies, the Entamoeba assignment to species performed by microscopy and serology overestimated the rates of prevalence, which is in the cases of E. histolytica and E. dispar.
Concerning Entamoeba species distribution through America, E. coli seemed to be the more cosmopolitan species. Its diagnosis by conventional methods is more easily performed than the diagnosis of the other species. Although this is a commensal parasite, it has the same transmission route as that of not only Entamoeba pathogenic species, but also protozoa such as Giardia lamblia and helminths. Thus, the frequency of E. coli should be used as an indicator of fecal/oral transmission, indicating intestinal parasite transmission through the water supply or contaminated food [53].
In contrast, the detection of species such as E. polecki and E. moshkovskii was limited to a few studies. Entamoeba moshkovskii was only detected in Venezuela and Colombia by using molecular methods. This species has long been thought of as a free amoeba, but in the last decade, it has been demonstrated that E. moshkovskii can infect humans and can be found more frequently in areas where amoebiasis shows high prevalence values [3]. Therefore, it is important to perform its diagnosis, especially when considering that it is morphologically indistinguishable from E. histolytica. On the other hand, E. polecki was detected in Ecuador by DNA detection and in Argentina by microscopy.
Infections by protozoan parasites are typically associated with factors such as fecal contamination of food, limited access to safe drinking water, poor environmental sanitation, and vulnerable socioeconomic conditions [54]. In this sense, Latin America and the Caribbean remain the world’s most unequal regions, with 10% of the people still living in conditions of multidimensional poverty [55]. Given the socio-cultural features, these regions tend to have the highest rates of infection by parasites. Indeed, reports of infection with Entamoeba are higher in Latin America and the Caribbean than in North America. However, microscopy likely underestimates the frequency of infection, hence more studies which perform molecular methods are necessary to provide more accurate data on prevalence.

5. Conclusions

This is the first study that reviewed and summarized data on the prevalence of Entamoeba species among American countries.
Entamoeba coli was the most widely distributed species with high prevalence values in several American countries. Among species of the Entamoeba complex, E. dispar was the most prevalent. Moreover, it is important to point out that the prevalence of E. histolytica was high, indicating that this infection remains represent a significant health threat among American countries.
High heterogeneity was detected regarding the number of studies and techniques performed to diagnose Entamoeba species among American countries over around 30 years. This highlights the need to further investigate Entamoeba infections in the regions poorly represented. Moreover, since molecular methods are more reliable for Entamoeba diagnosis, more studies are needed to further expand our understanding of this parasite distribution and the diversity of these parasites in American regions.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/pathogens11111365/s1, Figure S1: Flow diagram of the steps performed in this review; Figure S2: Forest plot for a random-effect meta-analysis of the pooled prevalence of E. coli in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’ and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru and Venezuela); Figure S3: Forest plot for a random-effect meta-analysis of the pooled prevalence of the Entamoeba complex in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’ and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru and Venezuela); Table S1: Summary of the studies included.

Author Contributions

A.S.: Conceptualization. Methodology. Formal analysis. Investigation. Data curation. Writing—Original Draft. Writing—Review and Editing. E.H.: Conceptualization. Methodology. Formal analysis. Data curation. Writing—Original Draft. M.d.R.I.: Formal analysis. Writing—Original Draft. Writing—Review and Editing. J.A.P.-M.: Validation. Investigation. Writing—Review and Editing. M.L.Z.: Resources. Writing—Review and Editing. Supervision. G.T.N.: Validation. Resources. Writing—Review and Editing. Supervision. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Agencia Nacional de Promoción Científica y Tecnológica, (PICT-2018-03763) and the Universidad Nacional de La Plata (UNLP 11/N881 and UNLP 11/N942).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

All data are incorporated into the article and its online Supplementary Materials.

Acknowledgments

We would like to thank the families who participated in this study. We are also grateful to Nicolas Viera for his technical assistance and Lucas Garbin for revising and proofreading the manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Maps representing the distribution of the studies included, according to the species detected, the techniques performed and age groups. The techniques performed are represented by different figures, and the age groups are represented by different colors.
Figure 1. Maps representing the distribution of the studies included, according to the species detected, the techniques performed and age groups. The techniques performed are represented by different figures, and the age groups are represented by different colors.
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Figure 2. Map showing (A) the richness (total of Entamoeba species detected in each study) represented by different colors and sizes of circles. On the right, each map represented the distribution of (B) E. coli, (C) E. complex, (D) E. dispar, (E) E. hartmanni, (F) E. histolytica, (G) Entamoeba spp., E. polecki and E. moshkovskii.
Figure 2. Map showing (A) the richness (total of Entamoeba species detected in each study) represented by different colors and sizes of circles. On the right, each map represented the distribution of (B) E. coli, (C) E. complex, (D) E. dispar, (E) E. hartmanni, (F) E. histolytica, (G) Entamoeba spp., E. polecki and E. moshkovskii.
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Figure 3. Maps showing the prevalence of Entamoeba species, which are morphologically identical, recorded among American countries studied: (A) Entamoeba complex, (B) E. histolytica, (C) E. dispar, and (D) E. moshkovskii.
Figure 3. Maps showing the prevalence of Entamoeba species, which are morphologically identical, recorded among American countries studied: (A) Entamoeba complex, (B) E. histolytica, (C) E. dispar, and (D) E. moshkovskii.
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Figure 4. Maps showing the prevalence of each Entamoeba species registered among American countries studied: (A) E. coli, (B) E. hartmanni, (C) Entamoeba spp., and (D) E. polecki.
Figure 4. Maps showing the prevalence of each Entamoeba species registered among American countries studied: (A) E. coli, (B) E. hartmanni, (C) Entamoeba spp., and (D) E. polecki.
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Figure 5. Forest plot for a random-effect meta-analysis of the pooled prevalence of E. coli in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela). Diamonds constitute a representation that summarizes the studies of each country. The complete version is available in Supplementary Figure S2.
Figure 5. Forest plot for a random-effect meta-analysis of the pooled prevalence of E. coli in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela). Diamonds constitute a representation that summarizes the studies of each country. The complete version is available in Supplementary Figure S2.
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Figure 6. Forest plot for a random-effect meta-analysis of the pooled prevalence of the Entamoeba complex in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela). Diamonds constitute a representation that summarizes the studies of each country. The complete version is available on the Supplementary Figure S3.
Figure 6. Forest plot for a random-effect meta-analysis of the pooled prevalence of the Entamoeba complex in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela). Diamonds constitute a representation that summarizes the studies of each country. The complete version is available on the Supplementary Figure S3.
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Figure 7. Forest plot for a random-effect meta-analysis of the pooled prevalence of E. histolytica in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela).
Figure 7. Forest plot for a random-effect meta-analysis of the pooled prevalence of E. histolytica in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela).
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Figure 8. Forest plot for a random-effect meta-analysis of the pooled prevalence of E. dispar in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela).
Figure 8. Forest plot for a random-effect meta-analysis of the pooled prevalence of E. dispar in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela).
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Figure 9. Forest plot for a random-effect meta-analysis of the pooled prevalence of E. hartmanni in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela); Forest plot for a random-effect meta-analysis of the pooled prevalence of (C) E. moshkovskii and (D) E. polecki.
Figure 9. Forest plot for a random-effect meta-analysis of the pooled prevalence of E. hartmanni in the American population by: (A) techniques: C: conventional methods, based on microscopy; M: molecular method, based on DNA amplification; E: Elisa method, serology-based; (B) Region: North and Central American countries as ‘Group 1’ (Nicaragua, Mexico, United States, Guatemala, Belize, Costa Rica, Cuba), Brazil as ‘Group 2’, and the other South American countries as group 3 (Argentina, Bolivia, Chile, Colombia, Ecuador, French Guiana, Paraguay, Peru, and Venezuela); Forest plot for a random-effect meta-analysis of the pooled prevalence of (C) E. moshkovskii and (D) E. polecki.
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Table 1. Nucleotide sequence data on Entamoeba species available in GenBank.
Table 1. Nucleotide sequence data on Entamoeba species available in GenBank.
Molecular MarkerSpeciesAccession No.CountryHostIsolation SourceReferences
SSU rRNA geneEntamoeba disparMK541026ArgentinaHomo sapiensStoolDirect submission
Entamoeba disparOM985615ArgentinaHomo sapiensStoolDirect submission
Entamoeba disparMZ787761ArgentinaHomo sapiensStoolDirect submission
Entamoeba disparOM985618ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliON713469ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliOM985619ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliMZ787759ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliOM985620ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliMZ787760ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliOM985617ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliMK541024ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliOM985616ArgentinaHomo sapiensStoolDirect submission
Entamoeba coliOM985619ArgentinaHomo sapiensStoolDirect submission
Entamoeba hartmanniMT703882ArgentinaHomo sapiensStool[34]
Entamoeba poleckiMH348163-MH348175ArgentinaSus scrofa domesticaStool[35]
SSU rRNA geneEntamoeba disparMW026767-MW026784BrazilHomo sapiensStool[36]
Entamoeba histolyticaMW026793
MW026794
BrazilHomo sapiensStool[36]
Entamoeba hartmanniMW026785-MW026792BrazilHomo sapiensStool[36]
Entamoeba coliMW026735-MW026766BrazilHomo sapiensStool[36]
Entamoeba coliFR686423BrazilHomo sapiensStool[1]
tRNAEntamoeba disparGU324326BrazilHomo sapiensStool[37]
Entamoeba histolyticaEF421375BrazilHomo sapiensStool[38]
SSU rRNA geneEntamoeba histolyticaKT825974ColombiaHomo sapiensStool[39]
Entamoeba moshkovskiiKT825984-KT825993ColombiaHomo sapiensStool[39]
Entamoeba disparKT825975-KT825983ColombiaHomo sapiensStool[39]
SSU rRNA geneEntamoeba coliFR686443PeruHomo sapiensStool[1]
SSU rRNA geneEntamoeba coliFR686446EcuadorHomo sapiensStool[1]
SSU rRNA geneEntamoeba hartmanniMK541027MexicoHomo sapiensStoolDirect submission
Entamoeba coliMK541025MexicoHomo sapiensStoolDirect submission
tRNAEntamoeba disparGU324327-GU324329
GU324333-
GU324337
MexicoHomo sapiensMixed liver abscess[37]
Entamoeba histolyticaGU324330-GU324332MexicoHomo sapiensMixed liver abscess[37]
Entamoeba histolyticaJN191598
JN191599
JQ828978
MexicoHomo sapiensCutaneous amoebiasis[40]
Entamoeba histolyticaKC791705-KC791758MexicoHomo sapiensAmoebic liver abscess[40]
Entamoeba disparKX461938-KX461956MexicoHomo sapiensStool[27]
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Servián, A.; Helman, E.; Iglesias, M.d.R.; Panti-May, J.A.; Zonta, M.L.; Navone, G.T. Prevalence of Human Intestinal Entamoeba spp. in the Americas: A Systematic Review and Meta-Analysis, 1990–2022. Pathogens 2022, 11, 1365. https://doi.org/10.3390/pathogens11111365

AMA Style

Servián A, Helman E, Iglesias MdR, Panti-May JA, Zonta ML, Navone GT. Prevalence of Human Intestinal Entamoeba spp. in the Americas: A Systematic Review and Meta-Analysis, 1990–2022. Pathogens. 2022; 11(11):1365. https://doi.org/10.3390/pathogens11111365

Chicago/Turabian Style

Servián, Andrea, Elisa Helman, María del Rosario Iglesias, Jesús Alonso Panti-May, María Lorena Zonta, and Graciela Teresa Navone. 2022. "Prevalence of Human Intestinal Entamoeba spp. in the Americas: A Systematic Review and Meta-Analysis, 1990–2022" Pathogens 11, no. 11: 1365. https://doi.org/10.3390/pathogens11111365

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